Biopesticides
METHODS
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BIOTECHNOLOGY’”
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Biopesticides
METHODS
IN
BIOTECHNOLOGY’”
John M. Walker, SERIES EDITOR 12 EnvironmentalMonitoring of Bacteria,edited by CloveEdwards, 1999 11 AqueousTwo-PhaseSystems, edited by Rap Hattl-Kuul, 1999 10. CarbohydrateBiotechnologyProtocols,edited by Chrrstopher Bucke, 1999 9. DownstreamProcessingMethods,edited by Mohamed LIesal, 1999 8 Animal Cell Biotechnology,edlted by Nlgel Jenkms, 1999 7. Affinity Biosensors:Techniques and Protocols, edlted by Km R Rogers and Ashok Mulchandanr, 1998
6. Enzymeand Microbial Biosensors:Techniques and Protocols, edlted by 5. 4. 3. 2. 1
Ashok Mulchandam and Kern R Rogers, 1998 Biopesticides:Use and Delivery, edited by Frankhn R. Hall and Julius J. Menn, 1999 Natural ProductsIsolation, edited by Rxhard J P Cunnell, 1998 RecombinantProteinsfrom Plants:Prod&on and Isolation of Clinically Useful Compounds, edited by Charles Cunmngham and AndrewJ R Porter, 1998 BioremediationProtocols,edited by David Sheehan, 1997 Immobilizationof Enzymesand Cells, edited by Gordon F Blckerstafi 1997
Biopesticides Use and Delivery
Edited by
Franklin R. Hall Ohio State Unwersity, Wooster, OH
and
Julius J. Menn Excipula, Inc , Highland, MD
Humana
Press
Totowa, New Jersey
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In biotechnology’*
Blopesttcldes
use and dellvery/edlted by Franklm R Hall and Juhus J Menn cm --(Methods In biotechnology, 5) P Includes Index ISBN O-89603-5 15-8 (alk paper) I Natural pestlctdes 2 BIologIcal pest control agents 3 Agrrcultural 1 Hall, Franklin R II Menn, Juhus J III Series SB95l I45 M37B56 1998 632’ 954~2 I 98-25118 CIP
pests-Blologtcal
control
Preface It was our intention and goal to bring together m Biopestzcides Use and the latest advances in the science and technology of the evolving field of biopesticides In the context of crop protectton, btopesttcides are a key component of integrated pest management (IPM) programs, m which biopesticides are delivered to crops m inundative quantities, vs the moculative approach, which is charactertstic of classical biological control. Although there are several definitions of biopesttcides m the literature, we chose to define them as either microbials themselves or products derived from microbials, plants, and other biological entities. In the developed, industrial countries, primarily in Western Europe and the United States, biopesticides are receiving more practical attention, smce they are viewed as a means to reduce the load of synthetic chemical pestttides m an effort to provide for safer foods and a cleaner envtronment. In the developing countries, biopestictdes are viewed as having the potential to exploit nattve resources to produce crop protection agents that would replace imported chemical pesticides and conserve much-needed hard currencies These trends are well represented by the dynamic growth of engineered crops expressing the delta-endotoxm insecticidal protem crystals of Bacillus thuringzenszs (B.t ) m corn, cotton, and potatoes and the development of recombinant B.t.s and biopesticides as key crop protection agents against such pests as the soybean caterpillar, which is effectively controlled by a nuclear polyhedrous virus m Brazil, the use of neem extracts m East Africa and India, and various botamcals m East Africa and South America. The btopesticide market is expected to grow at a rate of 10% per year vs l--2% for chemical pesticides. The current biopesticide market IS estimated at $500 million worldwtde At the projected rate of growth, the sales volume ~111 double by the year 2007. It is likely that major breakthroughs m biopesticide technology ~111further increase the rate of growth of biopesttcide usage A pertinent example mvolves the efforts by several multmattonal companies to produce baculoviruses m deep fermentation Success m this area could provide a major boost to the mcorporation of baculoviruses as major crop protection agents m the biopesticide armamentarmm. Delavery
V
Preface
VI
We do not view biopesticides as replacements for chemtcal pesticides on major crops Biopesticides, viewed realistically, will most likely find uses as supplements to chemical pesticrdes and as rotation agents m early season on major crops to retard the onset of resistance. Other uses that will increase the acceptance of biopesticides ~111be m IPM programs on minor crops and niche markets We have mvrted leading experts m the btopesticide field to contribute comprehensive chapters on mode of action, development, productron, dehvery systems (formulations), and market prospects for the future. In addition, we invited registration experts from both government and industry to review current registration requirements, time frames, and costs of registration and compare them with registration requirements of conventtonal pesticides. We also have contributions describing momtormg procedures and management of resistance of pests to biopesticides. It is our goal that this volume will serve as the current, most comprehensive treatise on the rapidly emerging field of btopesttcides and a useful resource for practitioners, students, regulators, and mdustrial planners and marketers. Franklin Julius
R. Hall J. Menn
Contents .. .- . . .. . .. . .. . . . . . ,.,,... . . . .. . .. .. . .. . . .. . . .. . . , V Preface .. . . .. . . . . .. . . . . .., XI Lrst of Contributors . . .. . . .. . . . . , . .. . .. .. . . . .. .. . .. . 1 Biopesticides. Present Status and Future Prospects .. . . . . . . I Julius J. Menn and Franklin R. Hall.. . .. ... . PART I
PROJECTIONS ON OPPORTUNITIES FOR BIOPESTICIDES IN CROP PROTECTION . . . .. . . . .. .. . .. . . . . . . . . ..
..
I1
2 The North American Scenario . .. .. . . . . . .. 13 . . . . *. . .. ., , .. . Jerry Caulder 3 Microbial Bropesticides: The European Scene Tariq M. Butt, John G. Harris, and Keith A. Powell. . . . .. ...*.... . . . 23 4 Developing Countries 45 Balasobramanyan Sugavanam and Xie Tianjian . . . . .. . .. . .. . , . . 5 Pesticide Policy influences on Biopesticide Technologies 55 . . . .,.. . . .. . .. . .. .. . .. . .. . . . . . . . .. . . .. . Noel D. llri . . . . . .. . . 75 . .. . .. . . .. , . .. . .. . .. . . . . . PART I I. BIOFUNGICIDES . . 6 Commercral Development of Brofungicides 77 ...* ,. . Rafael Hofstein and Andrew C. Chapple . 7 Biological Control of Seedlrng Diseases . . . . 103 K. Prakesh Hebbar and Robert D. Lumsden . 8 Joint Action of Microbials for Disease Control .. . . . . 117 Claude Alabouvette and Philippe Lemanceau .. 137 . .. .. . .. . .. . . . . . . .. .. . . . .. . . . .. . . . .. .. . . PART II I BIOINSECTICIDES 9 Neem and Related Natural Products . . . . . . , . . . .. . ,. . . . . .. . . . .. 139 Murray B. lsman 10 Commercial Experience with Neem Products 155 . . .. . .. ... . ,. . James F. Walter 11 Fermentation-Derived Insecticide Control Agents The Spinosyns Thomas C. Sparks, Gary D. Thompson, Herbert A. Kirst, Mark B. Hertlein, Jon S. Mynderse, Jan R. Turner, . .. . . . 171 and Thomas V. Worden . . .. . . . . . . . . . . 12 Baa//us thunng/ensis. Natural and Recombinant Bllomsecticide Products 189 James A. Baum, T. B. Johnson, and Bruce C. Carlton . . .. . . . . vii
*., VIII
Contents
13 Transgenrc Plants Expressing Toxms from Bacillus thuringrems . , . .. . .. Jonnie N. Jenkins 14 Production, Delivery, and Use of Mycoinsectrcides for Control of Insect Pests on Field Crops . Steven P. Wraigt and Raymond 1. Carruthers . 15 Entomopathogemc Nematodes .. . .. , Parwinder Grewal and Ramon Georgis 16 Naturally Occurring Baculovrruses for Insect Pest Control . . . . Brian A. Federici . . . .. . . . 17 Recombinant Baculoiviruses . . .. , . .*.. . . .,... . . .. .. ... Michael F. Treaty 18 Joint Actron of Baculoviruses and Other Control Agents ,.. .. .. William F. McCutchen and Lindsey Flexner . . . . . .. . PART IV BIOHERBICIDES . . . .. . .. . .. . . . . . . .. . .. . .. . .. . .. . . . . . . .. . .. . . .. . , .. . .. .,.,. 19 Mycoherbrcrdes . .. Alice L. Pilgeram and David C. Sands . . . 20 Formulation and Application of Plant Pathogens for Brologrcal Weed Control . . .. . .. .. . Nina K. Zidack and Paul C. Quimby .. . . . PART V OTHER BIORATIONAL TECHNOLOGIES 21 Phereomones for Insect Control. Strategies and Successes . . .. . . .. . . . . D. R. Thomson, L. J. Gut, and J. W. Jenkins . . . . ., PART VI REGISTRATION OF B!OPESTICIDES ,..... ..,. . , , . 22 The Federal Registratron Process and Requirements for the United States .. ... . . .. . ., J. Thomas McClintock , .. . . 23 IR-4 Bropestrcrde Program for Minor Crops . , Christina L. Hartman and George M. Markle 24 RegistratrorYRegulatory Requirements In Europe Mike Neale and Phil Newton .. 25 Environmental and Regulatory Aspects, industry Wew and Approach .. Joseph D. Panetta , .. PART VII MANAGEMENT PROTOCOLS . . .. . 26 Formulatrons of Biopesticides Susan M. Boyetchko, Eric Pedersen, Zamir K. Punja, . . ., , . .. . . and Munagala S. Reddy .. . .. . . . . . .. . . 27 Delivery Systems and Protocols for Biopesticides ,.. ,. .. Roy Bateman ... . .,.* . . *. . . . .. . .* .. .
211
233 271 301
321 34 1 357 359
371
383 385 473
415
443 453 473 485
487 509
ix
Contents 28
Analysis, Momtormg, and Some Regulatory Implications *.*,... . . . ., .. . . . . .. . .. . . Jack R. Piimmer 29 Principles of Dose Aquisitlon for Bioinsecticides . .. . .. . . . .. .. . .* * Hugh F. Evans, .., ..*... . . ....* .. . 30 Strategies for Resistance Management .. .. , . ,. . ., . ..., . . . . .. . .. .. . Richard T. Roush 31 Field Management’ Delivery of New Technologies to Growers .. . Mark E. Whalon and Deborah L. Norris . . . .. .. . . . .*... ..* . . . Index . . .. . . . , . .
529 553 575 .
595 609
Contributors Laboratoire de Recherches SUPla Flare pathogene duns le Sol, Doon, France ROY BATEMAN International Institute of Biologtcal Control, Ascot, UK JAMES A. BAUM Ecogen, Inc., Langhorne, PA SUSAN M. BOYETCHKO Agriculture and Agri-Food Canada, Saskatoon, Canada TARIQ M. BUTT IACR-Rothamsted, Harpenden, UK BRUCE C. CARLTON New Jersey Agrtcultural Experimental Statton, Cook College, Rutgers Untversity, New Brunswick, NJ RAYMOND I. CARRUTHERS National Program Stag USDA/ARS, Beltsvtlle, MD JERRY CAULDER Mycogen Corporation, San Dtego, CA ANDREW CHAPPLE Ecogen, Inc., Langhorne, PA HUGH F EVANS Forestry Commtsston Research Agency, Wreccleshan, UK BRIAN A. FEDERICI Department of Entomology and Interdepartmental Graduate Program tn Genetics, University of California, Riverside, CA LINDSEY FLEXNER DuPont Agricultural Research Center, Newark, DE RAMON GEORGIS Therm0 Trtlogy Corp., Columbta, MD PARWINDER GREWAL Department of Entomology, Ohio State Untverstty, Wooster, OH L. J. GUT Department of Entomology, Michigan State University, East Lanstng, MI FRANKLIN R. HALL Ohto State University. Wooster, OH JOHN G. HARRIS Zeneca Agrochemicals, Bracknell, UK CHRISTINA L. HARTMAN IR-4 Biopesticide Coordinator, Rutgers, The State Untverstty of New Jersey, New Brunswick, NJ Present Address. Agricultural Products Research Division, American Cyanamid Co , Princeton, NJ K. PRAKESH HEBBAR USDA/ARS, Beltsvtlle, MD MARK B. HERTLEIN DowElanco Discovery Research, Indianapolis, IN RAPHAEL HOFSTEIN Ecogen, Inc., Langhorne, PA MURRAY B. ISMAN Department of Plant Science, University of Brtttsh Columbia, Vancouver, Canada CLAUDE ALABOUVETTE
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Contributors
JOHNIE N. JENKINS
Crop Sctence Research Laboratory, USDA/ARS, State, MS J. W. JENKINS Pactfic Btocontrol Corp , LitchJield, AZ TIMOTHY B. JOHNSON Ecogen, Inc , Langhorne, PA HERBERT A. KIRST Elanco Animal Health Research and Development, Greenfield, IN PHILIPPE LEMANCEAU Laboratotre de Recherches sur la Flore pathogene darts le Sol, Dyon, France ROBERT D. LUMSDEN USDA/ARS, Beltsvtlle, MD GEORGE M MARKLE . IR-4 Associate Dtrector/Professor, Rutgers, The State Untverstty of New Jersey, New Brunswtck, NJ J THOMAS MCCLINTOCK USEPA, Washtngton, DC WILLIAM F. MCCUTCHEN DuPont Agricultural Research Center, Newark, DE JULIUS J. MENN 9 Exctpula, Inc , Highland, MD JON S MYNDERSE Lilly Research Laboratories, Elt Lilly and Co, Indtanapolts, IN MIKE NEALE Novartts Crop Protectton, Basel, Switzerland PHIL NEWTON Novartts Crop Protectton, Basel, Swttzerland DEBORAH L. NORRIS Michigan State Unzversity, East Lansing, MI JOSEPH D PANETTA 9 Regulatory and Envtronmental Affairs, Mycogen Corp , San Diego, CA ERIC PEDERSEN Agrtum Inc., Saskatoon, Canada ALICE L. PILGERAM 9 Department of Plant Pathology, Montana State Untverstty, Bozeman, MT JACK R. PLIMMER Tampa, FL KEITH A. POWELL Zeneca Agrochemtcals, Bracknell, UK ZAMIR K PUNJA Centre for Pest Management, Simon Fraser Untverstty, Burnaby, Canada PAUL C. QUIMBY, JR Northern Plains Agrtcultural Research Laboratory, USDA/ARS, Stdney, MT MUNAGALA S. REDDY Saskatoon, Canada RICHARD T. Rousn Department of Crop Protectton, Untverstty of Adelatde, Glen Osmond, Australia DAVID C. SANDS Department of Plant Pathology, Montana State Untverstty, Bozeman, MT THOMAS C. SPARKS DowElanco Dtscovery Research, Indtanapolts, IN BALASUBRAMANYAN SUGAVANAM UNIDO, China GARY D. THOMPSON DowElanco Dtscovery Research, Indtanapolts, IN D. R. THOMSON Pact@ Btocontrol Corp , Vancouver, WA l
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XIE TIANJIAN UNIDO, China MICHAEL F TREACY Amerctan Cyanamid Co., Prtnceton, NJ JAN R TURNER Ltlly Research Laboratones, Elt Lilly and Co , l
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Indtanapolts, IN NOEL D. URI Economtc Research Service, US Department of Agriculture, Washington, DC JAMES F. WALTER Rohm and Haas Co., Philadelphia, PA MARK E. WHALON 9 Michigan State Untverstty, East Lansing, MI THOMAS V. WORDEN DowElanco Discovery Research, Indtanapolts, IN STEPHEN P WRAIGH~ Plant Protectron Research Unit, US Plant, Soil, and Nutrition Laboratory, USDA/ARS, Ithaca, NY NINA K. ZIDACK Department of Plant Pathology, Montana State Untverstty, Bozeman, MT l
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1 Biopesticides Present Status and Future Prospects Julius J. Menn and Franklin R. Hall
1. Introduction Bropestlcrdes, mcludmg mrcrobral pestrctdes,entomopathogenic nematodes, baculoviruses, plant derrved pestrcides, and Insect pheromones, the latter when used as mating drsruptlon agents, are recetvmg increased exposure m scientific annals and the lay press, as alternatrves to chemical pestrctdesand as key components of integrated pest management (IPM) systems(2,2). The reality, however, IS that biopesticrdes currently represent only a small fractron of the world pestrcide market. At the present time, various economrc forecasting servtces estrmated the world market for pesticides m 1995 at approx $29 btlhon 0. The bropestrcrde share of the market was estimated to be around $380 million in 1995 (1). Although representing only 1.3% of the total, and since the majority of bropesticides are currently marketed for insect control, blopesttcides represent approx 4.5% of the world insecticide sales. However, the growth rate for bropestrcrdes over the next 10 years has been forecast at 1O-l 5% per annum m contrast to 2% for chemical pesticides (2) The foregoing IS based on several assumpttons that are predicated on the successor failure of several technologies; notably, transgemc crops expressing Baczllus thuringzensis (Bt) insect protein toxins. Should the latter be successful and allowmg that Bt engineered crops are m the biopesttcide arena, the growth rate of biopestrcides will be much greater than forecast The potential for resistance developmg to B&engineered crops m lepldopterans may alter the equatron stgmficantly. Furthermore, the agrochemlcal mdustry has been introducing recently hrghly Insect-pest-specific insecticrdes wrth modes of actlon From
Methods F R Hall
m B/otechno/ogy, and
J J Menn.
vol 5 B/opestmdes eds
0 Humana
1
Press,
Use and De//very Totowa,
NJ
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that are targeted to pest species.Such selective msectlcldes may also slow down the rate of growth of blopestlcldes. However, the science, technology, and marketing of blopesticldes are forging ahead as key components of IPM and sustamable agriculture. In this volume we have brought together a select group of biopesticlde experts reporting on the current status and prospects for blopestlcldes, their role m crop protection, delivery systems,monitormg resistance management, marketing, reglstratlon and pohcles influencing their future prospects. It IS our mtent to provide the readers of this volume with the state of knowledge, current status, and future prospects for blopestlcldes as key components of IPM programs in contemporary agriculture. 2. Opportunities for Biopesticides The followmg discussion highlights chapters included m this volume. The prospects and economic projections for bropesttcldes m the United States, Europe, and developing countries are discussed m Chapters 2, 3, and 4 The current state of blopestlclde development for the Unlted States (Chapter 2) 1s presented from an industry standpoint and although optlmlstlc, expectations for future commercializations are tempered by a plea for increased coordmatlon by industry, academics, growers, and others, because of the need to more effectively utilize these tools within the context of IPM, transgemc plants, and so forth. The European scene (Chapter 3) 1sa detailed descrlptlon of some of the microbial experiences and lrkewlse calls for added support from Extension/industry m the “implementation” phase. In the developing countries (Chapter 4), experiences (mainly with Bt) m China, Thailand, and other countries are identified wherein quality control, education, and a request for more activity from international organizations will aid the transfer of blopestlcide technology to active usage as complementary technologies to chemical pestlcldes, rather than as “mere replacements ” As a final component to the sectlon on opportumtles, pesticide pohcy issues, constraints and incentives for new technologies, and the recent impact of US legislation are outlined m Chapter 5 Although the outlook IS comphcated, the key factors of pesticide regulation, the Fan Act and Food Quality Protection Act (FQPA), government subsidies affecting crop dlverslty, management expertise with ecologlcally based systems, and “demand” for green produce will influence technology identification and lmplementatlon 3. Biofungicides In a section focusing on Blofunglcldes, it 1s clear that relatively few blofunglcldes have reached marketing status to date. AQ 1O@1sa recent mtroduction as a control agent against powdery mildew of fruit, primarily grapes
Blopes trades
3
(Chapter 6; ref. 3). These authors provide a well-documented roadmap of laboratory and field experiences with AQlO@ that should serve as a clear guide to “what works and what doesn’t” m developing a better understandmg of these btoagents n-rthe drffcult “real world ” As the authors conclude, dtssectmg the molecular elements contributing to fungal pathogenrcity will indeed aid progress m thts arena as we attempt to insure that all possrble attributes are expressed m targeting thts brofungtctde. It will be interesting to follow the fortunes of thts proneermg mtroductron m competttton wtth an old establtshed product, such as sulfur, and newer selective chemrcal fungtcrdes. Brofungrcrdes for control of seedling diseases, such as pythmm, fusarmm, rhizoctoma, and vertrcillmm, have received mcreasmg attention m recent years (41, primarily as nontoxrc, nonresidue producmg control agents. The utrhty and development of Glzocladzumvzrens for control of sorlborne pathogens IS described m Chapter 7, and the authors emphasize the necessity of a logical, well-documented series of studies from dtscovery through ecologtcal understanding and final usage studies m order to fully develop opportunmes for seedlmg brocontrol agents. Joint actton of brofungtctdes IS a relatively new area of mvestrgatton. Joint actton, or posstbly synergy, may increase the utrhty of brofungicrdes, as was demonstrated by combmmg a nonpathogemc strain of Fusarzum oxysporum wtth a strain of Pseudomonasfluorescens to control Fusarzum wilts (5) More recent advances m this mterestmg arena are described m Chapter 8. In thts complex array of poorly understood interacttons, It IS clear that good knowledge of antagomsts and then behavior are key constraints to more raprd commerctalrzatron It IS likely that niche markets may well prove to be useful starting points for marketing these btocontrol agents 4. Bioinsecticides Broinsecttcrdes represent the maJor segment of bropesticldes and comprrse the largest array of diverse mtcrobrals and natural products m the bropestrcrde armamentarium. Chapters 9 and 10 deal primarily with neem seed derived products and neem or1 as insect growth regulators, antrfeedants, msectrcrdes, and fungicides, and provide a clear outline of the hrstory and the current and future status of neem-related products. The potential of Azadnachtm, the prmctpal Insect-active macrocyclic lactone component of neem seed 011, has broad msectrcrdal actrvrty that makes rt an attractive candidate insecticide for specralty and niche crops (6). To date, the most economrcally significant bromsectrcrdes were the avermectms, derived by fermentation of a streptomyces species and chemrtally defined as macrocylic lactones The most notable are abamectrn (avermectm Bl) and Its chemrcally modified analog, Emamectm benzoate
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(MK-244). These blomsectlcldes were described m numerous publlcatlons, including ref. 7. More recently, a chemically related class of fermentation-derived msectlcldes, the spmosyns from Succharopolyspora species, was introduced by DowAgroSclences (8). The lead member IS spmosad, with excellent msectlcldal activity against lepldopterous larvae and other msects (Chapter 1I). An Interesting story describing Its development 1s hlghhghted by the authors’ awareness of resistance management and the opportunities to develop a unique set of molecules possessingsafe envlronmental and mammalian profiles, while at the same time proving to be selective, and thus somewhat market restricted. Clearly, there would seem to be “more to come” from this group of interesting bioactive naturally derived products. The best known group of blopestlcides, the Bts, are also produced by fermentation but yield insectlcldal crystal proteins rather than discrete chemicals, such as the spmosyns and avermectins By selection of natural Isolates from the thousands known, as well as those derived from plasmtd conJugatlon and recombinant DNA technology, it has become feasible to tailor make Bts that are targeted against specific insect pests (9,ZO; Chapter 12). Although identifying the limitations of field persistence and mcomplete coverage of target surfaces, the authors project a positive outlook for this vast array of toxins as attractive alternatives to existing products. The successwill depend on developments m improved formulations and an improved understanding of dosetransfer processes (as is the case with almost every blopestlcldal agent). The Bt technology has been taken a step further by engineering cotton, corn, and other crops to express truncated versions of the cryIA genes from Bt vanety kurstaki Engineered plants provide protection against certain lepidopterous larvae, notably Heliothis vzrexens, a major pest of cotton and corn (IO; Chapter 13). Although the picture looks bright as indicated by the recent flurry of merger activity among seed, chemical, and biotechnology companies, such as Monsanto, DuPont, AgrEvo, and others, rt IS tempered with a divergence of opmrons about llmltatlons resulting from pest resistance. As noted m Chapters 14 and 30 (under management strategies), one of the key concerns mvolvmg transgemc crops expressing Bt toxins IS the potential for resistance development m target insects. Contmuous exposure to the toxin challenge has a high probablllty for selection of reslstant mdlvlduals. Strategies have been developed to delay and/or ameliorate the onset of resistance mvolvmg establishment of refugia and high expression of Bt protein toxins in engineered plants (12,13) Entomopathogenic fungi (mycoinsecticldes) are gaming increased attention as environmentally friendly insect control agents. Although over 750 species were reported to infect insects, few have received serious conslderatlon as potential commercial candidates. Beauverza bassiana appears to have the
Biopestmdes
5
broadest potential as a viable msect control agent (14). The status of this area of insect control IS identified m Chapter 14. Technological advances m production, formulation, and shelf life have contributed substantially to the viabtlrty of mycoinsectictdes as practtcal insect management agents that can compete economically with chemical insecticides in certain situations, such as fruit and specialty crops. A comprehensive review of the use of entomopathogemc nematodes is covered m Chapter 15 Summarizing the rapid commercialization (prmctpally in the 199Os), the authors relate these successesto large-scale productton technology and innovative formulations allowing shelf stability that has allowed a cottage-type industry to emerge in both the United States and Europe. An ongoing plea IS made for more integration of crop protection technologies and technology transfer trainmg; both are emphasized as constraints to continued progress. Baculoviruses are summarized in three chapters dtscussmg natural (Chapter 16) and recombinant (Chapter 17) baculovnuses, as well as experiences with jomt action of baculovu-uses with other control agents (Chapter 18) Baculoviruses have already been employed as biopesticides m the United States, m the 1970s for control of the cotton bollworm, Helicoverpa zea, m cotton and the gypsy moth, Lymantrza dispar, m forests. However, the product, Elcar, for control of H. zea failed as a commercial entity, largely resultmg from inability to compete with the then newly introduced pyrethroids, mstabthty in the field, slow action, and narrow spectrum of bioactivity (15). In contrast, considerable success m control of the velvetbean caterpillar, Anticawa gemmatalis, was achieved m Brazil on large soybean acreage (16, Chapter 16). However, these represent isolated cases of successful field use of baculovnuses. Broader use was precluded as a result of the already listed shortcommgs. With the advent of recombmant DNA technology, baculoviruses have received renewed attentton because of their small genome and uncomplicated molecular organization, allowmg for ready mtroductton of quick-acting msect toxic genes, such as an engineered portion of the scorpion toxin, AaIT, which greatly improves the field performance of the engineered baculovuus by killing the pest insects more rapidly (17,28; Chapters 17 and 18). An improved understanding of the toxtctty processes involved with the joint action of baculovirus with other toxins and chemical pesticides may jump start this group of viruses to greater market potentials. 5. Bioherbicides Btologtcal weed control (bioherbicides) has been actively pursued for several years, primarily m academic and government research institutions. To date, over 100 weed pathogens have been reported (19). However, only a handful of
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bioherbictdes have entered commercial channels with very limited success, primarily because of their mabihty to compete with chemical herbicides that are specific, economic, and pose no environmental and residue hazard. However, bioherbicides are ideally suited for control of undesirable vegetation m pasture and rangeland, where the use of chemical herbtctdes would be prohibitively expensive (Chapters 19 and 20) 6. Other Technologies The successful development of pheromone based insect mating disruption m fruit trees and vineyards m North America and Western Europe has given pheromones a new dtmension as biopestictdes and provides promise that this technology, using pheromones as biocontrol agents, ~111reduce dependence on chemical pesticides for insect control m orchards and vmeyards (Chapter 2 1). 7. Registration of Biopesticides In recogrntton of the White House polictes concernmg environmental quality improvements and reduced dependence on chemical pesticides, wtth stated but unlikely attainable goals that 75% of chemical pesticides will be replaced with biopesticides by the year 2000, the USEPA established a Biopestictdes Pollution and Prevention Divtsion (BPPD) to manage accelerated registration and registration of biopesticides. The BPPD approved for registration 14 new biopestlctdes m 1995 and 10 m 1996, representing 35-40% of all new pesticide registrations. The average duration for registration of a btopesticide has been 12 mo vs 36-45 mo for a conventional chemtcal pesttctde. Furthermore, the agency required stgmficantly fewer data for a biopesticide m support of fmdmg no significant adverse effect to humans and the environment. The agency provides for an expedited review of the registrant’s application, the tolerance fee 1s waived, and requirements for an emergency use permit (EUP) may also be waived. The registration and associated policies m the US and Europe are described m detail m Chapters 22 and 24. The enlightened pohcuesand regulations governing btopesticides are especially sigmficant with regard to the approval process for use of biopestictdes on minor crops involvmg the IR-4 program (Chapter 23). The views of the industry relating to recent “safer” policies, by USEPA and other agenctes, are described m Chapter 25 Future expectations are tempered by the expressed need (by industry) for greater incentives provided by the USEPA, a renewed focus on clarifymg the benefits of such agents, greater coordmation/consolidation of databases, and greater flextbility m registration processes to provide recognition and encouragement of these more selective molecules offering greater environmental and human safety.
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8. Management Protocols Completmg the “hfe cycle of development” of crop protection biopestictdes IS that area that seemsto be mcreasrngly important in successfultmplementation of more complex molecules/strategres,i.e., user management.Biopestrcides,posstbly even more so than chemical pesticides,are very dependenton proper formulatton and delivery systemsas key elements in performance. Furthermore, shelf life and ratesof apphcation are also largely a function of appropnate formulations (Chapters 26 and 27). Momtonng the fate of biopesticidespost application 1salso critical m determimng efficacy and survival of btocontrol microbials. Much of the momtormg scienceand technology ISrelatively new and mvolves growing emphasisand attention to this area(Chapter 28). The doseacquisttion(including pest encounter)processes(and realitiesof poor use efficiencies)arejust now being betterunderstoodandtranslatedto improved placement cnterra for thesemolecules.Chapter29 provides a somewhatspectficbut unique look into the array of detailsneededfor anoptimizeduse.It provides an interestingcorollary to the storyrelatedin Chapter6, I.e.,the researchexperiences,researchma1successand failures with AQ 10 However, whethercompaniesarereadyto assumeagreaterrole in more basicstudiesmvolvmg this technologyis yet unknown. Resistance management 1sa recurring theme throughout, with recogmtion bemg given to this Important phase of developing any crop protection agent. Chapter 30 provides some interesting points about the practicality of managing resrstance, which is mcreasmgly receiving much attention by the industry, A final thrust to the story of bropesticide development covers the user acceptance of increasingly complex crop protection strategies (Chapter 3 1) These new crop protection agents (biopesticldes) are more specific, lessrobust m environmental persistence, require more precise timing, offer significant opportumtres as alternatives to conventional pesticides, yet clearly are not quite as reliable. Management of information, monitormg, and use profiles will help m achieving success,but this will require additional grower education by all parties concerned with education and technology transfer of new crop protectton strategies. Continued emphasis by the industry on conventional chemistries as the “development model” for pesticides, the lack of new visionary thmkmg about long-term economic and ecological benefits of biopesticides, and needed educational thrusts about cosmetic standards, performance expectations, and detailed use requirements remam serious constraints hmitmg this technology (20). 9. Conclusions In summary, bropesttcides are achieving a modicum of growth as alternatives to conventional pesticides. However, their full potential has yet to be reached. The key factors/trends envisioned to significantly impact future developments mclude the following
Menn and Hall Regulatory/legislative and economic pohcles, mcludmg the new FQPA, may encourage further growth via fast trackmg/reduced reglstratlon reqmrements for bloratlonals. Developed country policies (globally) will continue to press for safer materials and alternatives to chemical pestlcldes, mcludmg more complex crop protectlon strategies, such as IPM/ICM, and others Developing countries have already mltlated thrusts to more efficiently utlhze such materials User education m both cases remains a serious constraint for Increased growth of blopesticldes Greater attention by industry/academra to reduced risk agendas (human and envlronment), as well as an Improved identlficatlon of the economic benefits profile of a crop protection strategy will greatly aid a sustainable growth of bropestlcldes Industry experiences such as with AQ 10, further illustrate the need for a comprehensive review of the plant/disease ecosystem complexity regarding the reduced reliance on the sole “conventional wisdom” approach of tradltlonal pestlcldes Blopestlcldes are more specific, more complex, less robust m the environment, and require greater knowledge about the ecosystem mteractlons. Partnermg of expertise will engender greater successwith these more complex agents, 1e , mterdlsclphnary teams must be the accepted norm m the development strategy There must be continued recogmtlon of the “power” of the transgetuc technology to influence a sustainable agriculture and plans made for such options as reslstance management, pestlclde pohcy mfluences on crop diversity, density, and other variables, frequency of planting, and so forth. Recogmtlon by the industry that “delivery” Is an essential part of the crop protection use pattern ~111 aid the speed of user acceptance of blopestlcldes Contmuatlon of the emphasis on environmental and ecotoxiclty requirements should aid increased acceptance and registration of btopestlcldes, whrch will probably remam in niche crops. The ldentificatlon and utrllzatlon of natural plant defense mechamsms interfaced with temporal/spatial phenomena may reveal an mterestmg array of new product opportunities. Industry willingness to mvest more than the traditional knowledge/ marketing skills m this approach wdl dictate ultimate success. Recent industry mergers and amalgamations accompamed by developments m transgemc technologies and value-added products would suggest not only unique crop protection opportumtles, but also reveal a powerful agenda m life science strategies for the new millennium agriculture.
References 1 Menn, J J (1997) Blopestlcldes-are they relevant7 m Focus on Blopestzcrdes, The Royal Society of Chemistry, pp, 1,2. 2 Menn, J J (1996) Biopestlcldes Has then time come? J Envrron ,%I Health B 31(3), 383-389.
3 Daust, R A and Hofstem, R. (1996) Ampelomyces quuqualu, a new blofunglclde to control powdery mildew rn grapes Brrghton Crop Protection Conference on Pests and Diseases-November 18-2 1, 1996, BrIghton, UK, 1, 33-40.
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Papavizas, G. C. (1985) Trichoderma and Ghocladmm: biology, ecology, and potential for blocontrol. Ann Rev Phytopathol 23,23-54. Alabouvette, C. (1996) Blological control of Fusarium wilts IOBC wprs Bulletln/Bulletln OILB srop 19(8), 58
Leskovar, D. I. and Boales, A K (1996) Azadlrachtm: potential use for controlling lepidopterous insects and increasing marketability of cabbage Hort Scr 31(3),405-409
Mrozlk, H (1994) Advances m research and development of Avermectms, m Natural and Engineered Pest Management Agents (Hedm, P A , Menn, J. J , and Hollingworth, R. M , eds.), ACS Symposium Series, vol 551, no 5, American Chemical Society, Washington, DC, pp. 54-73. 8 Larson, L L , Sparks, T C , Worden, T V., Winkle, J. R., Thompson, G D., Klrst, H A., and Mynderse, J. S. (1996) Spmosad, the first members of a new class of Insect control products, the Naturalytes Proc. XX Znternatlonal Congress ofEntomology 19-009, 9
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Carlton, B. C. (1992) Development of improved bloinsectlcldes based on Bacdlus thuringzensis,m PestControlwzthEnhancedEnvironmentalSafe@(Duke, S O., Menn, J J , and Phmmer, J. R , eds.), ACS Symposmm Senes, vol. 524, no. 18, American Chemical Society, Washington DC, pp 258-266. Carlton, B C (1993) Genetics of BT insecticidal crystal proteins and strategies for the construction of improved strains, in Proceedings of the X&W Be&v&e Symposzum(Lumsden, R. D. and Vaughn, J, L , eds.), ARS, USDA, Beltsvdle, MD, pp 326-337 Jenkms, J. N. (1993) Use of Bacrllus thurlnglensls genes m transgenlc cotton to control lepldopterous insects (Duke, S 0 , Menn, J J , and Pllmmer, J. R., eds ), ACS Symposium Series, vol. 524, no 19, American Chemical Society, Washington, DC, pp 267-280 Tabashnik, B E (1995) Resistance to msectlctdes, Bacillus, and transgemc plants Pestle. Outlook 6(4), 24-27 Tabashmk, B. E , Malvar, T , Lm, Y-B., Finson, N., Borthakur, D., Shin, BS , Park, S-H , Masson, L., Maagd, R. A., and Bosch, D. (1996) Crossresistance of the DIamondback moth indicates altered interactions with domam II of Bacillus thurlngienszs toxins. Appl Environ Mlcrobzol 62(8), 2839-2844,
14 Feng, M. G., Poprawskl, T. J., and Khachatounans, G. G (1994) Production, formulation and application of the entomopathogemc fungus Beauverla basslana for Insect control. current status. Blocontrol SczenceTechnol 4, 3-34 15 Huber, J (1986) Use of baculovlruses m pest management programs, m The Bzology ofBaculovtruses, vol. 2 (Granados, R R and Fedenci, B. A , eds.), CRC, Boca Raton, FL, pp I8 l-202 16. Moscardl, F. (1988) Production and use of entomopathogens m Brazil, m Bzotechnology, Blologlcal Pesticidesand Novel Plant-Pest Resistancefor Insect Pest Management (Roberts, D. W. and Granados, R. R., eds.), Cornell University
Press, Ithaca, NY, pp 53-60
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17 Bonnmg, B C and Hammock, B D. (1996) Development of recombmant baculovuuses for insect control Ann Rev Entomol 41, 191-2 10 18 Kmg, L A , Possee, R D , Hughes, D S., Atkmson, A E , Palmer, C P , Marlow, S A , Ptckermg, J M , Joyce, K A , Lawrte, A M , Mtller, D P , and Beadle, D. J (1994) Advances m Insect vtrology Adv. Insect Physlol 25, l-73 19 Zorner, P S , Evans, S L , and Savage, S D (1993) Perspecttves on provtdmg a reallsttc techmcal foundanon for the commerctahzatton of btoherbtcrdes, in Pest control with Enhanced Envwonmental Safety (Duke, S 0, Menn, J J , and Plrmmer, J. R., eds ), ACS Symposmm Series, vol 524, no 6, American Chemtcal Society, Washmgton, DC, pp 79-86 20 Gaugler, R (1997) Alternative paradigms for commercializing btopesttctdes Phytoparasltzca 25(3), 179-l 82
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PROJECTIONS ONOPPORTUNITIES FOR BIOPESTICIDES IN CROPPROTECTION
2 The North American Scenario Jerry Caulder 1. Historical Trends and Highlights of Significant Advances The first glimmermg that microbes could be used to control msects is generally traced back to 1834 when Aogostmo Bassi discovered that a fungus, Beauveria basslana, caused an mfectious disease m the stlkworm. However, it was not unttl some 40 yr later that the first attempts were made to use insect pathogens to control pest populations, when Metchnikoff m Russia expertmented with A4etarhizium anzsoplzae for control of a beetle attacking wheat. Large scale attempts to use Insect pathogens took place in the Umted States toward the end of the 19th century, when a variety of pathogens were evaluated for control of the chmch bug (I). The tdentlflcatlon of bactertal pathogens of insectswas not far behind A key dtscovery took place in 190 1 when Ishiwata discovered a Bacdlus spp attackmg the silkworm Berliner discovered the same species mfectmg flour moths m Germany in 1915, and named the organism Bacrllus thurrng~ensu (Bt), after the German province of Thueringen (2), At the same time, others were looking elsewhere for novel ways to control msect pests and decrease the substantial crop losses they caused each year. Insecticidal chemicals were identified from a variety of sources,mcludmg such compounds as lead arsenate, as well as natural plant compounds, such as the pyrethrins and mcotme. In 1939, the era of the synthetic organic msecttctdes was ushered m with the discovery by Mueller of the msectictdal properties of DDT. The excellent efficacy and low cost of petrochemrcal-based compounds like DDT, coupled with then quack kill and broad spectrum of actrvtty, quickly made them the universal standards for controllmg Insect and mite pests. Research with biopesticrdes contmued to advance, with tdentification of new strains and species of pathogens and their metabolites. But it was not until the From Methods UI Biotechnology, vol 5 Btopesbodes Use and Dellvery Edlted by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
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1940s that the first btopesttctde product was commerctahzed m the Umted States, when a bacterial product based on Bacllluspoplllae was mtroduced for control of the Japanese beetle. In the 1950s the first Bt products were commercrahzed m the Umted States for control of a vartety of caterpillar pests attackmg crops and forests The greatest advances m the area of btopestrctdes have taken place wtth Bt products. These advances involved isolation of novel strams with htgher potency, as well as tdenttficatton of new strains producmg entirely novel toxms active on different pest species The tdenttficatton of Bt variety tsraelensts (3) as a potent mosqutto larvtctde suggested that Bt toxms could be active on a variety of targets. The 20 yr of research and product development that followed that key discovery have more than borne out those expectations At the same time, the revolution m molecular biology and genetic engmeermg allowed the unique and highly potent 6-endotoxms produced by Bt to be manipulated u-t a variety of ways that substanttally enhance then utthty and performance Some of these key advances are discussed m more detail below.
2. The Biopesticide
Conversion
As we look at the growing interest m bropesttctde-based products, tt 1s easy to see that a maJor trend m agrtculture today 1s a converston of pest management practtces from tradtttonal broad spectrum chemical pesticides to highly specttic btologtcally based products What has created and driven this btologtcal converston, and what are the prospects for btopesttctdes in North America? We can start by notmg the very different approaches involved m tdenttfymg new chemical pesticide leads vs new btopesttctde leads. On the surface, they appear quite stmtlar, because a great deal of drscovery and screening IS mvolved m both types of crop-protectron agents. However, the underlymg concepts are fundamentally different The chemtcal screening approach has htstortcally been very much an Edtsoruan search, i.e., a random screening of thousands of synthesized compounds for pesttctdal acttvtty. This has led to the development of many new compounds with excellent activity at a low cost to farmers Bropesttctdes, on the other hand, are based on btologlcal relationshrps, with mtttal tdenttficatton of a new class of actlves, typically resulting from tsolatton of a pathogen from the target pest or tts envtronment. Once a new active ingredient IS rdenttfied, then the development effort becomes very similar to the chemical approach, m that random screenings agamst insects are mtttated. However, even then, the screening 1s generally more targeted than for a chemtcal screenmg program Thus, the base concept of beginning with biological relattonshtps, such as pathogenests or antagonism, as a strategy for discovermg new acttves, means that the agents identtfted will generally be much more selective m their actton.
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Issues of environmental contammatton, worker and food safety, and nontarget effects from the use of chemicals are all derived from then nontarget actrvrty, and it 1sthese problems that are driving the development of alternatives such as the btopesttcldes. If biopesticides provide a safer, more selective form of insect control, then why do they account for only a fraction of the total pesticide market m North America and elsewhere’ Several factors limit the size and growth rate of btopestictdes Btopesttcidesgenerally lack the broad-spectrum activity, speedof control, residual life, and low cost of their chemical counterparts In the context of theseperceived limitations, biopesticides also tend to be more dtfficult to use, have shorter shelf lives, and tend to be more costly than traditional chemicals As a result of these challenges, penetration mto major insectictde markets has been limited There are at least two factors that will drive the growth of btopestrctdes. First, as society increasingly looks at the total value of a particular technology for pest control, this means lookmg beyond acute control and assessinghow a pest control product or group of products fits into the overall crop ecosystem, Another factor that will drive the growth of btopesttctdes 1sthe enthusiasm that 1scentered around biotechnology and the realization that the tools are available to improve effectiveness of btopesttcides while retammg then qualities of low environmental impact. 3. Use of Genetic Engineering to Enhance Biopesticides Has Become a Dominant Trend Begmnmg m the 1980s and to the present, a variety of molecular approaches has been used to improve market acceptance of bropestrcides. Early on, most of these efforts were directed at improving microbial msecticides, such as Bt, which has been in commercial use for over 40 yr (4). However, its use has been largely restricted to niche markets. Specific charactertstics that limit the wider use of Bt include hmtted host-range specificrty, inability to target cryptic feedmg pests, slow action compared to chemical msecticides, and lack of residual activity (4). Two general approaches were used to improve these charactertstics. One approach has been to transfer Bt toxins (genes) mto alternate mtcrobtal hosts, to address the issues associated with insect feeding or residual actrvtty. In 199 1, Mycogen (San Diego, CA) received EPA registration for the first two genetically engineered mtcrobial bioinsecticides, MVP@ and M-Trak@. These products consisted of Bt toxins that were produced and encapsulated m the host bacterium, Pseudomonas jluorescens. Recently, Ecogen has developed methods for homologous recombinatton with Bt This technology was used m the recent development of CryMax@ bioinsectrctde. These engineered microbial msecttcides do address such issues as spectrum of activity, residual hfe, and cost of product.
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4. Plant Expression of Biologically Derived Toxins Will Allow Penetration of Biopesticides Into Key Markets In North America, the largest msectlclde markets are associated with the control of insect pests m corn and cotton. The difficulty of blopestlcldes penetratmg these markets has to do with the biology of the primary insect pests.In corn, the primary insect pest 1s the corn rootworm complex, which IS comprised of several species wlthm the genera Diabrotzca. These larvae hve m the so11and cause economtc damage by feedmg on corn roots. Because of the solldwelling habltat, delivery of a mlcroblal product mto the feeding zone has been impractical or cost prohibitive. In cotton, the main pest 1sthe Heliothine complex. In North America, this complex consists of the tobacco budworm and bollworm. These larvae feed on parts of the plant, such as terminals and flowers, that rapidly outgrow msecticlde sprays. Larger larvae burrow mto bolls and become inaccessible to sprayed msectlctdes. For these insects, expression of the Bt toxin m the plant tissue may be the optlmal solution. Thts approach provides the ideal solution to the pesticide delivery issue and lack of residual activity The commercial impact of plants expressing Bt is just now bemg felt. 1996 marked the first sales of msect-reslstant transgemc corn by Mycogen and Cuba (Novartls), and insect resistant cotton and potatoes by Delta and Pme Land and Monsanto 5. Plant Expression Will Enhance the importance of Bt as a Source of Insect-Resistant Proteins The first insect-resistant transgemc crops entering the marketplace contam CryIA Bt toxms, which are active against a variety of lepldoptera Based on the initial demand for these crops, there IS every indication that the marketplace will demand crops that are resistant to other major insect pests. To satisfy this demand, additional insect active proteins will have to be discovered. Although blologlcally active proteins can and will be identified from many sources, it 1s likely that Bt will continue to serve as the primary source of insect active proteins for the near future. Strong current demand for Bt toxins is, in part, a result of their reputation for safety and efficacy. This demand will be met by the incredible diversity of toxin proteins that 1sproduced by Bt The pace at which new Bt proteins are being discovered 1s Illustrated by the fact that, m 1989, 14 toxin proteins were discussed m the classic Hofte and Whitely review (5); the latest Bt review, refers to over 100 Bt proteins (6). The discovery of this vast array of Bt proteins has important lmpllcatlons. One 1sthe ability to manage or delay resistance development. Resistance has not been a major problem with Bt msectlcldes, probably because of the limited use of these products Exceptions do occur when Bt usage IS particularly intense. A good example IS the use of Bt m cole crops to control diamondback
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moth. In tropical or semitropical areas, where growing seasonsare long, diamondback moth populations have developed resistance to CryIA toxins. Resistant populations have been isolated from insects m Florida, Hawaii, the Phihppmes, and Southeast Asia. Even though these insects are resistant to CryIA toxins, they still are susceptible to other Bt toxins, such as CryIC. Given the structural dtversity of Bt toxins, the author is optimrstic that additional protein families with no cross resistance ~111be identified. With an adequate number of noncross-resistant toxins, rotation and other use schemes can be developed to delay the onset of resistance. The challenge facing both industry and academia will be to reach an agreement over which management schemes are most appropriate. As more chemically diverse &endotoxms are discovered, the number of insects that are susceptible to these new Bt toxins is expanding. A case in point is the identtfication of Bt toxins that are active against black cutworm Black cutworm, Agrotis zpszlon, has traditionally been difficult to control with Bt toxins. Recently, the activity of two distmct Bt toxins has been repoited agamst cutworm (7,s). Similar progress is being made agamst recalcitrant Coleoptera, such as the corn rootworm (9). One can envision the impact that controllmg these two soil pests of corn ~111have on the overall msectrcide market, since over $300 milhon IS spent on chemical pesticides to control corn soil pests 6. Field Performance: Examples and Role in IPM Implementation Another key problem associated with the use of broad-spectrum chemicals has been then- impact on the crop ecosystem. Dependence on these materials has often created an unstable situation in agricultural pest management. Insecticide resistance, combmed with lethal effects on natural enemies, has resulted in pest resurgence and secondary pest outbreaks. The concept of integrated pest management (IPM) was developed in the 1950s and 1960s to address these agronomic problems, as resistance to DDT and organophosphate msecttcides began to cause crop failures m cotton and other crops m a number of countries IPM is an ecological approach to pest control that requires selective agents that are effective on target-pest species, yet preserves natural enemies and retains their contribution to overall control. Btopesticides are the most selective of currently available pest-control agents. As we commercialize a greater diversity and number of blopesticrde products, we Increase our potential to develop effective and comprehensive ecologically based IPM programs that will provide farmers with the greatest value, efficacy, and sustainability. Biopesticides have delivered great benefits to growers when used m IPM systems in a variety of crops. In fresh market tomatoes in Caltforma, for example, Trumble et al. (10) compared total input costs and yields achieved, under a standard conventional treatment regimen that used 7-8 applications of
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methomyl and permethrm, to an IPM program that used 3-4 applications of a Bt product. In these trtals, conducted m 1992 and 1993, the IPM program provided net profits equal to or better than those obtained with the chemical standard treatment. In replicated commerctal trials conducted in three valleys of Smaloa, Mexico, m processed tomatoes, Trumble and Alvarado-Rodriguez (21) evaluated an IPM program based on regular sampling and action thresholds The IPM program used a Bt product, a mating disruption pheromone product, abamectm, and releases of egg parasites. The IPM program was compared to a conventional program using chemical msecticldes applied 35 times m what was designed to be the best approximation to conventional grower practices. The results of these season-long trials showed that m the autumn planting the IPM program yielded net per-acre profits that were $304-579 higher than the conventional program. During the winter and spring plantings, only the IPM program was profitable Subsequent to these trtals, Alvarado-Rodriguez began implementmg this IPM program on a number of farms m Smaloa, Mexico, and m Florida, Honduras, and Nicaragua. On these farms, sigmficant yield increases have also been realized, compared to conventional practices. IPM programs like this one are showing that biopesticides can deliver excellent value, not only m addressing environmental and safety concerns, but m providing farmers with the agronomic and economic benefits of lowered input costs and higher yields. Thus, one can see that the bioconversion of agriculture IS being driven by a fundamental shift, not Just m the types of agents used, with a strong movement to biopesttcides and pest-resistant transgemc plants, but also m the systems m which these innovattve biotechnology products are being employed. As mentioned, the biopesticide industry has completed its first season sellmg Bt corn and one season sellmg Bt cotton. Bt corn, which expresses toxins to control European corn borer, has performed quite well. Likewise, growers using Bt cotton needed fewer msecticide applications than growers that planted conventional cotton. However, during the 1996 growing season, there was some concern over the efficacy of Bt cotton. The problem was greater than normal bollworm populations. The reduced efficacy of Bt cotton against high populations of bollworm was demonstrated prior to the commercial launch (12). Nonetheless, the need for additional insecticide use took many people (farmers, researchers, and the press) by surprise. This situation illustrates the importance of an IPM mmdset as opposed to the mmdset that accompanied the mtroduction of synthettc msecticides in the 1940s and 195Os,when application of an msecticide was thought to be the complete solution to a pest problem.
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7. The Future Looking forward, tt seemsinevitable that the transition to btologtcally based pest control practices wtll contmue. A major driving force impactmg agriculture IS the exponential rate of population growth that will produce a population of over 6 billion people by 2000. The impact that this growth will have on entomology and agriculture IS multifold (13). As the populatton increases by 1 billion every 10 yr, there will be extraordinary demands on our ability to produce food and fiber Most of the population growth is taking place m less developed countrtes. Although populations are more stable m the more developed countrtes, acreage devoted to agriculture IS decreasing. The challenge to both private and pubhc sector researchers must be to find addmonal ways to Increase agricultural productivtty m the face of an increasing populatton and decreasing acreage. The rate of population growth necessitates mcreasmgly efficiency m moving research ideas into the marketplace. An important trend IS the formatton of consortta and alliances between research efforts m public and private sectors, These alliances allow groups to focus on key research goals and make progress in a timely manner This trend must continue. Pesticide safety has been an important consideration for many years and will continue to drive btoinsecttcide growth. People have a reasonable concern about pesticides in then diet and environment. The issue of environmental quality 1swell established m more-developed countries. Stated simply, people do not want synthetic chemical residues m their foods. This issue 1s as much a perception as it IS a true toxtcology issue. As the population density increases, environmental quality ISlikely to become a more important issue m more countries, regardless of their state of economic development. Absent significant changes m current practices, nontarget effects of pesticides have an mcreasingly significant impact on environmental quality. One consequence of the increasing populatton and urbanization of farmlands is the increased contact between people and agricultural production. As this increase contmues, the safety of synthetic insecticides will become a greater issue. Biopestlcides effectively address the issues of environmental quality and safety. Since the active ingredients m biopesttcides exist in the natural environment, there 1sa greater level of comfort or a greater perception of safety. As progress m brotechnology and the discovery of new Bt toxins continue, people can look forward to increased use of biopestrcides and btologlcal toxins expressed m transgemc plants. People will have to ask how best to use these tools For example, should biopestrcides be deployed as synthetic msectrcrdes? Are pest-resistant transgemc plants an example of scheduled spraying taken to an extreme position? Alternatively, should these tools be used as part of an overall management strategy that includes parasltolds, predators, and pathogens, as outlined m the early IPM concepts proposed by Smith and van den
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Bosch (14) and others. The selecttvtty of bropestrcide and pest-resistant transgenie plants are complimentary for preservation of predatory msects.Moreover, the sublethal effects of biopesticides may actually mamtam predator populations (15). The integration of transgenic plants mto IPM is also an important Issue. On the surface, the scheduled spraying model for both bropesticides and transgemc plants may seem lakea good Idea. However, there are undesirable consequences, such as resistance development. Would it be better to use these plants m the context of IPM, in which the selectron pressures of a toxin expressed m plants are made less intense? These biopestrcide and transgemcs plants will play an important role. Their rmplementatton will require the coordmated actions of manufacturers, academics, growers, and private consultants.
References I Madehn, M. F. (1963) Diseasescaused by hyphomycetous fungi, tn Insect Pathology, vol 2 (Stemhaus, E A , ed ), Academic, New York, pp 233-272 2. Luthy, P , Jaquet, F., Huber-Lukac, H. E , and Huber-Lukac, M. (1982) Physiology of the delta-endotoxm of Bacrflus thurmgzenszs mcludmg the ultrastructure and histopathologrcal studies,in Basic Bzology of Mlcroblal Larvzczdes of Vectors of Human Dzseases (Michal, F , ed ), UNDP/World Bank/WHO, Geneva, Switzerland, pp 29-36 3 Goldberg, L H and Margaht, J (1977) A bacterral spore demonstratmg rapid larvrcrdal activity against Anopheles sergentu, Uranotaenla unguzculata, Culex unlvattatus, Aedes aegyptz and Culexprplens Mosq News 37,355-358. 4. Gelernter, W. and Schwab, G E (I 993) Transgemc bacteria, vu-uses, algae and other microorganisms as Bacillus thurznglensls toxin delivery systems, in Bacillus thurmgrenszs, An Environmental Blopesttclde Theory and Practice (Entwistle, P F ,
Cory, J. S.,Bailey,M. J., andHrggs,S , eds), Wiley, Chrchester,UK, pp. 89-104 5 Hofte, J and Whiteley, E B. (1989) Insectrcidal crystal protems of Bacillus thurmglensu. Microblol Rev 53,242-255 6 Schnepf, E , Crickmore, N , Van Rie, J , Lereclus, R , Baum, J , Feitelson, J , Zergler, D. R , and Dean, D. H (1997), manuscript m preparation. 7. Estruch, J J , Warren, G. W , Mullms, M A , Nye, G J , Craig, J. A , and Kozrel, M G (1996) V1p3A, a novel Bacillus thurmgiensis vegetative msecticidal protein with a wide spectrum of actrvities against lepidopteran msects Proc Nat1 Acad Scl 93,5389-5394
8 Lambert, B., Buysse,L., Decock,C , Jansens,S , Piens,C , Saey,B., et al (1996) A Baccllus thurlngzensls msectrcrdal crystal protem wrth a hrgh activity against members of the family Noctmdae. Appl Environ Microbzol 62, 8&86 9 Fertelson, J. S , Payne, J., and Kim, L (1996) Baczllus thurzngzensls insectsand beyond. Bzo/Technology lo,27 1-275. 10 Trumble, J T , Carson, W G., and White, K K (1994) Economic analysis of a Baczllus thurzngzensu-based Integrated pest-management program m fresh-market tomatoes. J Econ Entomol 87, 1463-1469
North Amencan
Scenario
21
11 Trumble, J T and Alvarado-Rodriguez, B (1993) Development and economtc evaluation of an IPM program for fresh market tomato productlon m Mexico Agriculture Ecosystems Environ 43,267-284 12 Mahaffey, J. S , Bacheler, J S., Bradley, J. R., and Van Duyn, J W (1994) Per-
formance of Monstanto’s transgemc B t. cotton agamst hrgh populations of Lepropterous pests m North Carolma, m Proceedmgs Beltwzde Cotton Conferences, pp 1061-1063. 13 Metcalf, R L (1996) Applted entomology m the twenty-first century Am Entomol 42,2 16-227 14 Smtth, R F and van den Bosch, R (1967) Integrated control, m Pest Control Blologlcal, Physical and Selected Chemzcal Methods (Kllgore, W. W and Doutt,
R L , eds ), Academx, New York, pp. 295-340 1.5 Soares, G G., Lewts, W J , Strong-Gunderson, J. M., Waters, D. J , and Hamm, J J.
(1993) Integratmg the use of MVPB bromsectxlde, a umque Bt-based product, with natural enemies of Noctmd pests. a novel concept m cotton IPM, m Proceedzngs of the 2nd Canberra Bacdlus thurmgzenszs Meeting, pp 133-145
3 Microbial
Biopesticides
The EuropeanScene Tariq M. Butt, John G. Harris, and Keith A. Powell 1. Introduction There 1s growmg interest in the explottatton of naturally occurrmg mtcroorganisms for the control of crop pests, weeds, and diseases.Btologtcal control agents (BCAs) may offer more environmentally friendly alternatives to chemical pesticides.They could also be used where pestshave developed resistanceto conventional pesticides.Unfortunately, there 1scomparattvely httle investment m the research and development of these organisms compared with that spent on the discovery of chemical pesttctdes.Two reasonsfor this are that microbial pesticides usually have a narrow host range, and that they often give mconststentand poor control in field trials. Consequently, more attentton 1sbeing given to the selectton of broad-spectrum blopesttcidesand improvements m production, formulation, and apphcatton technologtes. Efforts are also being made to opttmtze the impact of these agentsby mtegrating them with other novel crop protection strategies(I). One factor that cannot be ignored is the market potential of btopestictdes.Currently, only speciahzed,niche markets exist. Their full potential has not been realized because of the absenceof strong mcentrves to develop these agents and/or discourage chemical pesticides;availabrlity of new, biodegradable chemical pestlcrdes; absence/breakdownof the mfrastructure that facilitates transfer of new technologles and research knowledge to the end user (i.e., grower); absence of a universally acceptable regrstratron procedure; restrtcttons in the use of exottc BCAs; and lack of robust and reliable field effects Progress is also slow because the chtef producers are often small-medium-size enterprises(SMEs) that have hmtted resources for effective development and marketing of products. From Edited
Methods m B~olechnology, vol 5 Blopeshodes by F R Hall and J J Menn 0 Humana Press
23
Use and Dehvery Inc , Totowa, NJ
Butt, Harris,
24
and Powell
Fungicide 20% Herbickie 49%
hectic
Fig. 1. The share of crop protection in each of the major sectors of the world market.
Europe
Fungicide 30% Herbii5e 48%
Insecticide 22%
Fig. 2. The European Market share for fungicides, insecticides, and herbicides.
Figure 1 showsthe current shareof the agrochemicalmarket worldwide for insect, fungal, and weed control. For convenience, insecticides also include nematicides and
molluscicides.The Europeanmarkethasa different shape,with plant pathogensbeing more important and insectcontrol being a more minor component (Fig. 2). Clearly, from thesefigures, one might expectthe development of biological control for plant pathogensto have beencenteredin Europe. There is, however, little evidence of this. The useofBacillus thuringiensis (Bt) for control of insectshasbeendeveloped mostly in the United Statesand Canada.It is in the key cotton crop that B&derived genes have beenused to provide crop resistanceto insects. A wide range of BCAs have or arebeing developed ascommercial biopesticides produced in Europe, often with global markets in mind. In order to survive, many SMEs market products of other companies or produce BCAs under license. Presumably, this mutualism will decline as the use of BCAs increases(i.e., the market expands) and it becomes more lucrative for individual companies to develop their own agents. 2. Formulation and Delivery For any crop-protection agent, an efficient formulation is a necessityto translate laboratory activity into adequate field performance. The formulation must
Microbial
Biopesticides:
European
Scene
25
be mtrmsrcally compattble with the BCA, and, ideally, the formulated maternal should have superior performance compared wtth the unformulated material (2) For BCAs, there are particular challenges to be faced, because the active ingredient 1sfrequently a living organism that must be kept relatively tmmobile and inactive while in storage, but quickly resume its normal metabohc processes once applied to the target site To achieve this, some form of drying process ts usually done, such as an-drying, freeze-drying, or lyophihzation. A preservative, such as Proxel (1,2-benzisothtazohn-3-one), will often be mcorporated to prevent microbial contammatton Subsequent formulation IS then usually as a wettable powder, water-dispersible granule, or dust. Another approach is suspension in oil, m which the purpose IS to exclude oxygen from the organism, thus preventing respiration. An example is the Bt subspp kurstuki insecticide formulation Dipel ESNT, in which the actrve ingredient is encapsulated and then suspended in an 011base Moore et al. (3) found that dried comdra stored m 011formulatrons remamed viable longer than those stored as a dried powder, especially If stored at relatively low temperatures (IO-14 vs 28-32OC). Additton of sihca gel to oil-formulated conidia prolongs then shelf life. Undried conrdra of Metarhzzzum jluvovinde, without sthca gel, lose viability rapidly, with germmatron droppmg below 40% after 9 and 32 wk at 17 and 8°C respecttvely. After 127 wk in storage, germination remained at over 60 and 80% for the drred formulations at 17 and 8°C respecttvely (4). These comdra were found to have retained full vtrulence, compared with freshly prepared formulattons. Furthermore, conidta dried to 4-5% morsture content showed greater temperature tolerance than conidia with higher motsture content. McClatchie et al. (5) report that htghtemperature treatments caused delay in germmatton, as well as death of A4 flavovzrzde comdia. However, drymg comdta by adding sthca gel to 011 formulatrons greatly increased temperature tolerance Desprte thus, formulatrons composed of living cells still suffer sigmficant degradatron over trme, and this IS a problem that still needs to be solved. This IS a particular issue for the nonspore-forming bacterta and fungt The situation is rather easier wrth spore-forming organisms. Restmg stages, such as spores, are desrgned to retam water, be robust, and survive m a viable state, even when subjected to harsh envtronments. Nucleopolyhedrovrruses also produce propagules that are encapsulated with polyhedrin, giving them a tough, reststant coatmg that facthtates survival These types of organisms are, therefore, more easily formulated, and ltqurd products, such as suspension concentrates, are quite feastble. Equally important, the formulation type and packaging materials must be broadly similar to those wtth which the grower 1s already famthar. The products should be capable of application through the standard hydraulrc sprayer or
26
Butt, Hams, and Powell
applicatton equipment that 1scommon to a partrcular market, and have as few unique requirements as posstble A grower IS unhkely to mvest m new spray equtpment solely to treat a BCA, nor 1s he going to accept a very different spray regime or more frequent apphcattons than 1snormal practice. The grower will also want to purchase his BCAs through the same dtstributton chain as hts agrochemtcals. Yet, a distributor is not going to be happy to have to handle BCA formulations differently from his normal chemical stock. The dtstributor will expect the product to be packaged m standard sizesand types of contamers, as used throughout the agrochemtcals mdustry Storage stabthty must be such that product purchased at the start of one seasonIS good for the whole of that seasonand the next, without any special storage requirements. If the shelf hfe of a BCA forrnulatton ISvery limited, then a distributor may only be prepared to buy small quanttttes,thus hmitmg avatlabthty, or will only stockproduct on a consignment basts,which is a major mconvemenceto the BCA supplier Also, some BCAs have a specific need for refrigeratton, but very few dtstrtbutors m Europe have such facthttes, and even fewer would be prepared to invest m them. Finally, the BCA formulation must be composed of safe materials One of the mam features of BCAs is their perceived safety benefits to the envtronment, beneficials, nontargets, and, of course, the applicators. These benefits would be negated tf toxic formulatton components were used m the product. If the product 1stargeted at a fohar pest or disease, then addtttonal problems are subsequently encountered. All the usual requtrements for successful fohar treatment need to be met, mcludmg good sprayabtlity, no nozzle blockage, good leaf deposttton and dtstributton, and adequate rainfastness. In order to achieve these attributes, surfactants, stickers, and wetters must be mcorporated mto the formulation or applied m tank mixture. One of the chief causes of macttvation of many BCAs on the leaf surface 1sthe effect of ultravtolet (UV) radiation. High levels of UV can lead to rapid degradation of the material, perhaps wtthm a single day. Mtcroencapsulatton of the BCA has been one approach to overcome this problem, although this IS technically difficult and quite expensive to manufacture. Another technique that has been used, particularly with baculovnuses, is to incorporate mto the formulation or tank mtx an optical brightener. These brighteners may reflect UV or reduce its impact by disstpatmg the energy as fluorescent light and heat. But they can only protect the BCA when they are m the immediate proximity of the organism Because this is hard to achieve when simply admtxed mto the formulation, results with this approach have been highly variable. To exploit this technology effectively, ways have to be found to keep the brightener or other UV protectant materials m mtimate contact with the BCA. Also reported are the usage of otlbased formulations, which have proved to be beneficial to UV protection of comdta of M flavovmde (4,6,7)
Microbial
Biopesticides:
European
Scene
27
In the case of mrcrobtal msectlcides, good drstrtbutron over the leaf 1sessential, because they are nonsystemtc materials, and must come m contact with, or be consumed by, the target insect, m order to deliver a toxrc dose Feedmg attractants incorporated mto the formuiatron may be useful to encourage Insects to feed on the BCA (8), and Bt products are frequently tank-mixed wrth 2 kg/ha of sugar for fruit and vme pests in Europe, with good reported effect In other cases,some very specrfic additives can have a positive effect For example, the LD,, for some formulatrons of Beauveria basslana was reduced by 97% by the addrtron of coconut 011.It was suggested that the cutmophtlic propertres of the or1 could allow a greater number of fungal comdta to penetrate the mouth parts of the insect (9) 011 carriers can also distribute the moculum over the insect cutrcle, often carrying the comdta to the thm mtersegmental membranes, which are more readily penetrated by entomogenous fungr (Butt, personal observation). A different series of prtortttes come mto play when devrsmg formulattons for the control of soilborne pests and diseases Placement of the BCA IS of prime importance, to ensure that dlstrtbution through the soil 1s even, and, therefore, there IS a good chance that the BCA and the pest or pathogen will come in contact with one another. Preplantmg, BCAs can be applred as granules m-furrow, and by drench apphcatton On a small scale, such as m glasshouse sttuattons, material can be thoroughly incorporated Into the so11 Postplantmg, a drench applicatton or irrrgatron can be employed to take the BCA mto the son. Seed treatment may also be an option, although most seed tend to recetve a chemtcal fungrcide to control seedborne drseases, and these treatments can often be antagomstrc to BCAs. 3. Biological Control of Plant Pathogens Biological control of plant pathogenic fungi has long been an ambttton for academic and industrial researchers. However, there IS little evidence of major breakthroughs m the marketplace. The issues and problems have been dealt with m many publlcattons (IO). There are products that are avatlable for both soilborne and foltar pathogens, as well as considerable research on postharvest disease(11,12). Several products are or have been registered m Europe (Table 1) Current products are shown in Table 2. Although the products listed m Table 2 are commercially avarlable, the total sales of btological agents for crop protectron agamst plant pathogens amounts to much less than 1% of the fungrcrde market m Europe. The problem faced by developers of brologrcal agents for control of disease are complex and drfficult. Crops are grown under a variety of chmattc and environmental conditions, and temperature, rainfall, sot1type, crop variety, and
2
Fmland, Sweden, Norway
Adapted with permIssIon from ref. 33.
(= Penzophora) glgantea
Phlebropsrs
Country
for Biological
Netherlands Sweden, France United Kingdom
in Europe
Vertlc&um dahliae Truzhoderma harzlanum Trrchoderma wnde
Registered Finland, Hungary, Norway,
Agents
Streptomyces grzseovwzdzs
Agent
Table 1 Some Microbial Switzerland
Control
Target pathogen Fusarwm spp, Alternana, Pythlum, Botrytq and other so11 pathogens Agamst Dutch elm disease Sell-borne fungal diseases Antagonist to silverleaf fungus (Stereum purpureum) Fomes annosus
of Plant Diseases
Kemrra Agro Oy Kemu-a Agro Oy Gustafson Various Ecogen Ecogen Natural Plant Protectron (NW Various
GlioMix Mycostop Kodiak Vanous AQlO Aspire Fusaclean Various
Truzhoderma viride
Supplier
Control
Kemrra Agro Oy
Commercial name
Sold in Europe for Biological Rotstop
Products
Phleblopsls (= Penrophora) gigantea Ghocladmm sp Streptomyces grrseovwldls Bacillus subtills Agrobacterlum radlobacter Ampelomyces quzsqualls Candida oleophda Fusarlum oxysporum FO 47
Product
Table 2 Some Commercial
Wood treatment
Promotes plant growth, competes wrth soil microbes Fusarwm spp and other sod pathogens Soil pathogens Agrobacterium tumefaclens Powdery mildew Postharvest decay of citrus and apple Fusanum oxysporum, F momliforme
Fomes annosus
Target pathogen
of Plant Pathogens
30
Butt, Hams, and Powell
pathogen can change from farm to farm, or even within one field The producer of a crop protection product has to be able to give some assurance to the farmer that the product ~111 be robust, m order for the product to be used. The avallablllty of effective chemical controls for fohar pathogens has made it unlikely that a biological agent will compete effectively It is, therefore, not surprlsmg that the maJorrty of efforts m research has been concentrated on sotlborne or postharvest diseases Even m these situations, the lack of robustness has hmlted the penetration of such products. When success has been achteved, it has been m limlted crop-pathogen mteractlons, and has often been specific to crop, pathogen, and growmg sltuatlon The control of Agrobacterzum tumefaclens by the closely related bacterium Agrobactenum radzobacter (13) IS a classic example. The bIologIca agent IS apphed to unmfected roots of cuttings, and 1s then allowed to colomze the niche that would normally be at risk from the pathogemc species The success of this treatment may be enhanced by the productlon of a specific antlblotlc that mhlblts growth of the pathogen An lllustratlon of the problems faced m control of disease under more varied condltlons was provided by the excellent work of Defago et al. (14). This group showed that the sol1 environment played a key part m the ablhty of Pseudomonasfluorescens to control black root rot of tobacco One so11 type showed excellent potential for disease control, but a second negated the effect of the bacterium The application of nonpathogenic strains to control pathogenic fungi has been demonstrated by the work of Alabouvette et al. (15) Nonpathogemc Fusarzum oxysporum llmlted disease caused by pathogemc Fusarzum. the suppression was linked to the ratio of density of the nonpathogemc population m relation to the pathogenic species. The nonpathogemc strams compete with other mlcroorgamsms for nutrients and elicit a defense response m the plant, which protects It agamst more aggressive strains of Fusarzum Trlchoderma harzlanum and T wide have been proposed by various groups as potential BCAs. Trzchoderma sp appear to have the ablhty to rapidly colonize clean surfaces, such as compost or freshly cut timber Several products have been available, but the market share has been mmlmal. One problem may be the lack of competltlve ablhty of these species when apphed to so11or other media with an active mlcroblal population. One exception 1s GhoMlx, which IS a formulation of the fungus Glzocladzum. This product promotes plant growth and, presumably because of its rapld growth, the fungus prevents establlshment of potential disease-causing microbes. Antagonists of postharvest diseases share some of the attrlbutes of the above For example, the success of Epicoccum nlgrum, Penlcllllum oxalicum, and Candzda sake, which are bemg developed to control Monzlwzza laxa (brown rot
Microbial
Blopes ticldes:
European
Table 3 Factors That May Affect the Success
Scene
31
of BCAs for Plant Pathogens
Factors affectmg long-term survival Physlcal Soil type Matrtc potential Temperature PH Blottc Ablllty to colonize substrate Competition Survival structures Host genome Resistance of pathogen to BCA
Factors affectmg speed of effect BCA Germmatlon and recovery time Release from formulation Speed of growth Movement to site of actlon Pathogen Growth rate Degree of mche protectton Productlon of toxins
Adapted with permlssron from ref. IO
of peaches and other fruit), Fusarzum oxysporum fsp lycopersicz (tomato wilt), and Penzczllium spp, respectively, IS dependent upon their ability colonize the
fruit surface raptdly and displace the disease. Antagomstlc yeastsalso produce extracellular materials (mostly polysacchandes) that not only enhance their survival, but also restrict colomzation sites and the flow of germmatlon cues to other fungal propagules. Bacterial antagonists like Badus subtzh produce antlblotlcs (e.g , Iturm), which mhlblt diseases hke the brown rot pathogen Monzlznza fructzcola. The exact mechanisms of antagonism are poorly understood, but involve a complex of attributes, including nutrient competltlon, site exclusion, attachment of the antagonist to the pathogen, secretion of pathogemcity-related enzymes, induced resistance, and antlblosls caused by the actlon of bloactlve compounds Table 3 illustrates the issuesfaced when attempting to develop a BCA for so11 diseases,and shows quite clearly the need to take Into account many factors when considering the potential for a new project in this area. Given the difficulties listed above, the lack of commercial successfor blologlcal control IS perhaps not surpnsmg. It 1snevertheless possible, as demonstrated by Rlshbeth (16) m the control of Fomes anrzosus by Phlebzopszs (= Penzophora) gzgantea In this sltuatlon, the cut tree stump is inoculated with the blologlcal agent immediately after cutting. The control ISachieved becausethe substrateIS rapldly colonized by the control agent and the pathogen 1sunable to enter and thus Infect the nearby trees via the root system.This example shows clearly that specificity, competition, and growth rate are all important This lessonshould be heededby all those tempted to embark on a new project for biologtcal
control
32
Butt, Hams, and Powell
4. Biological Insecticides: Field Performance and Role in IPM Implementation 4. I. Mycoinsecticides Some of the pathogens that have been or are being developed for the control of insect pests belong to the fungal division Deuteromycotma, class Hyphomycetes (Table 4). The most common species are Metarhlzzum anzsopliae, Beauverla basslana, Paecdomyces fumosoroseus, and Vertdlwm lecarw These can be readily isolated from soils from most parts of the world, and are known to have a wide host range, but strains can doffer m then- specificity and virulence (I 7,18). Fungi, unlike bacteria and vnuses, do not have to be ingested to cause infection, but can penetrate the insect cuticle directly, using a combtnation of enzymes and mechanical (18-20). Once the pathogen has gained accessto the nutrient-rich hemocoel, the fungus may grow as thin-walled blastospores or hyphae. Most strains secrete htstolyttc enzymes and msecttctdal metabohtes. The latter can disorient the host, stop It from feeding, and cause death before mycelial colomzatton of the hemocoel 4.1.1. Verticdlium lecanll The fungus, Vertzczlliumlecanu, has been developed as a btomsectlctde for the control of aphids, whiteflies, thrtps, and red spider mites Christian Hansen’s BIO Systems were particularly acttve developmg the product for usage m Scandinavta, as MtcroGermin (21). The fungal spores are dried to form a wettable-powder formulatton, whtch can be mixed with water to produce a suspension suitable for immersion of plant cuttings. Shelf life ISclaimed to be 6 mo at 5°C. The chief market has proven to be the protection of glasshouse cuttings by dipping, prior to potting. Aphids and whttefltes can be a major problem m glasshouse plants, and, m such a closed envtronment, reststance to chemical msectictdes tends to develop quite qutckly. MtcroGermm offers an effective alternattve to chemicals m what 1s a high-value market, Potential outside of a glasshouse environment is limited, however, because the fungus reqmres a relative humidity of between 95 and 100% for at least 10-12 h to germinate effectively and colonize the insects. Late in 1995, the Dutch company, Koppert, purchased Christian Hansen’s Bio Systems. Koppert already had a similar product m then range, called Mycotal, and so it IS expected that efforts will be made to market a single product for other northern European glasshouse markets alongside then- extensive product range of predators and biocontrol agents. 4.7.2. Beauvena and Metarhizium Wlthm each genus, there are two species that have been examined for biological control potential. Beauveria bassiana and B. brongmartiz have been
Fungus
of Mycoinsecticides Pest insect Whltefly and thrlps Aphids Vine weevil Coffee berry borer Sugar cane white grub Corn borer Colorado beetle Colorado beetle Colorado beetle Cockchafer Cockchafer Cockchafer Locusts, grasshoppers Whitefly
in Europe
aReglstered, but not on sale, other products under development ‘Some commentators suggest quite large scale use (>lO,OOO ha), but this has been disputed (34). =From ref. 34 dUnder hcense from ThermoEcotek (now Therm0 Tnlogy)
Vertlcdlwn lecanu V. Iecann Metarhizlum anlsopllae Beauvena basslana Beauverla brongnlartn Beauveria basslana B. bassiana B. bassiana B basslana B. brongnlartii B. brongnlartti B brongnlartu Metarhlzlum flavovirlde Paecllomyces fumosoroseus
Scale Production
Mycotal Vertalec BIO 1020” Comdla Betel Ostrinil Bovenn Boverol Boverosil Engerlingspllz Schweizer-Beauvena Melocont Green Muscle PreFeRal
Product
Table 4 Commercial
Koppert, Holland Koppert, Holland Bayer, Germany AgrEvo, Germany NPP (Calliope), France NPP (Calliope), France Former USSRb Czech Republic/Slovaklac Czech RepublicYSlovakla” Andermatt, Switzerland Eric Scwelzer, Switzerland Kwlzda, Austria CABI, UK Biobest, Belglumd
Producer
34
Butt, Harris,
and Powell
the focus in this genus, and these species are known to produce a cyclodepsipeptide called beauvericin, which is toxic to insects. Similarly, Metarhizium anisopliae and M. flavoviride produce related insecticidal metabolites called destruxins. These toxins play an important role in the pathogenicity of the fungus, and probably help to disable the insect’s self-defense mechanisms while the fungus invades and colonizes the hemocoel. In Switzerland, a biological method to control the subterranean pasture pest, Melolontha melolontha, with the insect-pathogenic fungus B. brongniartii was developed during the 1980sand the pathogen was registered in 1990. Since then, approx 5000 kg are applied per annum to 100-I 50 ha of mostly pasture. Another strain of this fungus has been developed by Natural Plant Protection (NPP; France), and is sold under the commercial name Betel for the control of the sugar cane white grub (Hoplochelus marginalis, Melolonthinae) in the tropics. NPP also developed a strain of B. bassiana for the control of European corn borer, Ostrinia nubilalis (Table 4). Both pathogens are produced using solid fermentation technology. The pathogenis formulated in clay granules and applied at 25 kg/ha (Ostrinil) or 50 kg/ha (Betel). According to the manufacturers, the granules are applied in the sameway as chemical granules. Both products are stable for 1 mo at 35”C, but the shelf life is increased at lower temperatures. In Germany, Bayer AG developed BIO 1020, a strain of M. anisopliae for the control of Otiorhynchus sulcatus (black vine weevil) (22). This pest is a major problem on several ornamental crops in glasshouses and nursery stock. The product consists of dry granules with a claimed shelf life of 6 mo if kept in cool conditions. The granules are admixed with soil, and, following water uptake by the granules, the fungus produces large numbers of conidia that are viable for many months. Insects become infected when they come into contact with these conidia. This does mean, however, that the application must be of a preventative nature, but, because of the long survivorship of the conidia, satisfactory protection should be achieved for the whole duration of the crop. The recommended rate of the formulated product is 1 g/L soil, at which good levels of control of 0. sulcatus have been seenon a number of glasshousecrops (Fig. 3). Such a product has an excellent fit with other predators, parasites, and microbial agents for glasshouse crop protection. Recently, the use of M anisopliae has been reported for the control of western flower thrips, Frankliniella occidentalis (23). Strains of this fungus have also been shown to be highly pathogenic to several crucifer pests, yet is harmless to honey bees (17). In both instances, conidia were formulated in either aqueous solutions or oil, and were applied to leaf surfaces using conventional and/or electrostatic sprayers. Poor control can be attributed mostly to low temperatures and humidities, which will prevent spore germination and infection. In addition, UV light will
Microbial Biopesticides: European Scene
Azalea
I
Fuchsia
Chrysanthemum
I
Cyclamen
Begonia
Fig. 3. Effectiveness of BIO 1020 against Otiorhynchus sulcatus eggs and larvae in ornamentals under glasshouse conditions 28 d after treatment. (Adapted with permission from ref. 22.)
quickly inactivate spores, and leaf expansion and rain will dilute the inoculum on the leaf surface. Overcoming these factors will greatly improve fungal efficacy. Equally important is maximizing spore viability and ensuring better contact of the inoculum with the insect surface, because mortality is dose-related. The speed of kill (LT,,) is also dose-dependent (17,241. The more inoculum contacting the pest, the shorter the time to death. Selection of virulent, ecologically competent strains, combined with improved formulations and more effective targeting of the pathogen, will lead to more efficacious pest control. At IACR-Rothamsted, a push-pull strategy, based on the use of semiochemicals, is being developed in which pests are encouraged into trap crops or discard areas, where they are inundated with fungal pathogens. When developed, this strategy should greatly reduce the use of chemical pesticides (I). 4.2. Bacteria Only two species of bacteria have been developed for control of insect pests: Bt and B. sphaericus (Table 5). Products based on the different strains of Bt are the most widely used biological control agents in Europe. Bt subspp kurstaki (Btk) is used to control lepidopterous pests in vegetables, tomatoes, top fruit, vines, olives, and forestry. An example of the latter, in a major Polish forestry project, is described below.
Table 5 Insect-Pathogenic Active ingredient Bt serotype 3 Bt subsp azzawaz Bt subsp kurstakz Delta endotoxm of Bt subsp kurstakz Bt subsp tenebrionzs Bt subsp zsraelenszs Baczllus sphaerzcus
Bacteria
and Toxins
Registered
Registered uses (pest/crop) Wide range of crops and orchards Lepidopteran larvae Lymantria,
Ostrznza
Lepidopteran pests Coleopteran larvae Dipteran pests Mosquito larvae
in Europe Country
France France, Germany France, Germany, Hungary, Italy Austria Austria, Germany, Hungary Finland, France, Germany, Hungary Italy, Netherlands, Sweden France
Adapted with permtsslon from ref. 33
Poland IS a major softwood producer. Forests cover about 8.8 mullion ha, approx 30% of the land mass, and are a major earner of foreign currency. Protecting this resource is clearly a very high priority, especially because there are at least five sertous lepidopteran pests that can cause significant losses. Nun
moth (Lymantrza monacha) IS the most serious of these pests m Polish comferous forests. The larvae are major defoliators, feeding particularly off young leaves. Infestations are usually cyclical, with serious outbreaks occurring about every 50-60 yr. Unexpectedly, though, in the spring of 1994, over 600,000 ha of Polish forestry became seriously infested. This had not been predicted, since the last serious outbreak had only been 12 yr earlier. Polish scientistswere of the opmlon that the usage of broad-spectrum chemical insecticides to control the previous outbreak had made the forest more vulnerable to attack (25). It was postulated that the msecticide treatments had also elrmmated key parasites and predators of the nun moth, thus enabling the pest to increase m numbers more qutckly, and effectively shortenmg the outbreak cycle. A deciston was taken to spray the forests to control the latest nun moth
outbreak, but this time using more selective insecticides. An emergency program was put together in May 1994, with funding from the World Bank, European Union’s FAIR program, the Danish Environmental Protection Agency, and the British Know-how fund, totaling m excessof $9 mrlhon. Together with funding provided by the Polish government’s National Fund for Environmental Protectron, the total project cost came to more than $22 million (26). A special forestry formulation of Btk called Foray 48B, from Novo Nordisk accounts for almost 25% of the total insecticide used m forest systems. This
M/crob,al Biopestm-ies. European Scene
37
material is suitable for spraying from aircraft or helicopters at volumes as low as 4 L/ha when applied through ultra-low volume (ULV) spray equipment. As part of the project, Micronair ULV equipment was provided, to completely re-equip the Polish aerial applicator fleet, and pilot training was provided to enable the best results to be obtained. Usage of Btk was especially concentrated m environmentally sensitive areas, or where forest sorls dramed into rivers or lakes. Brological and economic impact studies were put mto place, to examme the implications of the spray program. The results were excellent, with Btk providmg about 95% control of the pest on average, while having minimal impact on beneticials and nontarget organtsms. Smaller, follow-up spray programs m 1995 and 1996 have effectively finished the job, and one would hope that the pest cycle in Poland has now been returned to its more natural 50-yr pattern. The nun moth causes similar problems m adjacent countries, m particular, Germany, Belarus, Ukraine, the Baltic Republics, and the Czech Republic. The Polish project has acted as a model for these other countries, and similar programs utrhzmg Btk are now m place, for example, m Belarus. For some years now, products based on Btk have become the first choice for lepidopteran pest control m North American forestry, especially for gypsy moth (Lymantria &spar) outbreaks. This trend is quickly spreading to Europe, where Btk IS mcreasmgly perceived as a highly effective and environmentally benign forestry msecticide Bt subspp zsraelenszs (Bti) is a quite different type of microbial msecticide. This strain is active against the larval stagesof Diptera, m particular, mosquito larvae. Mosqmtoes are, by nature, only regarded as pests when they are m the vicmity of people. Traditionally, mosquitoes have tended to be controlled by spraying or fogging the adults with broad-spectrum chemical insecticides, but this also exposes the human population to chemical residues of these pesticides. In these more environmentally conscious times, alternatives are being sought to reduce exposure risk. Although habitat alteration, such as marshland draining, has hrstorically been one of the best and most long-lived techniques for mosquito control, the opportumties to adopt these techniques are rapidly drmmishmg. Indeed, within Europe, there is a trend to protect and increase wetland areas, because they are regarded as being extremely valuable to wrldltfe, especially birds, but at the same time they present mosquito species with new opportunmes for colomzation and breeding (27). Control efforts have mcreasmgly moved toward tackling the problem at source, by applying larvrcrde to the waterbody utmzed by the mosqurtoes for breeding. However, because many breeding sites are m environmentally sensi-
38
Butt, Harris, and Powell
Fig. 4. Bti Europeanmarket, 1992-1993. tive areas, chemical larvicides (especially organophosphates) are inappropriate. A viable alternative has proven to be mosquito larvicides based on Bti. These products, such as VectoBac or Bactimos, contain a mixture of dipteran-active crystal proteins and spores. Various formulations are available, including liquids, wettable powders, granules, and slow-release briquettes. When applied to the water surface, the mosquito larvae filter out the Bti particles (together with other particulate organic matter), acquiring a toxic dose. Younger instars are more susceptible that older instars, and pupae and adults are not affected. Thorough, regular, and accurate scouting of the breeding site is therefore essential, to time the larvicide application correctly to target predominantly young instar stages. European countries have taken a number of different approaches to mosquito control and employ Bti products to varying degrees (Fig. 4). In France, mosquito control is predominantly in tourist areas, especially along the coast of southern France. Here, more that 80% of the Bti used is in the form of locally made sand granules. These are produced by mixing Bti primary powder (active ingredient) or wettable-powder formulations with high-grade sand, plus a small quantity of vegetable oil. Specially converted helicopters apply these granules, especially to forested or marsh areas, for the control of Aedes caspius. In Germany, a major mosquito control program is conducted in the Upper Rhine Valley, where the river banks tend to become flooded, especially in the
Microbial
Biopesticides:
European
Scene
39
spring, as the river rises because meltwater from Switzerland swells the volumes carried. In the valley itself, the major problem IS Aedes vexans, whtch tends to lay eggs on dry ground that wdl subsequently become temporarrly flooded. The primary control method IS using Bti larvtctde. Scouting of the breeding sites allows targeted applications to be made either by knapsack sprayer or helicopter-applied granular treatments over larger water bodies and in thick woodland. Another problem faced by this team IS that 50% of the houses m the valley villages collect rainwater in barrels for home/garden usage, and A vexans and Culex pzplens are found to proliferate in these To combat these pests, Btt tablets (Culmex) are manufactured locally and distributed freeof-charge to the householders to treat these contamers (28) (N Becker, personal communicatton) Hungary has a large number of government-sponsored tenders covering a major proportion of the country Key areas are Lake Balaton, Danube, and Ttsza River valleys. A wide range of mosquito pestsare found, includmgAea%s, Anopheles, Culex, and Mansonza A number of prtvate apphcatton companies compete for the spray contracts, using mostly Btl liquid formulations applied from helicopters. Although Btt usage patterns vary constderably across Europe, the products are viewed as possessmg many advantages, including being envnonmentally benign and cost-effective m practical usage. 5. New Developments 5.1. Baculoviruses
Nucleopolyhedrovnuses (NPVs) are increasingly being considered for use as insect control agents. Such vu-uses are almost exclusrvely pathogenic to Lepidoptera. These vtruses produce restmg structures called polyhedra, contaming one or more mfecttve vrrions. When the insect larva consumes contaminated foliage, the polyhedra dissolve in the midgut, releasing the virtons, which then invade midgut epithehal cells. The virus replicates wlthm these cells, uttltzmg them as a stepping stone to build up viral numbers, and subsequently, to invade the hemocoel and colonize the remainder of the Insect. The life cycle IS completed when the insect dies, liquefies, and releases large quantitles of new polyhedra onto the leaf surface. A small number of wild-type baculoviruses have been commerctalized m Europe A typtcal example IS Mamestra brassicae NPV, sold as Mamestrm by Calllope SA, which IS used to control early mstars of Helicoverpa armigera, Mamestra brasslcae, and Plutella xylostella. The product IS formulated as a suspension concentrate and used at 5 L/ha It is registered for use on vegetables m France, Germany, Belgmm, Switzerland, Italy, and United Kingdom, and has been trtaled against cotton pests in Africa.
Butt, Harris, and Powell
40 Table 6 Virus Yield from Wild-Type Stram
AcNPV-wild-type AcNPV + AaHIT (AcST3)
and Transgenic
AcNPV
Virus yield/larva (PIBs x lo-*) 96 1.0
The biggest disadvantage m using wild-type baculoviruses for insect control is the slow speed of kill. Insects can often take longer than 100 h to die, and are stimulated by the mfection to increase their feeding rate above normal in the interim. The consequence of this can be that unacceptable crop damage can occur before the population can be controlled. Researchers have sought to tackle this issue by arming baculoviruses with foreign genes expressmg msectspecific toxins, using genetic engineering techniques. It 1s believed that, by expressing a fast-acting toxin within the insect cell, feeding mhibmon and paralysis could occur quite quickly followmg ingestion, and that acceptable crop protection could be achieved. The Institute of Virology at Oxford, a facility of the National Environment Research Council (NERC), has been one of the pathfinders m relation to the research, and subsequent field testing, of genetically modified viruses m Europe Under extremely strict conditions of containment, modified Autographa calzfornica nucleopolyhedrovuuses (AcNPV), expressing a marker gene, were first trtaled m 1986, to determine the spread and survival of the virus. This was followed up with viruses that contained suicide genes, and then examples that were polyhedrm-negative, that is, deficient m then- protective coat protems, significantly reducing their persistence in the environment (29). More recently, work has concentrated on AcNPV containmg the Androctonus australis insectspecific scorpion toxin gene (coded AcST3). This modtfied vu-us was demonstrated to give significantly faster speed-of-kill m larvae of Trichoplusza ni under field conditions. Furthermore, because a baculovn-us is only capable of reproducing while the host is still alive, polyhedra yields from the msects infected with recombinant vnus were substantially lower than those infected by the equivalent wild-type (29) (Table 6) This suggests that, under practical use conditions, recombinant baculovnuses are competitively disadvantaged compared to wild-types, and, as such, are likely not to predominate m the environment. Other toxin genes can also be considered, as demonstrated m Fig. 5. Two constructs are compared with the wild-type AcNPV. The first construct has received a spider-derived gene encoding for a-laterodectus insect toxin (30). The second construct has received a gene described as Tox 34#4, which is an RT-PCR-generated cDNA clone encoding a protein with a high level of
Microbial Biopesticides: European Scene
41
Dose
Activity
1 x 10E6
PIB’slml
days after treatment
Fig. 5. Activity of wild-type AcMNPV vs constructsagainst Heliothis virescens (tobaccobudworm). (Adapted with permissionfrom ref. 32.) homology (94% identity) to the original TxP-1 itch mite (@emotes tritici) toxin (31). Both of these constructs have the toxin gene driven off the PlO viral promoter, which commences expression about 36 h postinfection. As can be seen,there is a substantial benefit in terms of speed-of-kill, especially with AcNPV + Tox 34#4 (32). This virus is used solely as a research standard within Zeneca. Arguably, highly effective recombinant baculoviruses offer the best likelihood of microbial insecticides achieving chemical-like levels of efficacy and crop protection effect, and have excellent potential for usage in key European markets, such as vegetables, fruit, and tomatoes. 6. Future Prospects The momentum for the development of natural agents for the control of pests, weeds, and diseaseswill be sustained. This will, in part, be the result of increasing awareness and sensitivity of the general public to health and environmental risks associated with chemical pesticides. However, as knowledge and experience in the harnessing of BCAs increases, they will be easier to deploy, and, therefore, will be used more extensively than at present. This momentum can only be maintained if there is investment in the research and development of BCAs, combined with support from extension services and industry, to optimize the impact of these agents. Only then can the technology
42
Butt, Harris, and Powell
be transferred to the end user, and a sustainable, envn-onmentally protection program established.
friendly
crop
References 1 Pickett, J A , Butt, T M , Doughty, K J., Wallsgrove, R M , and Wtlltams, I H (1995) Mmimismg pesticide input m otlseed rape by explomng natural regulatory processes Plenary lecture, m Proceedzngs of the GCIRC 9th Internatzonal Rapeseed Congress, Cambridge, UK, &7 July, 2,565-57 1 2 Rhodes, D J (1990) Formulatton requirements for btologlcal control agents Aspects Appl Bzol. 24, 145-153 3 Moore, D , Douro-Kpmdou, 0 K., Jenkins, N E , and Lomer, C J (1996) Effects of moisture content and temperature on storage of Metarhzzzum flavovzrzde comdta Bzocontrol Scz Technol 6, 5 16 1 4 Moore, D., Bateman, R P , Carey, M., and Prior, C (1995) Long-term storage of Metarhzzzumflavovzrzde comdra m 011formulattons for the control of locusts and grasshoppers. Bzocontrol Scz Technol 5, 193-199 5 McLatchte, G V , Moore, D , Bateman, R P , and Prior, C (1994) Effects of temperature on the viabtlny of the comdta of Metarhzzzum flavovzrzde m oil formulations Mycologzcal Res 98, 749-756 6 Moore, D , Bndge, P. D , Htggms, P. M , Bateman, R P , and Prior, C (1993) Ultravtolet radiation damage to Metarhzzzum flavovzrzde conrdta and the protectton given by vegetable and mineral oils and chemical sunscreens Ann Appl Bzol 122,605-616 7 Jenkins, N E and Thomas, M B (1996) Effects of formulation and appltcatton method on the efficacy of aerial and submerged comdta of Metarhzzzum flavovzrzde for locust and grasshopper control Pestzczde Scz 46,299-306 8 Smith, D B., Hostetter, D. L , and Pmnell, R E. (1980) Laboratory formulation compartsons for a bacterial (Bacillus thurzngzenszs) and vtral (Baculovrrus Helzothzs) msecttctde J Econ Entomol 73, 18-21 9 Lisansky, S. (1989) Btopestmides fall short of market proJections Performance Chem l&387-396 10 Powell, K A , Faull, J L , and Renwrck, A. (1990) Commercial and regulatory challenge, m Bzologzcal Control of Sozl-Borne Plant Pathogens CAB lnternational, Wallmgford, UK 11 Pusey, P L , Wtlson, C L , and Wtsmewski, M E (1993) Management of postharvest diseases of fruits and vegetables strategies to replace vamshmg fungicides, m Pestzczde Interactzons zn Crop Productzon Benejczal and Deleterzous Effects (Altman, J , ed ), CRC, Boca Raton, FL, pp 477-492 12 Wilson, C L. and Wismewskt, M E (1989) Biological control of postharvest diseases of fruits and vegetables an emerging technology Annu Rev Phytopathol 27,425-441 13 Ryder, M H and Jones, D A (1990) Biological control of crown gall, m Bzologzcal Control of So&Borne Plant Pathogens CAB International, Wallmgford, UK 14 Defago, G. and Haas, D (1990) Pseudomonads as antagomsts of sotlborne plant pathogens. mode of action and genetic analysts Sozls Bzochem 6, 249-29 1
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Biopesticides:
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Scene
15 Alabouvette, C (1990) Biological control of Fusarzum welts m suppresstve solIs, m Btologzcal Control of Sod-Borne Plant Pathogens CAB lnternattonal, Wallingford, UK 16 Rtshbeth, J. (1963) Stump protection against Fomes annosu~ III. Inoculatton with Pentophora gtgantea. Ann Appl Btol 52,63-77
17 Butt, T M , Ibrahtm, L , Ball, B. V , and Clark, S J (1994) Pathogemctty of the entomogenous fungt Metarhtztum antsopltae and Beauverta basstana agamst cructfer pests and the honey bee Bzocontrol Set Technol 4,207-2 14 18 Butt, T M , Ibrahtm, L , Clark, S J., and Beckett, A (1995) The germmation behavtour of Metarhtztum anzsopltae on the surface of aphid and flea beetle cuticles Mycologzcal Res 99, 945-950. 19 St. Leger, R , Butt, T M., Staples, R , and Roberts, D W (1989) Syntheses of proteins mcludmg a cuticle-degrading protease during dtfferenttatton of the entomopathogemc fungus Meturhtztum antsopltae Exp Mycol 13,253-262 20 St Leger, R , Butt, T M , Goettel, M S , Staples, R , and Roberts, D W (1989) Productton in vrtro of appressorta by the entomopathogemc fungus Metarhtztum antsopltae Exp Mycol 13,274-288 21 Anon (1989) Agrow Btologtcal Crop Protectton, PJB, Surrey, UK. 22. Remecke, P , Andersch, W , Stenzel, K , and Hartwtg, J (1990) BIO 1020, a new mtcrobtal msecttctde for use m horttcultural crops, m Proceedtngs ofthe Brtghtun Crop Protectton Conference, Pests and Diseases, vol 1, pp 49-54 Vestergaard, S , Gtllespte, A. T , Butt, T M., Schretter, G , and Etlenberg, J. 23 (1995) Pathogentctty of the hyphomycete fungt Verttctlltum lecantt and Metarhtztum anzsoplrae to the western flower thrtps, Frankitntella occtdentalts Btocontrol SCZ Technol 5, 185-192 24. Butt, T M., Barrtsever, M , Drummond, J, Schuler, T H , TIRemans, F T , and Wtldmg, N (1992) Pathogemcity of the entomogenous, hyphomycete fungus, Metarhtzzum antsoplzae agamst the chrysomeltd beetles Psylltodes chrysocephala and Phaedon cochleartae Btocontrol Set Technol 2,325-332 25. Glowacka B and Malmowskt, H (1994) Department of Forest Protectton, Warsaw, personal communicatton 26 Anon (1994) A threat to a thud of Poland’s forest Bzotzmes (Novo Nordtsk) 27. Harris, J. G (1994) Expertence of B t z usage m U.S A , Europe, and Afrtca, m Proceedtngs of the Semtnar on Mtcrobtal Control ofMosquttoes, Untversttt Sams Malaysia, Penang, Malaysta 28. Becker, N and Margaltt, J. (1993) Use of Baczllus thurzngzenszs zsraelenszs agamst mosquttoes and blacklies, m Bactllus thunngienszs, An Envtronmental Btopestzczde Theory and Practzce (Entwtstle, P. F , Cory, J S., Bailey, M J , and Htggs, S , eds ), Wtley, Chtchester, UK, pp 147-170 29 Cory, J (1995) Open Baculovirus Publtc Meetmg, NERC Oxford, November 30. Watkms, M , Ktyatkm, N , Hughes, D , Beadle, D , and Ktng, L (1997) Study on the btologtcal properties of a novel recombinant baculovirus, tn Proceedtng of the BCPC Necesstty? pp. 279-284
Conference,
Microbtal
Insecttctdes,
Novelty
or
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31 Tomalskr, M D and Mtller, L. K (1991) Insect paralysis by baculovn-us medrated expresston of a mtte neurotoxm gene. Nature (Lond) 352,82-85. 32 Harrts, J G (1997) Mrcrobtal msecttcldes an industry perspective. How the mdustry sees the future, the opportumttes and the tools to solve the problem, m Proceedmgs of Mcroblal Insectudes Novelty or Necewty? BCPC Symposium 68,4 I-50. 33. OECD (1996) Data requirements for registration of bropesttcrdes in OECD member countries survey results. Envnonment monograph No 106, OECD, Pans, France, p 12 1 34. Feng, M G , Poprawskt, T. J , and Khachatourians, G. G (1994) Productton, formulation and appltcatton of the entomopathogemc fungus Beauverla basslana for insect control. current status Bzocontrol Scl Technol 4,3-34
4 Developing Countries Balasubramanyan
Sugavanam
and Xie Tianjian
1. Introduction Blo- and botanical pesticides are often grouped together m developing countries as possible alternatives to chemical pesticides. In reality, botanic pestlc!des are no different from chemical pesticides, but blopestlcides are all far removed from them. Botanical pesticides derived from tobacco (Nicotiana tabacum), pyrethrum (Chrysanthemum cznerariaefolium), derrls roots, neem, and so on, have been known for many decades, but occupy only a very small fraction of the overall pesticide market, which IS now worth almost $28 bllhon, and 1slikely to grow to $34 bilhon by the year 1998. Some of the well-known botanical pesticides will fail today’s strict and exhaustive reglstratlon requirements. However, the botanical pesticides gave ideal models for sclentlsts to modify structure and optimize blologlcal activity The synthetic pyrethroids revolutionized the pesticide industry m the 197Os,and today share more than a $2 bllllon market. In the 1980s and 199Os,based on mcotme and strobllurm, major inventions were made m bringing to the market compounds, such as Bayer’s (Germany) tmidacloprid (11 and ICI (UK) A5504 (azoxystrobm) (2), shown in Fig. 1. In addition, BASF also has invented a strobllurin analog called kresoxlme methyl (BAS490F). These will have a big impact In the plant funglclde market. In these mventlons, traditional structure-activity relationship, partltlon coefficients, mode-of-action studies, and computer graphics have been utilized by synthetic chemists to invent key molecules that could fit the relevant enzyme surface, like lock and key, to invoke the needed blologlcal actlvlty and at the same time not interfere with mammalian and aquatic species and not accumulate in the environment. In the case of blopesticldes, there was a great hope for these products during the early 1970s. However, because of major breakthroughs m conventronal From Methods m Botechnology, vol 5 Elopesfudes Use andDe/wery E&ted by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
45
46
Sugavanam and Xie
Imidadoprid
Fig 1 Chemicalsrecently synthesizedusmgnatural products as lead compounds chemistry durmg the 1970s and 1980s in the invention of new synthetic chemlcals, the resources available to blopestlcldes became less and less At the same time, with the soarmg cost of inventing new pestlcldes, the long and expensive time required for reglstermg pesticides, and also problems encountered m developing countries caused by misuse of pesticides and the unnecessary exposure of workers and the environment to highly toxic pesticides, there was a great necessity and urgency to move to user- and environment-friendly pestlcldes. Blopestlcldes came at an ideal time and also, many countries agreed to relax registration requirements and reduce the time required to register blopestlcldes. This started a flurry of research actlvltles by many companies to Invest more m research and development to dlscover blopestlcldes. A large number of pheromones, and blologlcal agents based on fungi and viruses, have been successfully tested m the laboratorles and the field, but there has been very little impact m the market Still, the Baczllus thurzngzenszs (Bt) registered during the 1970s for insect control, and the various genetic mampulatlons of It, dominate the biopestlclde market 2. The Situation in Developing Countries With great importance given to integrated pest management (IPM) worldwide, the role of biopestlcldes 1scrucial as one of Its components. In developmg countries, excessive use of pesticides has caused development of resistance by insects and fungi to many conventional pesticides, and also resurgence of pests caused by destruction of natural enemies. Classic examples, including the brown plant hopper on rice, and bollworms and white fly on cotton, are all problems emanating from human use or misuse of synthetic pestlcldes. Barbosa (3) lists hundreds of pests of mternatlonal importance m more than eight major crops to which Bt could play a role. Although Bt and other blopestlcldes have good potential, both on their own or within the definition of IPM, there are many barriers to cross, because the new synthetic pestlcldes are becoming more and more effective, the formulations are becommg more and more userand environment-friendly, while blopestlcldes lack consistency m their field performance, and suffer quality variations and shelf-life mstablhty The luxury
Developing
Countries
47
of usmg synthetic pesticides m various types of formulattons and delivery systems are hmited m the case of biopesttcides Again, big companies getting fully mvolved m developmg biopesttcides are also lrmited because of lower profit margms, hence, only companies addressmg mche markets, or when organic farms supplemented with attractive subsidies to compensate for addltional costs m terms of using biopesticides and biological agents, are taking up biopesticrdes. In developing countries, lower labor costs would make biopesttcides or biological agents, such as viral msecticides, more attractive, provided there are enough mcentives and technical assistancegiven by the governments and international agencies, such as FAO, WHO, and UNIDO. Such countries such as Indonesia, the Philippines, and Egypt have been phasmg out a number of msecticides, and here the biopesticides could replace some of them and fit wtthin the prmctples of IPM. 3. Production of Biopesticides in Developing Countries Developtng countrtes began looking into the local production of biopesticides, focusing mostly on Bt, almost 30 years ago. In 1964, China estabhshed a research and development laboratory to explore possible local production. A group of researchers at Campmas Umversity m Braztl studied all aspectsof Bt fermentation in the 197Os,and filed two patents In Egypt, Bt production was carried out in a sugar and dtsttllery company using a 5000 L fermenter equipped with centrifugatton and drymg facihties Countries such as India, Mexico, and Thailand tried to look mto low cost production of Bt Unfortunately, exceptmg China, most of these attempts never became a commercial reality, because of lack of experience m quality control, formulation, and application of btopesttcide at that time. In Chma, Beauverza basszsana was the most important fungal msectitide, and was developed more than 10 yr ago A vast amount of vtgorous mycelium was harvested from fermentation (liquid stage) and transferred mto semisolid media (solid stage), consisting of bran, sugar, agar, and minerals. The final product contained 1.8 x IO” spores/g. Many village manufacturers adopted this procedure to produce 5. basszana for control of pine caterpillar and corn borer. Chma’s Ministry of Forestry is m charge of formulatmg the product standards, and will be publishing them soon. For viral msecticrde, the first factory was established m 1985 to produce Hellothzs armzgera NPV. The production flow chart is given tn Fig. 2 Artificial diet for rearing msects was composed mostly of soybean, barley, and yeast Recently, most HaNPV preparations have been processed mto cheaper liquid formulattons. In China, three HaNPV firms have been registered, and about 100 t of this product, contammg 3 billion PIB/mL, are now sold to farmers for control of cotton bollworm
Sugavanam and Xie
48
new hatched
the fourth
tnster
lnrvae
larvae’
Fig. 2 Flow chart of HaNPV production.
4. Bt Production in China Bt production m China has a long history. In the early stages, problems m fermentation and product quality control caused fluctuation m the performance of the product However, since the 198Os,great improvements have been made m screening strains and overcoming phage contammation, changing downstream processmg, formulation, and bioassay procedures. The flow chart of production of Bt m China is given below: Llquld Liquid stock seed + slant seed -+ fermentation + sieving -+ centnfugatlon + checking quality -+ packaging liquid formulation Solid Spray drying of the centrifugal hquld + mlcromlllmg + blendmg + checking quality + packaging powder formulation
In China, use of local Bt strains is encouraged. Several hundred Bt strains are screened every year. One strain, MP-342(H3ab), screened by Hubet Bt Research Centre (Bt RDC), containing cryIA(a), cryIA(c), cryIIA, cryIIB, and cryV genes, shows high toxicity to cotton bollworm. It is the most important Bt strain for commerctal production. Thousands of local Bt strains have been collected in several institutes and universities in China. Primarily defatted soybean flour and cottonseed flour are used as raw material.
During the early days
Developing
Countries
49
of commerctal productton, the concentration of medta was between 3 and 4%, whrch induced low potency of broth. Based on Bt metabolism studies, optrmtzmg fermentation media composition and fermentation parameters, the potency now can reach the level of 3000-4000 IU/pL Phage contammatton, which once threatened Bt fermentation, 1s now completely removed, and the failure rate Induced by phage has been kept to below 1% since 1986. Two kinds of Bt formulattons are produced. The liquid formulatron, usmg only centrifugatton, 1snot as good as the wettable powder formulatton, but is very popular, and today makes up 70-80% of the total Bt market m China. 5. Quality Control Quality control plays a key role m Bt productron. Spore count has been totally replaced by bioassay. The standard sample developed by BtRDC and the Central Chma Agricultural University have been adopted by the scientific community and manufacturers. Two testing insects, cotton bollworm (Heliothzs armzgera) and diamondback moth (Plutellu xylostella), are used in the laboratory The product quality standards are as follows: liquid formulation: 20004000 IUIyL, 1 yr stabthty period, powder formulatton: 16,000-32,000 IU/pL, 2 yr stab&y period. Good-quality Bt products, reasonably priced, are becoming popular m China. Over 40 factories have been registered; all equipment used m the plants are made locally, and give satisfactory performance. BtRDC is the biggest Bt manufacturer in China, and has increased its capacity by moving from 7000-L fermentor in the early 1980s to 40,000-L fermentor now. The production of ltqutd formulation has increased from 1200 Mt in 1993 to 1400 Mt in 1994 to 2500 Mt in 1995 to 5500 Mt in 1996. Most of the wettable-powder formulations are exported. In China, more than 1 mtllton ha are treated with Bt, and local productron will keep increasing, and will complement synthetic pestrctdes in selected important outlets. 6. Registration Requirements Registration requirements of btopesttcides vary from country to country. In China, the Instrtute for the Control of Agrochemlcals, Ministry of Agrtculture (ICAMA), 1sthe authority for pesticide registration. Based on the fact that there are no accidents reported in large-scale Bt production and application, and no adverse effect on nontarget species, such as honey bees, buds, and fresh water fish for decades,and that all Bt manufacturers use native strams for local production, ICAMA makes registration requirements for Bt simple and effective For finished products, the guidelines of data required are given in Table 1. The potency of Bt products is determined by bioassay with newly hatched cotton bollworm (Helzothzs armigera) or dlamondback moth (Plutella
50
Sugavanam Table 1 Guidelines
for Data Required
for China’s
and Xie
ICAMA Registration
Chemical and physical properties Name and type of formulation Quantity of active ingredient Content and identity of nonactive ingredients, such as UV protectors Water-retaining agents, and so on Content of extraneous organisms Chemical and physical properties Stability of product and effect of temperature and storage conditions on biological activity Method of analysis Toxicology Acute oral toxicity or pathogenicity (to mice) Acute dermal toxicity (to Oryctolugus cuniculus) Efficacy Crops to be protected Target pests Degree of specificity for target pests Effective dose level and mode of action Rate, frequency, and method of application
xylostella) in different factories, and by comparing this to a standard sample supplied by ICAMA. According to the guidelines and analysis method mentioned above, most manufacturers do not have difficulties in obtaining registration for Bt products. It is clear that ICAMA makes a great contribution to promoting Bt production and development. Registration of viral and fungal insecticides is just in the early stages. 7. Biopesticides
in Thailand
Thailand has played an important role in promoting biopesticides. Research and development carried out at Mahidol University and the Ministry of Agriculture at Keserat University have promoted both Bt and viral insecticides that have been taken up by private entrepreneurs. Thailand has also played the role of focal point in UNIDO’s program (4) Regional Network on Pesticides for Asia and the Pacific (RENPAP) (see also Subheading 9.). India has been a long supporter of biopesticides, but most of the work was research-oriented, with very little applied research and promotion of production. Because of a highly subsidized malaria eradication program using DDT, there was no incentive
to use biopesticides
in vector control.
Resistance
to
Developing
Countries
51
DDT and its illegal use in agriculture might be a major incentive for moving to biopesticides as environmentally friendly alternatives in malaria vector control. Export barriers because of pesticide residues might also provide outlets for the application of biopesticides in vegetables, cotton, and so on. 8. Other Countries In 1995 UNIDO, in collaboration with the RENPAP, organized a workshop on production and quality control of biopesticides in China (5), in which many Asian countries participated. The main objective of the workshop was to assist countries in Asia to develop capabilities in production and use of biopesticides. Many papers presented in the workshop (5) revealed the situation in many countries of the region. In Pakistan, the use of microbial insecticide has been adopted as part of IPM approach to provide an environment-friendly alternative to generally hazardous broad-spectrum insecticides used against Heliothis armigera. Laboratory bioassays using spore crystal preparations of Bt kurstaki indicated high mortalities of the first instar larvae of H. armigera. Potted chickpea (Cicer arietinum L) plant testsrevealed that the biopesticide Dipel2x and Dipel ES (Bt kurstaki), at rates of 1.6 kg/ha and 2.0 L/ha, caused 81.48 and 84% larval mortality, respectively. Field tests of Bt on chickpea crops (three consecutive seasons)indicated that Dipel2x and Dipel ES (Bt kurstaki; Abbot, USA), at the rates of 1.6 kg/ha and 1.5 L/ha (with and without molasses), respectively, caused significant increase in grain yield, compared to control plots. In Pakistan, where the major portion of insecticides are used on cotton, use of biopesticides and biological control agents would be economically and environmentally appealing, but commercial production and use of these is still not seriously taken up in that country. In the Philippines, the use of biopesticides is becoming increasingly important. The total market share of Bt in the insecticide market increased from 4% in 1992 to over 9% in 1995. The use of Btk is primarily in cabbage, against diamondback moth. In the Philippines, lack of facilities and financial support for Bt research and development, and lack of technology on bioassay and commercial production of Bt, are the major constraints in the development of Bts and their formulations. In South Korea, in order to reduce adverse impact on nontarget organisms and the environment, the government has put the emphasis on development of alternative pest control agents based on low input and sustainable agriculture. Biopesticides obviously appear as good alternatives. Of the 568 pesticides registered in the country, biopesticides account for 3% (15 products). Production of biopesticides increased almost 200-fold in the last 10-yr period (1984-l 994). Quality control of pesticides is regulated under the Pesticide Management Law through the National Agricultural Science and Technology Institute (NASTI). The quality of Bt-based pesticides is switched to Diamondback Moth Unit
52
Sugavanam
and Xie
(DBMU) from Biologtcal International Unit (BIUL). In South Korea, signif? cant research work 1sbemg carried out on btopesttctdes, but needs integrated gutdelmes, tncludmg btologtcal testmg methods, requu-ed for quality assurance of btopesticides. In Vietnam, research work on the utthzatton of btopestictdes was mmated m 1970, m order to develop domestic production of Bt. Bt application IS quite effective and popular m controllmg pests, such as Plutella xylostella in vegetables, and other leptdopteran pests. In collaboratton with the Food Industries Instttute, 300-L batches of Bt kurstaki, with a shelf life of 7 mo under low temperature, are bemg produced, and the product has been commerctahzed Though the locally produced Bt is cheaper than imported Bt, product standardization and contammations are some of the problems yet to be solved. In Africa, major research and development work has been cart-ted out at the International Center of Insect Physiology and Ecology (ICIPE), m Nairobi, Kenya Independently, and m collaboratton wtth mternattonal orgamzatton and bilateral agencies, the center has developed Bts and carried extensive field studies. Recently, they have been testing a Bt product from Finland called Dudstop for the control of filth flies, whtch are known to be potenttal agents for transmtsston of entertc diseases,such as dysentery, mfanttle dtarrhea, typhoid, and trachoma, among others. Most of the tests have been carrted out m refugee camps m Kenya, Ethiopia, Tanzania, and Et-urea. In collaboratton with the Hebrew Umversity of Israel, the Institute ts testing Bt uraelensu and Bacdlus sphaerzcus for larvicidal effect on different mosqutto spectes and then perststence. The Institute is eager to establish pilot plant factlittes for productton of some Bts, but, again, lack of funds and support make these goals unattainable. 9. Activities of International Organizations International orgamzations have been acttve for many years m promotmg btopesttctdes, on their own, or as part of an IPM strategy With the development of resistance to many pesticides and the problems faced with the contmued use of DDT m malaria vector control, and the recent concern over perststent orgamc pollutants, Bt lsraelenszs offers an excellent opportunity to interfere wtth the mosqutto cycle at tts cructal stage as a larvtctde. As early as 1982, the World Health Organization, supported by the World Bank and the United Nations Development Programs (UNDP), developed gutdelmes (6) for productton of Bt H-14 for biological control of vectors. The guidelines supported production of Bt m developmg countrtes for both public health and agricultural requirements The FAO and UNIDO were requested to assist in early-stage evaluatton and plannmg. UNIDO has been active m orgamzmg workshops m productton, quality control, and bioassay in developmg countries. The FAO also wtll extend its code of conduct for btopesttctdes. Most of the work so far
Developmg Countr/es
53
has been concentrated on conductmg workshops and expert group meetings, with many recommendations for commercial production of biopesticides to complement synthetic pesticides. As always, most of these recommendations were not followed by financial and policy incentives and commitments by donor or recipient countries. 10. Opportunities for Developing Countries With developmg countries giving great emphasis to IPM, biopesticides offer an excellent opportunity for developing coutries. Some of the reasons for this, as could be seen from the experience of China, are summarized below. 1 Raw materials are locally available, and could be made from locallyavailableBt strams 2 Preparation of vuus msecttctdes needs manual labor and, hence, 1s highly suttable to developmg countrtes 3. Technology transfer and quality control could be negotiated with relevant companies or mstitutrons m both developed and developmg countrtes 4. For proper trammg m apphcatton of btopesttctdes, mternattonal orgamzattons, such as FAO, UNIDO, and WHO, could be contacted 5. Use of biopesttctdes would also eliminate export restrtctlons based of restdues of certam pesticides, especially in vegetables, frmts, and other commodittes.
Developing countries should look into biopesticides for complementmg synthetic pesticides and not for replacing them. If carefully planned m certain outlets, biopesticides would bring great benefits m reducing the use of synthetic pesticides, especially those that are toxic and persistent. There should be a systematic national/regional strategy to momtor development of resistance to biopesticides, so that they could be rotated along with synthetic pesticides. With the present technology, the market share of biopesticides would be very limited, compared to synthetic chemicals. If one combines biopesticides wtth biologtcal
agents, disease, and insects, and herbicide-resistant
transgemc
crops, the overall effect of biotechnology on crop production and protection will have great impact in the next millennium. One should also apply the caution that synthettc pesticides will contmue to dominate
the market tn the near
and distant future, because of constant improvement m mventions of new pesticides, their formulattons,
and application
technology.
References 1, Shtokawa, K , Tsubot S , Kagabu, S , and Morrtya, K (1994) Imtdacloprtd a chlopraomcotmyl msecttclde, its invention and features, m Ezghth ZUPAC Znternational Congress of Pestlclde Chemutry, Options 2000, American Chemical Society, Washmgton, DC, p. 4 2. Anthony, V M , Clough, J M , Godfrey, C R A, and Godwm, J R (1994) Syntheses of fungtctdal methoxyacrylates, Ezghth IUPAC Internatzonal Con-
54
3.
4
5
6
Sugavanam and X/e gress of Pestzclde Chemistry, Optlons 2000, Amertcan Chemtcal Soctety, Washmgton, DC, p 5 Barbosa, S (1993) Potential of Bt m mtegrated pest managementfor developmg countrtes, m Blopestlclde Bt and rts Appllcatlons in Developing Countries (Salama, H S , Morris, 0 N , and Rached, E , eds), National Research Centre, Catro, Egypt, and IDRC, Canada,pp 59-7 1 Dhua, S P (1992) Regtonal network on pesttctdes for Asta and the Pacific (RENPAP) an overview, m Recent Developmentsin the Field of Pestwdes and thew Application to Pest Control (Holly, K , Copping, L S , and Brooks, G T , eds ), UNIDO, Vtenna, pp 277-284 Report on Workshop on Productton and Qualtty Control of Btopesttctde Bt Wuhan, Republtc of Chma, November, 1995 UNIDO Report, DP/ID/Ser A/ 1765,1995. Vandekar, M and Dulmage, H T , eds (1983) Guzdellnesfor Pvodzxtzon of Bacillus thurznglensls H-14, UNDP, World Bank, WHO
5 Pesticide Policy Influences on Biopesticide Technologies Noel D. Uri 1. Introduction Pesticide pohcy has a substantial impact on the development and use of btopesttctdes. Before explormg the nature and extent of this impact, it 1sworthwhile to examine btopestictde use, m order to put policy influences m proper perspective The constant evolution and adoption of new productton practices, includmg relatively pesticide-intensive farming, has led to a sustained increase m output and comctdent benefits to the American consumer m a variety of ways, mcludmg the price of food The conventional pesticides used today were new and uncertam m prevtous periods In an analogous way, biopesttcrdes and other forms of biologrcal control being developed today will be conventtonal pesttctdes m the future. The growth of biopesttcide use is an Integral part of the technologtcal revolutton m agriculture that has generated major changes m production techniques, shifts in input use, and growth m output and producttvtty (I) Predicting the growth m biopestlctde use, however, IS difficult, because of recent changes in federal laws affecting the farm sector (a major consumer of btopesttctdes) and regulating the registration and use of pesticides. Addtttonally, accurately forecasting the changes m the price of biopesticldes relative to the price of conventtonal pesticides complicate the predictron problem. These issues will be discussed below The market for brologtcally based pest controls IS small but fast growing The market value of btologtcally based products-natural enemies, pheromones, and mtcrobtal pesticides-sold m the United States during the early 1990s was estimated at $95-147 mtllton, 1.3-2 4% of the total market for pest control products (2). At least 30 commercral firms produce natural enemies. From Methods ,n Biotechnology, vol 5 B,opest!ades Use and Dehvery Edited by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
55
56
U-1
Even though the current market for brological products is growing, and large pest-control companies are begmnmg to participate, the market IS still so small that biologlcals are unlikely to replace conventional chemical pesticides m the foreseeable future, unless major research and development activities are started (3). Biologrcal pest management includes the use of pheromones, plant regulators, and microbial organisms, such as Bacillus thuringlenszs (Bt), as well as pest predators, parasites, and other beneficial organisms. The US Envnonmental Protection Agency (EPA) currently regulates biochemicals and mrcrobral organisms, and classifies them as biorational pesticides. 7.7. Microbial
Pesticides and Pheromones
Brorational pesticides have differed significantly from conventional pesticides, because they have generally managed rather than eliminated pests, have a delayed impact, and have been more selective (4). Thus, for example, microbial pesticides have not been successful as herbicides, because target weeds are replaced by other weeds not affected by the microbial pesticide Among the most successful mrcrobials has been Bt, which kills Insects by lethal infection. Growers have dramatically mcreased then use of Bt during the 199Os, especially under blomtensive and resistance-management programs, because of its environmental safety, improved performance, selectrvity, and activity on insects that are resistant to conventional pesticides. It is one of the most important msect management tools in certified organic production. Bt was used m more than 1% of the acreage of 12 fruit crops m 1995, up from 5 crops m 199 1 (Table 1). Between 12 and 23% of the apple, plum, nectarine, and blackberry acreage received Bt applications m 1995, and it was applied on over half of the raspberry acreage. Among vegetable crops, the acreage treated with Bt increased for 13 of the 20 crops surveyed between 1992 and 1994, and was used on about half or more of the cabbage, celery, and eggplant acreage Bt has been used on only a couple of field crops. Corn acreage treated was steady at 1% m 1994 and 1995, and treated cotton acreage increased from 5% m 1992 to 9% m 1994 and 1995 New Bt strains, with activity on insects not previously found to be susceptible to Bt, have been discovered in recent years. Current research is devoted to improving the delivery of Bt to pests and to increasing the residual activity and efficacy of Bt. Pheromones are used to monitor populatrons of crop pests and to disrupt mating m organic systemsand some IPM programs. Pheromones were used on 37% of fruit acreage to monitor and control pests, and on 7% of vegetable acreage to control pests (Table 2).
Table 1 Agricultural Applications of Bacillus fhuringiensis Selected Crops in Surveyed States, 1991-1995
Crop Field crops Corn Cotton (upland) Fruit Grapes Oranges Apples Peaches Prunes Pears Sweet cherries Plums Nectarmes Blueberries Raspberries Blackberries Vegetables Tomatoes, processed Lettuce Sweet corn Onion Broccoli Tomatoes, fresh Cantaloupe Snap beans Cabbage Bell peppers Cauliflower Cucumbers Strawberrres Celery Honey dew Spinach Eggplant
Planted acres (in thousands)
(Bt), Area receivmg apphcation (in % acres)
1991
1992
64,105 1 I .650
a
796 760 345 144 94 68 47 44 36 30 11 4
a
b
2 3 C, 0 a n a L1
b
0
a
11 49 18 b
323 191 164 128 111 104 98 71 70 61 54 51 46 36 26 10 4
b 6 b
b b b b b b b b h b b b b
OApplred on CO5% of the acres *Not a survey year for that commodny (Adapted wtth permlssron from refs. 40 and 42.)
57
1993 ‘2
5
b b b
8
b
b
b
10 8 45 n
b
6 18 3 ” 7 31 32 20 48 35 12 19 24 51 28 13 13
1 9
1 9 6 3 12 5 9 2 9 14 22 5 52 23
1 8
b
b
1995
2 7 13 3 0
b
b
1994
h b b b b
b b
b h b b b b b b b b
5 20 3 1 14 39 8 29 64 37 20 22 33 61 10 21 48
b
b b b b b 6 b b b b h b b b b b
58
Ur1
Table 2 Use of Selected Biological Pest Management Practices on Fruit and Vegetable Crops in Major Producing States in the 1990s % of acres Crop Fruit Grapes Oranges Apples All frurts Vegetables Sweet corn Tomatoes Lettuce All vegetables
Planted acres (m thousands)
Beneficial Insects
Pheromone traps
Resistant varietres
18 22 2 19
14 28 66 37
31 21 16 22
NA 5
17
NA NA NA NA
730
613 381 3251 640 357 259
2914
3 3
6
1 7
NA not avarlable (Adapted with permlsslon from refs. 40 and 41 )
1.2. Beneficial
Organisms
Natural enemres of crop pests or beneficrals may be Imported, conserved, or augmented. Many crop pests are not native to thts country, and the US Department of Agrrculture (USDA) issues permits for the natural enemies of these pests to be Imported from thetr country of ortgm. Natural enemy rmportatron and establishment, also called classrcal brologrcal control, has been undertaken prrmartly m umverstty, state, and federal projects. Twenty-erght states operate brocontrol programs, and most have cooperatrve efforts with USDA agencies (2) Some crop pests, such as the woolly apple aphid m the Pacific Northwest, have been largely controlled with this method. Natural enemies may also be conserved by ensuring that then needs for alternate hosts, adult food resources, overwmtermg habitats, a constant food supply, and other ecologrcal requirements are met, and by preventing damage from pestrctde apphcattons and other cropping practrces (5). Over one-half the certrfied organic vegetable growers m 1994 were provrdmg habitat for beneficrals. A small but mcreasmg number of companies are supplymg natural enemies of insects, weeds, and other pests to farmers. For greenhouse and agrrcultural crop productron, most natural enemies being sold, such as beneficial insects, predatory mites, parasitic nematodes, and insect egg parasites, are used for managing pest mites, caterpillars, citrus weevrls, and other insect and arthro-
Policy
Influences
on Biopesticides
59
pod pests, However, a number of natural enemies-musk thistle defohatmg weevils, for example-are bemg sold for managmg weeds on rangeland and unculttvated pastures (6). The Cahfornia Environmental Protection Agency has published a list of commercial suppliers of natural enemies m North America since 1979, and the number has increased steadily. In 1994, 132 companies were listed, mostly m the United States, offering over 120 different orgamsms for sale (7). 1.3. Host-Plant Resistance Corn and soybean breeding for genetic resistance to insects, disease, and other pests has been the research and development focus of major seed companies for many decades (8). US soybean acreage, for example, receives virtually no fungictdes, because of the effectiveness of the disease-resistant soybean cultivars that have been developed. The use of classical breeding programs is now being augmented wtth new plant breeding efforts using transgemc and other genetic engineering techmques. In March 1995, the EPA approved, for the first time, a limited registration of genetically engineered plant pesticides to Cuba (Base& Switzerland) and Mycogen (San Diego, CA), and, m August 1995, granted condrtronal approval for full commercial use of a transgemc pesticide to combat the European corn borer (9). Thts plant pesticide, Bt corn, is produced when the genetic mformation related to insecticidal properttes IStransferred from the Bt bacterium to the corn plant. This technology could reduce the need for conventional chemical msectrcides in corn productton. In 1995,26% of US corn-planted acreage was treated with msecticides, and corn borer is one of the top insect pests targeted for treatment. Since these new corn varieties, however, contam natural genes and genes produced from the soil bacteria Bt, many scienttstsare concerned that the new corn will hasten pest immunity to Bt That is especially a concern for the growmg number of producers who rely on the foliar-applied Bt, and has led the EPA to approve the new pestrcrdes, condrtioned on the momtormg for pest resistance and the development of a management plan in case the insects become resistant Although most classtcal breedmg programs have focused on pests resistant to chemtcals or treatments that were too expensive (10), consumer concern over pesticides m agricultural products has prompted biotechnology companies to enter the genetically engineered plant market. As agricultural biotechnology products attam commerctal success,some private Investment fundmg may shift from the smaller pharmaceutical markets toward agrtcultural crop protection (II). On the other hand, consumer acceptance of bioengmeered Bt corn, Bt cotton, and other genetically engineered crops has not yet been dem-
Uri
60
onstrated m major US markets. A 1992 survey of consumer attitudes about food biotechnology found that most consumers want mformation on labels about vartous food characteristics, including the use of biotechnology (12) Animal Plant Health Inspection Service (APHIS) has approved or acknowledged 638 field trials for insect-resistant varieties since 1987,286 field trials to test viral resistance, and 94 field trials for fungal resistance (23). 2. Biopesticide Use in the Context of Pesticide Policy Many factors affect the adoption of biopesticides as a crop productton technology. Pest cycles and annual fluctuations caused by weather and other envtronmental conditions often determine whether infestation levels reach treatment thresholds. Changes m farm biopesticide use are related to producers’ decisions on the amount and mix of crops to plant. Given this, other factors that influence bropesttcide use decisions are relative factor prices and government farm, conservation, and regulatory policies 2.1. Relative
Factor
Prices
The changing relative prices between different pesticides 1simportant, especially as biopestictdes strive to replace conventional pesticides For example, the largest pesticide market m the United States is cotton. It accounts for 35% of the msectictde market, with about $850 million m sales m 1996 (13). Bt cotton has the potential to be a challenge to conventional fohar sprays for control of the budworm/bollworm complex. The cost of Bt cotton, including Tracer (DowElanco, Indianapolis, IN), Pirate (American Cyammid, Pearl River, NY), Proclatm (Merck, Whitehouse Station, NJ), and Confirm (Rohm and Haas, Philadelphia, PA), however, averages about $34/acre. Conventional insecticide treatment averages around $10,20/acre. Given the current price differential, Bt cotton is not likely to replace conventtonal msecticides. In another example, btological control has been shown to be effective on Canada thistle, leafy spurge, the knapweeds, St. Johnswort, musk thistle, and other weeds. Biologtcal control through beneficial insects (e-g , Canada thistle stem mnnng weevtl and musk thistle rosette weevil), however, 1sprtced substantially higher than, say, atrazme. In 1996, the price of atrazme (a common herbicide used to control these weeds) was approx $3.90/acre, and btologtcal control is priced at about $70.00/acre (13). Thus, biological control will not likely to replace atrazme or one of the other triazme herbicides m the near future,
2.2. Government Commodity and Conservation Programs Federal commodity and conservation programs affect agricultural biopesticide use, m part, through the amount of acres planted. Past commodity programs were designed primarily to provide price and income protectron for
Policy Influences on Biopesticides
61
farmers. Land set-aside requirements helped restrict supply and increase commodtty prices (14). Although the Federal Agriculture Improvement and Reform Act (FAIR) of 1996 eliminated those set-aside requirements, the reauthorized Conservatton Reserve Program, designed for envtronmental objectives, pays producers to keep acreage in conserving uses, rather than in production. Fewer acres planted generally implies less biopesticides applied. Other federal agricultural conservatron programs influence productton practices on planted acreage, which in turn wtll affect biopesticide use. 2.3. Agricultural Chemical Regulations: Implications for Biopesticide Use Pesticide regulation m its modern form began with the enactment of the Federal Insecttcide, Fungicide, and Rodenticide Act (FIFRA) m 1948. Under this mandate, Congress required that all chemicals for sale m interstate commerce be registered against the manufacturers’ claims of effectiveness. The law also required manufacturers to indicate pesticide toxicity on the label. Congress amended FIFRA in 1954, 1959, and 1964, but, in practice, pesticide regulatton by 1970 meant efficacy testing and labeling for acute (short-term) toxicity. Pesticide regulation passed mto a new phase with the 1972 amendment to FIFRA, and the transfer of regulatory jurisdiction to the EPA. Under this new regulatory regime, Congress gave the EPA the responsibility of reregistermg extstmg pesticides, examining the effects of pesticides on fish and wtldlife, and evaluating acute and chronic toxicity In the 1988 amendment to FIFRA, pesticide producers were required to demonstrate, wtthm 9 yr, that all pesticides registered before November 1984 meet current standards (4). Pesticides are also regulated by various provtsions of the Federal Food, Drug and Cosmetic Act (FFDCA). Under the FFDCA, the EPA establishes the maxtmum allowable level (tolerance) of pesticide residues that can be present on foods sold m interstate commerce, and the Food and Drug Admimstratton (FDA) momtors food and feed for pesticide residues. In 1996, Congress passed the Food Quality Protection Act (FQPA), which was intended to update and resolve inconsistenctes in the two major pesticide statutes: FIFRA and FFDCA. The major components of the FQPA address the issues of settmg a single, health-based standard (i.e., a reasonable certainty of no harm) for all pesticides m all foods (although benefits can continue to be considered in certain instances when setting standards), provtdmg special protection for infants and children, regulatory relief for minor use pesticides, expediting approval for safer (reduced-risk) pesticides, requnmg periodic reevaluatton of pesticide registrations and tolerances, and reauthorizing and increasing registrant fees to fund such reevaluattons, establishing national umformtty of tolerances unless States petition for an exception, and mandating
62
U-1
the dtstrtbutton of mformatton m grocery stores on the health rusks of pesttcldes and how to avoid such rusks (24a,Z5,16). The crttical components of the FQPA, as far as btopestictdes are concerned, deal with expediting the review of mmor-use pesticides and expediting the approval of reduced-risk pesttcides. Both sections of the legrslatton should serve to accelerate the development and commercialtzatton of new btologtcal approaches to pest control EPA 1s giving hrgh prtority to rmplementmg the Minor Use Provtslons of FQPA. It has created a new program dedicated solely to coordmating minor use Issues withm the Office of Pesttcrde Programs The defimtton of a minor-use crop has been determined to be a crop produced on fewer than 300,000 acres, or a major crop (a crop grown on more than 300,000 acres) for whtch the pesticide use pattern 1s so limtted that revenues from expected sales ~111 be less than the cost of regtstermg the pesttclde, and there are msuffictent efficactous alternatives for the use, alternatives pose greater risks, the mmor use is stgmficant m managing pest resistance, or the minor use plays a stgmficant part m integrated pest management (IPM) The first part of the definition means that all but 26 of the 600-plus crops produced m the United States are minor crops. EPA will consider every crop m the United States to be a minor crop, except for almonds, apples, barley, canola, carrots, corn (field and sweet), cotton, grapes, hay (alfalfa and other), lettuce, oats, oranges, peanuts, pecans, popcorn, rice, rye, snapbeans, sorghum, soybeans, sugarcane, sugarbeets, tobacco, tomatoes, sunflowers, and wheat. Provtstons intended to help preserve the availabthty of minor use pesticides include expedrting the review of data submitted m support of mmor uses, granting time extenstons for submtttmg data on minor uses, and giving those who invest m data development for minor uses addrtronal exclusive rights to use of the data to support registration. The mmor use program at EPA, m conJunctton wtth a similar program at the USDA wtll coordinate decrstons on minor use issues m consultation with growers. A revolving grant fund is authorized at the USDA to fund the generation of data necessary to support minor use regtstratton. The Department of Health and Human Services 1s authorized to fund studtes in support of registration or reregistration of minor use pesticides that are important for public health purposes The Reduced-Risk Pesticide Inmattve 1s designed to encourage the development, regtstratton, and use of new pesticide chemicals, which would result m reduced risks to human health and the environment, compared to existing alternatives. In 1995, the average amount of time tt took to register a new conventional pesticide was 38 mo; the new reduced rusk pesticides take, on average, 14 mo (17). Since 1993,29 new chemtcal submtssrons have been received by EPA as reduced-risk pesticide candidates. Of the 29, 17 met the reducedrisk crtterta for expedited review Nme of those 17 have been registered
Policy Influences on Biopesticides
63
In November 1994, EPA established a separate division m the Office of Pestrcrde Programs, the Bropesticides and Pollution Prevention Division, to encourage the development of reduced-risk pestictdes, and to manage the regrstration and reregistration of biopesticides Biopesticides are defined by EPA to include naturally occurring and genetically engineered microorganisms, genetically engineered plants that produce then own pesticides (such as crops that produce the msectrcidal proteins from the Bt bacteria), and naturally occurrmg compounds, or compounds essentially identical to naturally occurrmg compounds, that are not toxic to the target pest (such as pheromones) EPA approved 14 new biopesticide active ingredients m fiscal year 1995 and 10 m fiscal year 1996, which represents over one-third of new active mgredients registered rn those years EPA also issued Reregistration Eligibrhty Decision documents for eight bropesticides. FQPA explicrtly recognizesthe importance ofieduced-risk pesticides and supports expedited review to help these pesticides reach the market sooner and replace older and potentially riskier chemicals. The new law defines a reducedrisk pesticide as one which “may reasonably be expected to accomplish one or more of the followmg: reduces pesticide risks to human health; reduces pestrcrde risks to nontarget organisms; reduces the potential for contammation of valued, environmental resources,or broadensadoption of IPM or makesit more effective.” Other statuteswith the potential to affect pesticide use include the Clean An Act, Clean Water Act, Safe Drinking Water Act, Coastal Zone Management Act (CZMA), and the Endangered Species Act. The Water Quality Act of 1987 (sec. 3 19) and the CZMA address nonpomt somces of pollution, such as those from farm fields These are discussed in detail in ref. 18 4. Effects of Policies on Development and Use of Pesticides In the agricultural sector, pohcy influences on pesticides take two forms. Fn-st, pohcy affects the choice of production practice, which will be more or less pesticide-intensive, depending on the policy. Second, government policy directly impacts the development of new pesticides and pest-management practices Each of these issues IS discussed m turn. 4.1. Direct and Indirect Impact of Government Policy on Use of Pesticides Government regulation attempts to mitigate the adverse effects of pesticide use Prmcipally because of concerns over the environmental problems associated with pesticide use m production agriculture, farmers, with some mvolvement on the part of government rn the form of cost sharing and educational and technical assistance, are experimentmg with a myriad of new and traditional tools, materials, and practices Short-term productivity enhancement and
64
Un
chemical use efficiency are the major goals m some of the systems; envn-onmental risk reduction and the long-run sustamabihty of farming are more promment m others To help mmimrze the trade-off between lower pesticide use and reduced net farm income, IPM, precision farmmg, and cultural and biological pest and nutrient management methods are among options encouraged by some. The first two attempt to increase efficiency of chemical use, the latter two attempt to avoid chemical use altogether. Pest scoutmg, economic thresholds, and other tools to help the farmer determine when to make pesticide applicattons, which pesticides to use, and how much to use, have been developed for decades, and expert systems and other decision-support systems to integrate these elements are emerging Prectsion farming and herbicide-resistant bioengineered crops are efficiency technologies that aim at reducing pestictde use that are Just now being developed and commerctahzed. Scoutmg and threshold use is widespread m specialty crop production (19) Half of the US fruit and nut acreage, and nearly three-quarters of the vegetable acres m the surveyed states, were scouted for insects, mostly by professional scouts. Growers reported using thresholds as the basis for making pesticide treatment decisions on virtually all of these scouted acres. Potato growers reported that 85% of their acreage was scouted and thresholds were used m making nearly three-quarters of their msecticide apphcatton decisions. A number of alternative productton practices, including crop rotation, conservation tillage, alterations m planting and harvestmg dates, trap crops, samtation procedures, irrtgatton techniques, fertihzation, physical barriers, border sprays, cold-an treatments, and habitat provision for natural enemies of crop pests, are now bemg relatively more extensively used for managing crop pests. Their diffusion IS expected to grow more widespread. These alternative production practices work by preventmg pest colonization of the crop, reducing pest populations, reducing crop injury, and enhancmg the number of natural enemies m the croppmg system (20). Crop rotation is one of the most important of these techmques that is currently m widespread use. Over half of the corn and soybeans were grown m rotation with each other during the mid- 1990s (22). Farmers rotating corn with other crops used msectictdes less frequently than did those plantmg corn 2 yr m succession (11% vs 46%). Corn IS often grown as a monocrop in areas that have high demand for livestock feed, and where climatic restrictions limit the soybean harvest period (8). Crop rotation is much less prevalent for cotton, however, which has among the highest per acre returns of the field crops grown m the United States, and less than one-third of the cotton producers use this technique.
Policy Influences on Biopesticides
65
4.2. Impact of Government Policy on Development of New Pesticides Research and development expenditures are an important factor affecting the development of new pesticides. There is a fairly extensive literature exploring the relationship between research and development expenditures on a good or service and the use of that good or service (22-24). Basically, research and development expenditures m basic mdustrtes, such as the chemical industry, are conditioned by the present value of expected net revenue. That is, research and development expenditures are made with the expectation that a profit for the firm will result. The net present value is a function of costs, such as research and development expenditures, and regulatory costs of getting a new pesticide registered, as well as the revenue generated from the sale of the pesticide. In this setting, and as apparent from the foregoing discussion, pesticide pohcy is only one, albeit an important one, of the factors affecting pesticide use, and hence the development of btopesttcides. Any government pohcy affecting relative factor prices, price responsiveness, expected returns from chemical use, conservation, and technology development and adoption will impact the development of new pesticides. The two major statutes, FIFRA and FFDCA, instruct regulators to weigh the benefits of pesticide use against unreasonable risks. This balancing process has been characterized so that the use of the term “unreasonable risk” implies that some risks will be tolerated under FIFRA; it is clearly expected that the anttctpated benefits will outweigh the potential risks when a pesticide is used according to commonly recognized, good agricultural practice (25). A study of the impact of pesticide regulation on innovation and the market structure in the United Statespesticide industry shows that pesticide regulatton in the United States has encouraged the introduction of fewer, yet less toxic pesticrdes (#j.* The 1972, 1978, and 1988 amendments to FIFRA require that new and existing pesticides meet strict health and environmental standards. Requirements for pesticide registration wtth the EPA include field testing, which can include up to 70 different types of tests that can take several years to complete and cost mtlhons of dollars. They consist of toxicologtcal studies, a two-generation reproduction and teratogenicity study, a mutagenicity study, oncogemcity studies, and chronic-feeding studies. The toxicological studies include acute (immediate), subchronrc (up to 90 d), and chrome (long-term) effects. Other tests are used to evaluate the effects of pesticides on aquatic systems and wildlife, farmworker health, and environmental fate. Recent *High toxlclty pestlcldes are those that belong to Class I acute toxlclty (indicated m the label), or are chrotucally toxic to humans, or to fish and wildlife. Lower toxlclty pesticides are all others (4)
66
U-i
estimates suggest that research and development of a new chemical pesticide (including the testing indicated above) costs between $50 and 70 million and takes 11 yr (4). As a consequence of the regulation requirements, pesticide firms refocused their research away from persistent and toxic pesticides. The number of pesticides with chronic (long-term) toxicity dropped by 86 between the 1972 and 1976 and 1987 and 1991 periods, and lower toxicity pesticides account now for more than half of pesticide sales. A 10% increase in testing costs is associated with a 2.8% increase in the proportion of less-toxic pesticides registered. In 1996, the Office of Pesticide Programs of the EPA registered 22 new pesticide active ingredients, more than half of which were considered reduced-risk pesticides. These decisions included the approval of 10 biopesticides and 12 new chemicals, which include three reduced-risk chemicals (26). The biopesticides include Bt Cotton (Monsanto), I-octen-3-01 (Armatron), Jojoba oil (IJO Products), Bt (CryMax) (Ecogen), Myrethecium verrucaria (Abbott), meat meal (Lakeshore Enterprises), red pepper (Lakeshore Enterprises), Verticillium lecanii (Abbott), NK Bt corn (Northrup King), Monsanto Bt corn (Monsanto), and Lavandin oil (S.C. Johnson). Pesticide regulation has also had undesirable consequences. Regulation discouraged new chemical registrations: The number of new pesticides registered by the EPA in 1987-l 99 1 was half that of 1972-l 976 and each 10% increase in pesticide regulatory costs caused a 2.7-% reduction in the number of new pesticides introduced (4). The higher regulatory costs contributed to an industry-wide increase in research spending, which encouraged some small firms to leave the pesticide industry. Pesticide regulation also encouraged firms to focus their research on pesticides used in larger crop markets, such as corn and soybeans, abandoning minor-crop markets, such as horticultural crops. The decline in new registrations of chemical pesticides suggests that there are market opportunities for biopesticides and genetically modified plants. These products are not only environmentally preferable, but also less costly to develop and register than chemical pesticides. Thus, it has been estimated that the average cost of developing a biopesticide ranges from $3 to 5 million vs $50 to 80 million for the development of conventional pesticides (27). Such new products, however, as noted previously, are only effective against a narrow range of pests. The 15 largest (in terms of retail sales) agricultural chemical companies are developing biopesticides, including pheromones, bioinsecticides (viruses), botanical extracts, soybean seed, corn and sorghum seed, microbial products, Bt manufacturing, microsponge formulation, and gene insertion. Cropper et al. (28) examined EPA’s Special Review Process for pesticides between 1975 and 1989, to determine whether the decision to cancel or continue the registration of pesticides could be explained by the risk and benefits associated with pesticides. Cropper et al. estimated a trade-off of $35 million
Policy
Influences
on Biopesticides
67
in producer benefits per cancer avoided among pesticide applicators. More recently, Cropper et al. (28) estimate a trade-off of $72 million per cancer avoided among pesticide applicators and $9 million per cancer avoided among consumers (in 1986 dollars). Abler (30) argues that these figures are too high, because Cropper et al. calculated the benefits at existing prices, not considering the effect of pesticide restrictions on producer prices. Abler argues that producers could even gain from pesticide restrictions if output prices increased enough. On the other hand, higher output prices caused by restrictions on pesticide use have not been empirically documented. 5. Conclusions Biopesticides developed and used in the future will emerge against the backdrop of the environmental effects associated with the use of conventional pesticides and government policies designed to control these effects. In the final analysis, farmers’ choices on pesticides will be influenced by the prevailing costs and benefits of conventional pesticides and their alternatives, including biopesticides. The outlook for pesticide use is complicated, though some directions can be perceived. There are a number of factors that will serve potentially to impact pesticide use, which in turn will affect the development of biopesticides. These include pesticide regulation, the FAIR Act, the crops planted, the management of ecologically based systems, and consumer demand for green products. 5.1. Pesticide Regulation Pesticide regulation will continue to exert a major influence on pesticide use and the development of pesticides and pest management alternatives in the United States.The number of pesticide-active ingredients for sale in the United States has decreased by 50% since 1989 because of EPA’s reregistration process (31). Moreover, regulatory changes involving the removal from the market of pesticides, which had been previously registered, because of evidence on unacceptably high health hazards from occupational exposure, may also undermine the confidence that farmers have in the safety of pesticide use (32). Finally, implementation of the FQPA of 1996 will impact pesticide registrations in general and biopesticides in particular. The FQPA is designed to expedite the review of minor-use pesticides and the approval of safer pesticides. Both sections of the legislation should serve to accelerate the development and commercialization of new biological approaches to pest control. Although the legislation does not expressly recognize the presumption of biologicals for the expedited review category, the provision will assist in promoting new research and development activities (17).
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5.2. The FAIR Act Short-term effects of the FAIR Act on blopestrcideuse stemfrom greater flexlbllity provided to producers through elimination of baseacreageand set-asides.Elimlnation of base acreage will faclhtate rotations, which could reduce insecticide use. Without the concern of mamtaming base acreageto receive federal deficiency payments,one would expectproducers to plant crops for which returns are higher (e.g., corn rather than wheat), where producershave suchoptions. Hence,blopestlcide use will change based on how and where the mix of crops will change. For example, If producers plant more corn, a more chermcally intensive crop, rather than wheat, which generally requires lesschemicals,one would expectchemical use to increase (13) Elimination of set-asides,other acreagereduction programs, and a potentially smaller Conservation Reserve Program could result m increased planted acreage, with resulting increasedblopesticide use. Set-asides,however, have been relatively low, If not zero, for several program crops recently, sothe increasein planted acreage would not be dramatic. In net, greater biopestlclde use would be expected if more chemically intensive crops areplanted on existing acreageand greater acreageoverall ISplanted, but greater crop rotations would curb such growth (26). In the long-term, input use will hinge on the relative marginal productlvlty and cost among labor, pesticides, fertilizer, and other factors, which the FAIR Act will not alter. As nominal prices decline from 1995-1996 peaks, and real prices are anticipated to continue to decline, there will be less incentive to apply inputs whose value of the marginal product does not increase. Although federal support will fall, market demand 1sexpected to keep commodity prices relatively high by historical standards. Thus market mcentlves will replace federal mcentlves regarding apphcatlon of chemical inputs 5.3. Crops Planted The USDA projects that crop acreage of eight major crops will rise between 5 and 10% by the year 2005 from 1995 levels (33).* Both corn and wheat acreage are expected to rise by about 10 million acres each; that of cotton 1s expected to decline by about 3 mllhon. Hence, although the changing mix of crop acreage complicates a proJection of pesticide use, it seems likely that, from increased planted acreage, blopesticlde use will continue to rise, if other influences are held constant (13). 5.4. Ecologically Based Management Systems The USDA announced several years ago that switching to an ecosystembased approach for managing natural resources 1samong its major agricultural prloritles for the 1990s (34). The new approach, which 1sto be adopted gradu*Cropsarebarley,corn,uplandcotton,oats,rice,sorghum,soybeans,
and wheat
Pohcy Influences on Biopesticides
69
ally, adds the goal of mamtammg or improving the condttton of the land as the context for providing sustamable levels of goods and services. Ecosystem management 1spartly based on the emergmg research on btodiverstty, ecosystems, and environmental accountmg from new scientific disciplines, such as conservation biology, landscape ecology, and ecological economics. The impacts of species loss on crop-breeding programs, and more complete accountmg of the costs of food and fiber productton, are some of the issues that are addressed. Much of the imttal application of this approach has been for national forests and other pubhc resources, but tts potential use for crop productton systems 1s also being explored The National Research Council (NRC) (35) has published the results of a study to examme ecologtcally based pest management practices for agriculture and forestry. The NRC report concludes that pest resistance and other problems created by pesticide use has created a need for an alternative approach to pest management that can complement and partially replace current chemically based pest-management practices. Ecosystem-basedpest management is the approach that was recommended. The USDA’s Forest Service adopted an ecosystem management philosophy in June 1992, and this approach has been influencing the development of forest management plans m the Pacific Northwest and other areas. For example, ecosystem design-arrangmg landscape structures m the watershed to support species biodiversity, as well as timber production and recreation-was used in the recently developed forest management plan for a 30,000-acre watershed in Mt. Hood National Forest (31). A number of stateshave begun to examine ecosystem-based pest management m specific agricultural cropping systems. Maine’s Agricultural and Forest Experiment Statton, for example, has recently reported results from the first 4 yr of its pioneering industry-supported ecosystem proJect on sustainable potato production (36). Various states and regions also have some ecosystem research underway, mcludmg some federally funded IPM proJects, which are lookmg at btologtcal alternatives, as well as public-private efforts at the local level, such as the Chesapeake Bay watershed project, and the BIOS proJect for California almond growers. 5.5. Consumer Demand for Green Products and the Market Response The market for food products with a green label, such as certified organic and IPM, has been growing m the United States.Although organic food products only account for about 1% of total retail food sales at the present time, overall orgamc sales reached $2.8 billion in 1995, and have increased over 20% annually since 1989 (37). Orgamc foods are becoming more widely avatlable to United States consumers through the growing number of large natural
70
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food stores, mainstream supermarkets, and direct outlets, such as farmers markets. A consistent set of national standards for organic productton and processmg, which 1s currently being developed by USDA, IS expected to enhance consumer confidence in the United States. Development of these standards was required by the Orgamc Foods Productton Act, which was passed by Congress as part of the Food, Agriculture, Conservation, and Trade Act of 1990. This legtslatton requn-es that all except the smallest organic growers will have to be certified by a state or private agency accredited under the national standards. The National Organic Standards Board, which was appointed by the USDA to help implement the provisions of the act, currently defines organic agriculture as a sustainable production management system that promotes and enhances biodiversity, biological cycles, and so11 biological activity. It 1s based on mmtmum use of off-farm production inputs and on practices that mamtam organic Integrity through processing and distributton to the consumer (38). In tandem with the growth m demand for food with a green label is the demand for food with less pesttctde residue. Btopesttctdes are viewed as being safer than chemical products (27). Early m then development, biopesticide companies, mcludmg Biosys, Consep, Ecogen, and Mycogen, were forced to concentrate then marketing efforts on niche markets (prtmarily vegetables and fruits) because products did not have the price/performance (efficacy) characteristics necessary to compete m the larger pesticide markets They are now estabhshmg themselves in major markets lrke cotton and corn. They found the less-competitive niche markets were a sheltered corner where they could mature. These small markets gave biopesticides a sales base for products that did not have the attributes desired m larger markets. Biopesttcide companies have since invested heavily m upgrading products, so they can move beyond then- niche market base mto major pesticide markets (39). Biopesttcide companies have made substantial improvements m recent years and have become more competitive with conventional chemical companies Most btopestlctdes have improved prtce/performance charactertsttcs as a result of improved technology, which has resulted m better efficacy and lower costs. For example, recently developed Bt products, mcludmg Bt (CryMax) (Ecogen) and Mattch (Mycogen) have more concentrated toxins, give more consistent performance, have longer residual formulations, and contam relatively more potent Bt strains. These improvements have allowed the companies to lower prices, Finally, companies have reposmoned products m markets where the products add value, and have focused on educating growers on the use of the products. For example, nematodes have been repositioned to address selected citrus
Policy
Influences
71
on Biopesticides
and ornamental markets. These sorts of reposltloning, markets, should continue m the future, as companies products are most effective.
focusing recogmze
on selected where their
References 1 Carlson, G A and Castle, E. N (1972) Economics of pest control, m Pest Control Strategres for the Future, Commlttee on Pest and Pathogen Control, National Academy of Sciences, Washmgton, DC, pp 72-l 03 2 US Congress, Office of Technology Assessment (1995) Bzologzcally Bused Technologzesfor Pest Control, OTA-ENV-636, US Government Prmting Office, Washmgton, DC 3 RIdgeway, R , Inscoe, M , and Thorpe, K (1994) Bzologzcally Bused Pest Controls Markets, Industrzes, and Products, US Department of Agriculture, Agl ~cultural Research Service, Washington, DC 4 Ollmger, M and Fernandez-CorneJo, J (1995) Regulatzon, lnnovatzon, and Market Structure zn the US Pestzczde Industry, Agricultural Economic Report 7 19, US Department of Agriculture, Econom.lc Research Service, June 5 LandIs, D A and Orr, D B (1996) BIologIcal control approaches and apphcatlons, Electronzc IPA Textbook (Radchffe, E. B and Hutchlson, W D., eds ), Unrverslty of Minnesota and the Consortium for International Crop Protection, Mmneapolls, MN 6 Poritz, N (1996) Biological control of weeds, m Bzologzcal Control of Weeds 1996 (Pontz, N , ed ), Montana State Umversity Press, Bozeman, MT, pp l-21 7 Hunter, C (1994) Supplzers of Beneficzal Organzsms zn North America, PM 9403, Cahforma Envlronmental Protectlon Agency, Department of Pestlclde Regulatlon, Sacramento, CA. 8 Edwards, C R and Ford, R. E. (1992) Integrated pest management In the corn/soybean agroecosystem, m Food, Crop Pests, and the Envzronment (Zalom, F G and Fry, W E , eds ), American Phytopathologlcal Society, St Paul, MN 9 Environmental Protection Agency (1995) EPA Issues condltlonal approval for full commercial use of field corn plant pestlclde targeting the European corn borer, EPA Press Release, Washington, DC 10 Zalom, F and Fry, W (1992) Food, Crop Pests, and the Envzronment, American Phytopathologlcal Society, St Paul, MN. 11. Nleblmg, K (1995) Agricultural biotechnology compames set their sights on multi-bllhon $$ markets, Genet Eng News 12, I,2 12 Hoban, T and Kendall, P. (1993) Consumer Attztudes about Food Technology Project Summary, Extension Service, North Carolma State Umverslty, Raleigh, NC 13. Economic Research Service (1997) Agrzcultural Resources and Envzronmental Zndzcators, US Department of Agriculture, Washmgton, DC 14 Aspelm, A L (1984) Pestzczde Industry Sales and Usage I992 and 1993 Market Estzmates, BEAD, Office of Pestlclde Programs, US EnvIronmental Protectlon Agency, Washington, DC, June
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14a. (1996) Pesttctde and Toxzc Chemtcal News, August 21, FCN Publrshmg, Washmgton, DC. 15 US Envtronmental Protectton Agency (1996) Major issues tn the Food Qualzty Protectton Act of 1996, Preventron, Pesttctdes, and Toxic Substances, Washmgton, DC, August 16 Jaemcke, E (1997) The Myths and Realtttes of Pesttctde Reductton, Henry A Wallace Instttute for Alternattve Agriculture, Beltsville, MD 17 US Environmental Protection Agency (1997) 1996 Food Quality Protectton Act Implementatton Plan, Preventton, Pesticides, and Toxic Substances, Washmgton, DC 18 (1996) Farm Chemrcals Handbook, Meister, Wtlloughby, OH 19 Vandeman, A , Fernandez-ComeJo, J , Jans, S , and Lm, B H ( 1994) Adoptton of Integrated Pest Management tn US Agrtculture, AIB-707, US Department of Agrtculture, Resources and Technology Divrsion, Economic Research Service 20 Ferro, D N (1996) Cultural controls, m Electrome IPM Textbook (Radcliffe, E B and Hutchison, W D , eds ), Umversity of Mmnesota and Consortium for International Crop Protection, Mmneapohs, MN 21 Lm, B H and Delvo, H (1994) Pest Management Practices on 1993 Corn, Fall Potatoes, and Soybeans, Natural Resources and Environment Drvision, Economic Research Service, US Department of Agriculture, Washmgton 22 Kahn, A (1971) Economtcs ofliegulatton, Wiley, New York 23 US Congress, Office of Technology Assessment (1986) Technology, Publzc Poltcy, and the Changing Structure ofAmerican Agrtculture, OTA-F-285, US Govemment Prmtmg Office, Washmgton, DC, March. 24 Scherer, F M. (1980) Industrial Market Structure and Economtc Performance, Rand McNally, Chtcago 25 National Research Council (1993) Pesttcides tn the Diets ofInfants and Children, National Academy, Washington, DC 26 Office of Pesticide Programs (1996) Office of Pestrctde Programs Annual Report for 1996, Environmental Protectton Agency, Office of Pesticide Programs, Washington, DC, November 27 Anonymous (1996) Future development of biopesticides expedited by FQPA Pestrctde Toxic Chem News 24, 19-20 28 Cropper, M L., Evans, W N , Berardi, S J , Ducla-Soares, M M , and Portney, P R (1992) Determinants of pesticide regulatton a statistrcal analysts of EPA decision makmg, J Poltt Econ 100, 175-197. 29 Cropper, M L., Evans, W. N., Berardi, S. J., and Ducla-Soares, M. M. (1992) Pestictde regulation and the rule-making process, Northeastern J Agrtcultural
Resource Econ 21,77-82 30 Abler, D G (1992) Issues m pesttcide policy Northeastern J Agrrcult Resource Econ 21,93,94 3 1 Pease, W S , Liebman, J , Landy, D , and Albrtght, D (1996) Pesttctde Use tn Caltfornta. Strategies for Reducing Environmental Health Impacts, Calrforma Pohcy Seminar, Umversrty Environmental Health
of Califorrna,
Berkeley, Center for Occupatronal
and
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32. Bender, J. (1994) Future Harvest Pesttctde-Free Farmtng, Umversity of Nebraska Press, Lmcoln 33. World Agricultural Outlook Board (1997) Agrtcultural Baselzne Projectzons to 200.5, Refecttng the 1996 Farm Act, WAOB-97-1, US Department of Agrtculture, Washmgton, DC, February. 34. Comanor, S and Gelburd, J (1994) Ecosystem approach to resource management, Agrzculturai Outlook, AO-204, Economrc Research Service, US Department of Agrtculture, January-February 35 National Research Counctl (1995) Ecologtcally Based Pest Management New Soluttons for a New Century, National Academy, Washington, DC. 36 Umverstty of Mame (1996) The Ecology, Economtcs, and Management of Potato Cropptng Systems’ A Report of the Ftrst Four Years of the Maine Potato Ecosystem Project, Bulletm 843, Mame Agricultural and Forest Expertment Statton, Orono, ME, Aprtl 37 Natural Foods Merchandiser (1996) Widening market carries orgamc sales to $2.8 billion m 1995, Nat Foods Merchandiser 17, 5-7 38 Ricker, H S (1997) Nattonal organic program: status and Issues, m Proceedtngs of the Thzrd National IPMSympostum/Workshop, US Department of Agriculture, Economic Research Service, Washmgton, DC, pp. 63-65. 39. Btosctence Securmes (1996) The Outlook for Bzopesttctdes, Btoscience Securtties, Inc , Ormda, CA 40 US Department of Agriculture (various) Agrzculturaf Chemical Usage Fruzt Crops Summary, Nattonal Agricultural Stattstics Service and the Economtc Research Servwe, Washmgton, DC 41 US Department of Agrtculture (various) Agrzcultural Chemtcal Usage* Vegetable Crops Summary, National Agrtcultural Stattsttcs Servtce and the Economic Research Service, Washmgton, DC
II BIOFUNGICIDES
Commercial
Development
of Biofungicides
Raphael Hofstein and Andrew Chapple 1. Introduction The commercial development of biofungicrdes received a significant boost m recent years, primarrly because of impressive progress in the rsolatron and charactertzatron of novel strains of microorgamsms that can fulfill the mam characteristics of a brofungrctde, which are the consistent suppression of pathogens under field conditions, and easy mass production in standard fermentation facrlrties (1,2). Progress was imtially slow because of the mherent properties of the natural isolates, most of which are obligatory parasites that require the presence of a host for propagation (3). With the meteoric development m recent years of new tools m industrial molecular biology, and, more specifically, m the area of fermentation technology, srgmficant progress has been made m the commercral development of cost-effectrve brofungrcrdes. The conceptual and methodological consideratrons leading to a commercially vtable product for biological control of fungal diseasesIS the theme of the followmg discussion. The arena of btofungicide development has been classified mto three categories: sorlborne pathogens; foliar diseases;and postharvest rots durmg storage All three have been extensively documented over the past decade (4.Q. However, only a few brofungrcrdes have been successfully promoted through regrstratron, and even fewer have managed to cross the barrier between basic and commercral development. Those that have managed to overcome the hurdles of actually becoming a commercral bropesticrde have included in then development, right from the inception of an research and development program, a crmcal analysts of market needs and potential, as well as financtal conslderatrons, such as cost of goods (9). From Edited
Methods UJ B~ofechnology, vol 5 Bmpestmdes by F R Hall and J J Menn 0 Humana Press
77
Use and Delwery Inc , Totowa, NJ
78
Hofstein and Chapple
Historically, the list of commercially viable blopestlcldes Included almost exclusively Baczllus thurzngzenszs (Bt)-based products for the control of lepldopteran pests (20). The hst of Bt products became very lmpresslve m recent years, primarily because of DNA recombinant technology, and products entermg the market have proven to be very effective against a whole array of economically important pests (21). However, unlike Bt products that rely on an inert protemaceous crystal toxin as the active ingredient, most of the blofungicides under dlscussion require an Intact, hvmg cell for function (12). Moreover, since Bt-based products are relatively inert, they can be readily incorporated mto a user-friendly formulation. Intact-cell-dependent blofunglcldes, on the other hand, require very delicate and rather sophisticated approaches m the design of a commercial formulation, one that will ensure product stablhty durmg storage (I.e., shelf life), as well as rellablhty during apphcatlon (23). As discussed by Baker (2415) and Baker and Scher (26), It IS well recognized that a substantial amount of biological control occurs m nature, and that increased or even spectacular suppresslon of plant disease can occur naturally m some agricultural situations These events, though well documented and potentially useful for the isolation of blologlcal control agents, did not result m the development of many commercially viable products. Likewise, the delicate equlllbrlum between saprophytlc and parasitic mlcroflora on the phylloplane has been dlscussed by Dubos (17), who brilliantly made reference to blocenosls as the backbone of such an equlllbrmm Again, because of the natural balance between antagonists and pests, disease may be suppressed. However, m order to Implement these features mto economically feasible control of fohar diseases, a better understanding of the dynamics of antagonist-pathogen interactions 1s required. Moreover, the antagonist has to fulfill certain criteria before it can be considered a legitimate candidate for promotlon to a commercial blofunglclde Several reviews have addressed aspects of maxlmlzmg the chances of developing a naturally occurring organism (18-20). The criteria for a successful blofunglclde can be summarized as follows. Effective suppression of the fungal pathogen before It causes economically important damage to a crop Consistent performance under authentic condltlons of crop management and the crop environment Adaptation to exlstmg integrated pest management (IPM) schemes of disease control Price competitiveness with other means of combatmg the same target pest Compatlblhty with other chemical or blologlcal treatments targeting other pest(s) Adaptation to commonly used farm agronomic methodologies Preservation of naturally occurrmg beneticlal antagonist(s) of related or nonrelated pests User and environment frlendlmess
Commercial
Development
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The hkehhood for successful development of a commerctally vtable btofungtctde 1smaxtmtzed once all these crtterta are fulfilled. To obtain a reliable program that uses such products as prominent building blocks of a comprehensive IPM approach, it 1scrucial, right from the onset of the research program, to evaluate the adaptation of a naturally occurring orgamsm mto an economttally feasible strategy of pest control. The prmctpal drawback to developing btofungtctdes is that it is very difficult to harness the organisms to mdustrral processesof mass productron, especially fermentation m sterrle vessels, as well as incorporatton mto user-friendly formulations (21). Clear understanding of the delicate balance between antagonistic mtcroorgamsms and crop pests could eventually lead to manipulation of ecosystems to enhance crop protectron (22-24). Regarding sotlborne and foltar pathogens, the impact of naturally occurring saprophytes on disease suppression is well documented. However, tt 1s now established that it IS insufficient to rely on mnocuous mrcroflora to ensure the high degree of plant protection required m modern agriculture. The balance has to be shifted m a direction antagonistic to the fungal pathogen, or else to impose quantttattve advantages to the antagonist. The latter is the tmpetus for seeking an alternative approach by vn-tue of the development of commercial biofungtcides, and this can be most eastly attained by directed mtroductton of a selected antagonist into a given btocenosts, as prevtously proposed m excellent review articles (see refs. 25 and 26). 2. Steps in the Development Process The development of a cost-effective btofungtctde is an intricate undertakmg. The various steps involved in the process are m a quote rrgid order, which IScritical tf failure IS to be avoided. The authors describe a sequence of steps m the development strategy based on experience reflecting successes,but also failures, m several campaigns. These steps are depicted m a rather rtgorous and critrcal fashion. 2.1. Screening for Naturally Occurring Microorganisms The best source for potentially effective biofungrctdes is the site of natural interactton between a pathogen and tts antagonist. For instance, hypovirulent strains of a plant parasite were sought in sites of declining disease, or, in the case of soilborne pathogens, screening for mtcrobtal antagomst m suppressive soAs (27). In the case of hyperparasttic antagonists such as Ampelomyces quzsqualu, the hyperparastte of various powdery mildews (PMDs), the pathogen could serve as a carrier, and, therefore, colonies of the pathogen can actually become an ideal site for screenmg (28-30). Several criteria should be used as guidance from onset of the screening process, including extent of antagonism m a bioassay that best resembles the commercial envnonment (31,32), adapt-
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abtltty of the antagomsttc mtcroorgamsm to artttictal mass-productton factlttres (33), and versattltty of antagomsm to vartous spectes of the pathogen on dtfferent crops (34). 2.2. Selection of the Most Cost-Effective Fermentation Process Several methodologies have been adopted for mass productton of pesttcidal mtcroorgamsms, but the only economtcal approach currently avatlable IS one that relies on submerged fermentatton m a sealed fermentation tank. All others, including fermentation m a solid matrix, require an unacceptably long process m especially dedicated equipment. The latter has a detrimental effect on cost of goods, and therefore becomes prtce-prohtbttlve. Submerged fermentatton has proven to be the preferred technology, and one that allows for hrgh ytelds m a relattvely short period of time To attain a cost-effective process, tt IS rmperatrve to select a growth medium that rehes on mdustrtal waste products wellbalanced to supply an optimal ratio between nitrogen and carbon (35) Every development program must address such elements as low-cost nutrients and opttmizatton of the time-course. The prmcrpal author has reviewed these elements (36) describing the development of AQ 10, a btofungtctde developed for the control of PMD, based on A quuquah. 2.3. Development of Bioassays A system that can adequately simulate an authentic snuatlon m a commercoal setting 1sa crtttcal element in a proper research and development program (37). The chances of selectmg the mtcrobtal tsolate of choice to be promoted from a ubtqurtous microbial strain mto a cost-effecttve btopestictde can be maxrmtzed by a versatile assay system The btoassay has to reflect the mode of actton of the product. Although most research efforts resulted in the eluctdation of anttbrottc-producing bacteria for pathogen control that can be simulated m a Petri dish, progress made m recent years m industry, gave rise to more complex fungal agents, whose mode of action ISbased on parastttsm or competttion for space and nutrients. A preferable assay system for such agents IS the intact-plant simulator, tested m a growth chamber or greenhouse. 2.4. Development of a User-Friendly Formulation Product formulatton IS a most crtttcal aspect of the entire development program. A user-friendly formulatron has to fulfill several crrterra, mcludmg allowmg a mtcroorganism to retain and express tts pesttctdal properties; providing a stgmficant extension of shelf life of at least 6, but preferably 18 mo, at ambient conditions, so that the biofungtctde can be stored over two seasons; and allowing the active ingredient to be applied wtth extstmg appltcatton equtpment. During the course of developmg AQ 10 for commercial acceptabtltty,
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several major changes m the features of the formulation were requtred m order to fulfill the above criteria. After screening several options, a water-dispersible granular formulation proved to be most adequate for the product. It is chtefly because of this formulatton that AQ 10 reached commerctaltzatton relatively quickly Better understandmg of market needs durmg the prehmmary stage of product development may asstst in the process of tatlormg the right formulatron to each product 2.5. Establishment
of an Extensive
Field-Testing
Program
It IS cructal, and yet insufficient, to design a powerful screening broassay When adopted for the development and fine-tuning of a chemical pestictde, such bioassays often adequately predict how a new product will manifest Itself m the field; however, this ISdefimtely msuffctent m the caseof biofungtctdes. Modes of action, such as micoparasitism (e.g., Ampelomyces [38], T~rcI?odevma harzlanni 1391, and Giocladwm roseum [40l) or competttton for space and nutrients, such as in the case of, e.g., ASPIRE (Ecogen, Langhorne, PA) (41) and BIOSAVE (Ecosctence, New Brunswick, NJ) (42), for postharvest decay control, can only be determined partially in a simulator or bioassay. To demonstrate its full potential, a product must be tested m the field, and preferably in large plots, rather than the small replicated blocks commonly used for statistical analysts. Field trials are also the best stage to determme how a biofungicide can be incorporated mto an IPM program (43-46). 2.6. Preparation of a Registration Package Since biofungicides are considered envtronmentally friendly, most registration authorrttes view them as safe, and hence justify a relatively fast track of revtew (47). It 1s the authors’ experience that each case IS different, and, according to the purpose of the program and the target pathogen, the registration authorities will select the evaluation process to meet the nature of the appltcatton. For instance, biofungicides for postharvest decay control m packmghouses were relieved of the need to conduct ecological testing, since the orgamsms are expected to be applied only in a confined environment (48). Btopesticides can be exempted from tolerance requirements, and usually are relieved from any significant periods of field re-entry intervals (REI). Such elements are clear advantages of a biopesttctde, and will be obtained only when properly represented during the registration process. 2.7. Establishment of Demonstration Programs Small-plot, randomly replicated trials are part of the prerequtstte for product registration, but demonstration trials in which the product manifests itself under the authentic conditions of a commercial setting are crucial for biopesticides m
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general, and biofungicides m particular Once registered, a btofungicide can, at a relattvely early stage of its development, be subjected to such demonstration programs without having to absorb the burden of crop destruction. The benefits of such trials are threefold: first and foremost, they help the end user get acquainted with the prmciple of disease control through competition and/or parasrtism; they are also essentral for an adequate analysis of the formulation and its adaptability for a commercial setting; last, they are the only setting that allows for proper design of IPM schemes (49,50). 2.8. Design of User-Friendly Protocols Since biofungicides are a relatively new component m the arsenalof tools avallable to the farmer as part of the agronomic routine, the protocols must be very detailed, and certain issues,such as rates, application intervals, and methods of application, must be addressed cautiously. It is, conceptually, as well as techrntally, erroneous to assumethat the extrapolation from a standard protocol representmg a chemical fungicide to that of a btofungicide ISlmear. It definitely is not. A good example is the matrix of permtssible tank mrxesof AQ 10 and chemical nutrients, msecticides, and fungicides (51). Incorporatton of AQIO into an IPM program calls not only for legitimate alternation between a chemical and biological agents: In general, the two have to be mcluded m the sametank mix, otherwise, the whole program can be questioned from an economic standpoint. AQlO became commerctally recogmzed and acceptable only when a breakthrough had been made m the area of compatibility with other treatments. Compatibthty, together with fine-tuned ratesofapphcation, and optimization of Intervals, are key elements in the protocol as it 1spresentedto the end user. It must be stressedthat the primary concern of the end user is the cost-effectiveness of the product. 3. Product Development: AQ10 as a Test Case The development of A guzsqualzs mto a commercial product (AQl 0) for the control of PMD on a variety of crops is an mstructive example of the authors’ views of the learning curve related to the commercial development of biofungicides m general. It is a truism that the most difficult step for any biological control agent is that from glasshouse to the field, something very few biocontrol agents have managed. Because AQ 10 has successfully crossed this hurdle, a large part of this chapter is devoted to a description of the development trials, and, more importantly, the thmkmg behind the trials and the analysis that followed It is certainly not enough to conduct trials merely to see if it works, and at what rates, and so on. Especially for brologicals that will be combined into IPM programs, bringing the real world mto the trials and designmg assessmentand scoutmg schemes that are realistic for the end user are critical components of trial design.
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3.1. From the Glasshouse to the Field A. quisqualis has a field- and glasshouse-testing history quite at odds with the conventional academic approach. Although it started its developmental career in the laboratory and the glasshouse (52,53), the speed at which it progressed to the field was very different from that of the usual process for microbial agents. Most other agents have undergone academic laboratory and glasshouse study, and, while learned publications are prepared, passthrough a great number of generations prior to being subjected to the intended environment: the field. The latter route, namely the development of the agent with the glasshouse setting in mind, can be detrimental, because commercial application is much broader than just tailoring a product for the glasshouse industry. Such an approach may slow down commercial development, and the strain may go through even more generations before a desire to increase the range of use of the organism (or the realization that the glasshousemarket cannot sustain an on-going research program, let alone a company) causes the researchers to expand their horizons. By now the strain is very much at home in the test tube and flask, and the sort of selection pressures put on the active ingredient, the spores, in the fermenters can cause problems. The organism is first selected for an environment completely at odds with the real world-the small-scale fermenter or lab production system-and then is expected to perform in an environment where a pathogen has many advantages. In the case of PMD, these advantages include continued selection pressure by the grower for not only resistance or tolerance to any conventional pesticides, but also speed of infection and subsequent spread throughout the crop, especially in situations like the glasshouse and vineyards, where regular prophylactic sprays are the norm. AQlO bypassed some of this by being tested in the field very early. As a result, development decisions were field-driven, not laboratory- or glasshouse-driven. Not only do growers’ habits and cultures have an impact, but so does mass production in a fermentation vessel. The fermenter is analogous to a two-edged sword. Selecting for fast-growing, high-yielding strains that are tolerant to fermenter conditions may be an advantage. In the case of insecticidal nematodes or bacilli, fermenter-targeted strains may be narrowing the range of expression of the organism toward the faster-acting end of the spectrum. Taking the natural population ofA. quisqualis, there is probably going to be a normal distribution of behavior regarding the likelihood of the spore to germinate, or other characteristics. Clearly, a product for the control of PMD is best composed of spores that germinate at the least provocation, and it is presumed that the fermenter selection pressure drives the organism toward rapid response to signals for growth or germination. To put it crudely, those cells in the original inoculum that grow fastest will have a significant advantage over any slowerresponding cells, so that the progeny (i.e., the AQlO formulation itself) is
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largely made up of fast-responding members of the natural population. This may or may not act in favor of the preferred selection of the population that ought to be manifested in the authentic environment of the open field. Such considerations must be included in the design for optimal screening of the best naturally occurring strain to be selected for commercial development. The AQlO strain of A. quisqualis, which eventually became the strain of choice, was isolated from a semiarid part of Israel (54), and then transferred to other parts of the world for further field development. The advantage is that upon transfer to other locations, such as vine-growing areas of Italy, France, California, and South Africa, the spores had to adjust to less extreme, more humid environments than those of the original locale. Hence, the AQ 10 strain of A. quisqualis is probably performing reasonably well, having been taken from an environment where rapidly exploiting such conditions would be important. The PMD present in the vineyard has been under a very different set of environmental pressure in different parts of the world. Therefore, and almost as a guideline, if a replacement to the current strain of AQ 10 should be required, or if a biological control agent for downy mildew or gray mold in vines is needed (55), then the organism or strain chosen should be sought in semiarid climatic zones,where the optimal conditions for the control organism are close to those required for normal conditions of the targeted disease. Similar thinking was applied to the development of a yeast strain (Aspire) for the control of postharvest decay pathogens. The two may only be differentiated by the fact that the latter is destined for the confined environments of a packinghouse (56). It is important to note that biofungicides, such as AQ 10 and ASPIRE, which affect the pathogen via hyperparasitism and competition, respectively, are at a disadvantage whenever the environment favors the fungal pathogen, simply because the pathogen develops at an explosive, almost epidemic, rate (57). To avoid such scenarios in vines, and in order to establish a more persistent level of disease control, AQlO was applied frequently (Le., every 1O-14 d), and as part of a more comprehensive IPM approach in which sulfur, sterol-inhibitor fungicides, and AQlO offer a variety of tools for PMD control. Multiple applications apparently work by establishing a critical mass of spores in the treated area. These spores are not expected to survive long in the environment, and must interact with existing colonies of PMD quite rapidly, It has been observed in several different locations that, on the surface of leaves, AQ 10 can remain dormant in the absence of the pathogen for up to 14 d, but only when humidity is constantly high (i.e., >90%). In the normal conditions of the greenhouse or, even more so, the open field, the spores will have to germinate and interact with the host within several hours. This is the rationale behind the strong recommendation to apply the product at cooler or more humid periods of the day.
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Early m the development of AQlO as a field control agent for PMD control in grape vmes, it was assumed that it could be used as a stand-alone treatment, with the idea of replacing chemical fungicides almost entirely Although AQ 10 gave consistently improved control of PMD when compared with untreated vines, disease control was too often unacceptable from a commercial viewpoint, especially toward the end of the growmg season.It was therefore decided that the chief strategy of use for AQ 10 would be as a replacement for conventional chemical control during certain morphological stages of vme and grape development (e.g., bloom to bunch closure, or from closure to verarson). For example, for a season of seven or eight 14- or 10-d interval sprays, the first two would be sulfur (m keeping with general PMD control practice), the next three AQlO, and the last 2-3 sprays would be an ergosterol biosynthesis inhrbitor (EBI), or similarly powerful chemical. However, field results were still extremely variable using this approach. Although, in general, AQ 10 performed less effectively m high disease pressure situations and with highly PMD-susceptible vine varieties, there were fatlures of control m situations that appeared optimal for AQlO, and other, excellent and reproducible results against high disease pressure m non-PMD-tolerant varieties. To resolve these mconsistenties and come up with user-friendly guidelmes, the results from several trials were closely analyzed. Two methods of disease assessmentwere used m the field trials. disease mctdence and disease severity. Disease Incidence reflects the percentage of leaves or grape bunches showing any PMD symptoms. Disease severity, on the other hand, scores the average diseased surface area of leaf or berry covered with PMD symptoms One of the prmcipal problems with the analysis of a season’s field data from multiple sites is the variability m assessors’estimates of disease severity. It is far easier to standardize disease incidence between cooperators or field-trial operators. However, Ecogen was fortunate, because, for two consecutive years, five of SIX trials m one of the programs were all assessedby the same highly sktlled and experienced cooperator, who on several occasions had shown a very high level of consistency of disease estimation, when results were reassessedby outside observers. It was therefore possible to assessthe relationship between disease mcidence and the underlying disease severity, and also the relationship between disease mcidence at one assessment date and dtsease severity at the next. The former is important as a measure of the accuracy of disease incidence for estimating severity; the latter as a measure of the reliability of predicting later disease severity based on current estimates of disease incidence. The data was collected from four different sites, whtch represent highly qualified grapevine growing areas in Italy. (It should be noted that a similar analysis has been made for other parts of the world, with virtually semi-
86
Hofstein and Chapple
lar results.) In each sate, AQlO was tested as part of an IPM scheme with two sulfur sprays at bud-break, followed by 2-3 AQlO sprays and followed by 23 sprays of an EBI. One other component m the blend of treatments was a selection of surfactants chosen to enhance the germmatton of AQ 1O’s spores. For SIX mdtvidual trials at the four sites, It IS clear from Fig. 1A that, wtthm sites, there IS a good correlatton between the underlymg disease severity and the disease incidence assessed. However, there was no such correlatton when considering the individual treatments (Fig. 1B). Therefore, the data was reanalyzed, taking the individual blocks from the sues, and treating these as expertmental units This approach makes sense when considering the variability wtthm sites* Although overall mean effects might differ from sate to site, the variability within any given site was always high, and blocks from one site gave levels of disease severrty that might be expected at another Analyzmg the data this way, Fig. 2A shows a clear linear relattonshtp between assessment of disease incidence and the underlying disease seventy. Similar lmeartty IS attained for the same data when broken up with respect to treatment regime, as opposed to site (Fig. 2B). However, It was the predictive power of disease incidence that was of particular significance for the future of the product development. As It appears m Fig. 3, from the relationship between the dtsease inctdence at the first assessment date and the disease severity at the second assessment date, there was a clear and reliable relationship between the two measurements. It was, therefore, decided that incidence could be used by a grower as a disease-threshold mdtcator for spraying The data has also been depicted to reflect the prolonged impact of AQl 0 on disease progresston. Figure 3 represents the correlation of severtty m second assessment as a function of percent mcrdence m the first assessment. The question reman-red. What threshold should be used? An alternative way of consrdermg the data presented IS as percent effective control (i.e., the reduction m PMD severity when compared with the untreated control plot included m the trial). Figure 4 represents the analysts of the data when the latter approach has been adopted. It reveals two important pomts. First, the regresston line of percent effective control at the second assessment date vs disease incidence, measured at first assessment date, IS far shallower for the standard chemical regtmen than for any IPM regimen including AQ 10 as a treatment. The difference m slope 1s a measure of the relative fragility of the btologrcal control agent, which should be interpreted as an mdlcatton that, at least m the case of btologrcal fungicides, there IS lrttle room for error m timing of appltcation. Once the PMD reaches a certain level of mfestatlon, the AQIO regime loses acceptable control. Second, rt 1sclear from these data (Fig. 3) that the threshold for effective control by AQ 10 IS under 30% disease mcldence. growers typically accept about 10% severity as a legitimate level of
0
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Commercial Development
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89
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damage to the crop at the end of the wine-grape season. Since these observations were made, and as a critIca measure during commerclahzatlon of AQ 10 for a variety of crops with much lower damage tolerance, the product has been presented as a preventative treatment that is a very effective tool for PMD control, as long as it ISapplied when visible incidence is nearly zero (mstructions to growers are to use the product when diseaseincidence doesnot exceed 3%). % Disease seventy assessment 1(treatmentn) % Disease seventy assessment2 (treatmentn) % Disease seventy assessment 1 (untreatedcheck) - % Disease seventy assessment2 (untreatedcheck) (1)
Figure 4 depicts the percent disease suppression, but with no reference to the existing level of disease;Figure 5 shows the percent relative control, 1.e, the percent suppression of disease over the period of the two assessmentsas a function of the background disease levels at the time of the assessment(Eq. 1). For example, if a treatment had 12% disease severity at the first assessment, with a background of 20% m the untreated check in that block, and 16% severity at the second assessment,with a background disease severity of 45%, then
90
Hofs tein and Chapple 100
~+m.&O ---_8 -. t3 0 O--------Oa-----_ ‘. ---------~~~ ‘. ----.-____ .JI/l. v . --__ 0 *‘ j .A,Qy)bf am0 . . .i . . ” . ‘. ‘.. . . =ll . . .. . . -\ A * -. . t. Ii- . . . . A .. ’ ‘. I G . -\ ‘. - - - AQ regression line “9 _ Chemical regression line ’ “=y-; . * . A IPM Regime I , .. n IPM Regime II . T IPM Regime III . . _ * IPMRegime IV . o Standard chemical I
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Fig 4 Correlation of disease mcldence at first assessment date with % effective control at the second assessment date (see text), usmg mdlvldual blocks from trial regimes as data points (1.e , data points are registered with respect to treatment) the PMD will have been suppressed by 24 5% (a posltlve value; Fig. 5) However, if the PMD 1sescaping control, percent relative control will be negative.
It appears from Fig. 5 that the higher the disease mcldence at the first assessment date, the more likely it IS that the PMD will not be controlled There are several caveats. The first disease assessmentswere all performed after at least one of the AQ 10 sprays had been completed, and the second assessmentsafter at least one or two more AQlO sprays Intervals between assessment dates ranged from 7 d when disease pressure was very high, to 21 d, when disease pressure was much lower. Hence, the mltlal disease pressure at the first assessment date was generally higher in the AQ 10 treatments than m the chemical ones, and subsequent control of disease would have been more difficult to accomplish m the AQ 1O-treated plots than m the chemically treated ones. In the cases presented, the disease was allowed to run Its course. Useful mformatlon was obtamed about control effects at high disease threshold, but these would not normally be obtained m a grower’s vineyard, because AQIO would have been replaced by a more robust method earlier m the season as an act of eradication. The question still remains: What exactly 1sthe threshold to recommend to growers?
Commercial
Development
of Blofungicides
r
-60 % Disease incidence, 1st assessment
Fig 5 Relatronshlp between % disease incidence at the first assessment date and % relative control at the second assessment date (see text), comparing the chemical standard regimen (filled triangles and all the AQIO treatments combmed (hollow circles) PMD infectlon 1s microscopic. The observable symptoms (small powdery colomes on leaves or berries) are evidence that the infection has been present for some time. Requtring a grower to use a microscope is clearly unreasonable, so the threshold for changmg from AQlO to conventional chemicals, based on observable symptoms reflected m scoring for percent incidence, has been set lower than the data presented actually mdlcates. In practice, and from other research, the manufacturer has been recommending a much lower threshold, approx 3% Incidence. This has two advantages: First, scouting need not be at too short an interval, requiring excessive time and labor, second, the grower has confidence m the control of the disease, even late in the season. The above threshold became a firm guideline. Figure 6 shows the result from trials in an area heavily infested with PMD. Yet, because of careful disease management, and with a much better understanding of the attributes and hmitatlons of AQ 10, it became the first blofunglclde to be officially included in IPM programs. It may, after all, appear a trivial discovery, but, because of Its mode of action, bringing hyperparasltlsm onto existing colonies of PMD, it took many field trials and much sophisticated data analysis to be able to reach such conclusions, and to draw practical guidelines from them.
Hofstein and Chapple
92 Data on bars is % disease incidence associated with the
Fig 6 Trial results for Bourgogne (France) site, showing % disease severity for chemical, AQ 10, and untreated regimens, for three assessment dates Numbers on bars are % disease severity
3.2. Timing and Quality of Spray Applications Spray application techniques have been known to play an important role m the performance of many pesticides (58). It appears that it is an even more important consideration in the commercial development of biopestictdes, and products of AQlO’s nature, in particular. One prerequisite IS that the apphcanon equipment used m trials must match that of the end user. Aspects of thts problem have been demonstrated m preliminary work (59), which shows that the distribution of particles of A quuqual~s m a spray tank differs markedly before and after passage through a pump (Fig. 7). Because efficiency of application of AQlO is dependent on distributing single spores evenly through a canopy, clumpmg of spores can decrease the efficiency of apphcatton stgmficantly. It was also shown that the dtstrtbutton of particles of a mineral surfactant (60), considered an enhancer of spore germinatton, also differs dramatically preand postpump. The particle distribution for the surfactant is depicted in Fig. 7. Surfactant systems for emulstfymg oils that are nonfungnoxtc are difficult to find, and, although the mineral oil used in most AQlO studies has some
01
0.15
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A. quisqualis
Ftg 7 The effect of pump sheer stress and atomtzatton on the frequency dtstrtbutton of A qusqualzs sporesand adJuvant or1(ADDQ) m the spray volume, pre- and postpump B, stirred m a beaker; T, stirred m 50 L of water m a spray tank; R, after 5 min recycling through a diaphragm pump; and S, after recycling and then spraying through a hydraultc flat fan nozzle (Reproduced wtth permtsston from ref. 59)
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Hofstern and Chapple 12 days after inoculation a
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Fig 8. Compartson of two strategres for trmmg start of A quuqualls apphcatron applymg only at first stgns of disease, or applying 1 d after moculatton again at first signs of dtsease (Glasshouse trral In zucchnn, agamst Sphaerotheca fuhgznea ) Bars with the same letter do not doffer at the P < 0 05 level (Tukey’s HSD test) surfactant properties, these were found to be msufficrent to form a reasonable emulsion. When drops are created by the atomtzatron system, the probabrhty that a spore IS delivered with an or1 droplet must be high (near 1.O) for the enhancement properttes of the 011to take effect. It 1snoticeable that the small-scale trtals n-tthe glasshouse were done with an-pressurized systems that lack pumping or recycling. These hmttanon might have hampered the performance of AQ 10 Indeed, later on, all tnals were conducted with growers’ equipment, and, as tn the vane trials, efficacy has Improved on several crops, mcludmg roses and zucchnn, growmg m a glasshouse The trmmg of AQlO apphcattons has been addressed m more detarled test trials on cucumbers m glasshouses. One set of trials (Fig. 8) demonstrated that prophylactic treatment of cucumber resulted m effective suppression of PMD Essentially, AQlO apphcatton as early as arttficial mfection, followed by another appltcatton at first disease symptoms, gave very good results, whereas delaying application until disease symptoms were observed fatled to do so The results given m Fig. 8 mdtcate that spores of AQlO ought to be available at onset of PMD
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The tmphcation of these trtals for a standard recommendation to the glasshouse industry appears to be that A. quzsqualzs is effective for a short time after application, and that obtaining control very early m the disease progresston is crmcal. Hence, the grower must have a good idea of the ltkehhood of the dtsease occurrmg m the glasshouse, m order to trme the first apphcations. Again, coverage and even distribution of AQlO are crtttcal apphcatton parameters. Several risk-assessment models have been developed for the forecast of disease development. One of the most powerful examples has been described by Gubler et al. for PMD (62). This model has been translated into practical terms, and telemetry statlons have been mstalled rn several locations, to provtde warnmg of the onset of disease progression (i.e., ascospore release) These phenomena have been coupled to the prophylacttc concept of AQ 10, and tt was proved again, whenever the product was applied at relatively low levels of incidence, that tt provided commerctally acceptable disease control. Timing of appltcation and quality of applicatton are two major concerns in any program m proficient design of plant protectton, m general, and to btological pathogen control, m particular. However, in addition to inclusion withm IPM programs, assessmentof combmatton treatments of btofungictdes with environmental chemistry has also become a prtority, e.g., tank mtxes plus rates, advantages of addtttves H3, tdentificatton of alternate regtmes An exhausttve list of combinations has been screened, and the results offered to end users of AQlO (51). It became apparent that the latter mformatton contributed such value to the program that this has become a key component m every research and development program at Ecogen. 4. Current Status and Future Prospects Past reviews concernmg commercral development of btofungtcldes have highlighted the importance of cost-effective production of the active mgredient (62,63). Stgmficant progress has been made m recent years, and tt IS worth emphastzmgthe breakthroughs m massproductton of mtcrobial active mgredients through submerged fermentation, a method yteldmg large amounts of product m a cost-effective process. It has been demonstrated by the senior author, as well as other research groups, that a product-tailored formulation IS a key element m the whole program. However, what we have tried to accomplish m this chapter, which discussesthe experrence of developmg A. quuquah mto a commercial product, is to draw some basic conclusions that might be useful for others with a similar objective. It appears from this case study that the only way to learn about the attributes of a tentative btofungtctde is to throw tt mto an authentic commerctal sttuation as early in the program as possible. Such an approach, even though possessmgnumerous logtsttcal hurdles, apparently offers some significant shortcuts. This concept could be viewed as a useful gmdelme
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m any development program, but appears to be more profound m the development of blofunglcldes, since most of the small-scale slmulatlon assays commonly used m the development of chemicals fail to represent the commercial arena during the development of blologlcals. ASPIRE, a naturally occurring yeast for the postharvest control of decay, 1s a useful example of how the experience gathered during the development of AQ 10 helped accelerate the process of lmprovmg another blofunglclde The yeast suppresses decay formatlon via competition with germinating spores of prominent pathogens (e g., Penzczllzum spp) for space and nutrients. Although a standard tray assay, whereby artificially wounded and inoculated fruit ought to represent a situation in the packmghouse, has always been useful m the commerclal development of chemical funglcldes, the same has not been the case for blofungicldes In order for ASPIRE to express its full funglcldal potential, we had to rely on natural wounding and natural infestation (19). Again, when we consider the best approach to the development of blofunglcldes, taking the program to the end user 1sthe preferred approach. ASPIRE received a boost m the rate of development when it was subjected to testing m pilot- and commercial packing lines. Under these circumstances, it became apparent once agam that a blofunglclde cannot be promoted as a stand-alone program, but rather must be offered as part of a comprehensive disease control program, namely a tool m IPM Several accomplishments have been made m recent years m the area of commercial disease control Tnchodex@ (Makteshum, Israel) has been developed for gray mold (Botrytis) control, and Fusarium prollforatum was recently proposed for downy mildew control (on grapes) Other products have been commerclahzed for the suppression of soilborne pathogens It 1sstriking to review recent developments and realize that a better understanding of disease etiology, together with realization that no product can combat devastating pathogens as a stand-alone treatment, reveal an underlying opportunity for new discoveries m the area of plant pathology. In fact, at a time when many chemicals already suffer loss of performance because of pesticide resistance, blopestlcldes in general, and blofungicides m particular, are becoming recognized tools for reslstance management wtthm IPM systems. Molecular biology has produced many powerful tools for lmprovmg the understanding of pathogen-host recogmtlon and interaction. The resolution has already had a tremendous impact on expression of Bt genes m transgemc plants, offermg a whole new concept m defense against msect pests (66). Slmllarly Impressive is the progress made m an area of plant defense mechanisms and the molecular processesinvolved in defense induction (65). However, methodologles with higher resolutions are still required, to enable a better understandmg of the molecular attributes of microbial fungicldal agents known to date
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These will, in turn, allow for a more focused effort m improving the performance of the products. AQ 10 and Trichodex are two examples of brofungrcides developed in recent years, and mtroduced already as commercial products. In reviewing the status of these examples, together with a whole host of biofungtcides for the control of soilborne pathogens, it is quite obvious that their potential to combat fungal pathogens has not been expressed. Therefore, and primarily as a safety compromise, they are promoted as a component within IPM systems,and are greatly dependent on amendment with chemical fungicides or enhancers. However, once the analytical resolution of dissecting the molecular elements that contribute to the fungicidal activity are revealed, it is presumed that the potential is better utilized. Indeed, recent developments m genetic engineering have already provided significant potential to improve some of the attributes. Future prospects are viewed as two parallel directions of product developments: intensify the expression of active gene products m better hosts, e.g., walldegrading enzymes, such as chitinases and glucanases of bacterial origin expressed m Trichoderma (66), and dissect fungicidal genes and their expression in transgemc plants. The latter approach has already proven extremely fruttful m producing herbicide-resistant or lepidopteran-pest-resistant crops, as mentioned above. It will be possible to achieve similar successeswith respect to fungal disease control, regardless of the direction selected for development, only when there is a better understanding of the molecular basis of disease suppression. As a result of increasing knowledge of the mechamsms of pathogenicity, more progress IS expected to be made m developmg new types of diseaseprotectants, as well as the genetic engineering of resistant plant varieties. The key to progress is the successm extensively interfering with the virulence of the pathogen. Agam, all that IS known to date about the mode of action of AQlO is that it exerts its suppressive effects via hyperparasitism of PMD. We have not been able to determine the molecular cues of host-pathogen recogmnon, let alone the process by which A quzsqualis governs the metabolic function of the pathogen Progress m elucidation of the mode of action will have nnmediate implications on the quality of the biofungicide product. It ~111still remam an overridmg concern of those who translate scientific achievements mto commercial products to ensure that all inherent attributes are expresseddespite hurdles of mass production, and that it is all executed m a cost-effective fashion. References 1 Chet,I. (1987) ZnnovatzveApproaches To Plant Disease Control. Wiley,Toronto,Canada. 2 Papavizas,G. C (1984) Soilborneplant pathogens new opportunities for biological control. Proceedings 1984 Brltlsh Crop Protection Conference-Pests and Diseases,
pp 371-378.
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3. Sundheim, L. and Tronsmo, A. (198X) Hyperparasites in biological control, in Biocontrol qf Plant Diseases (Mukerji, K. G. and Garg, K. L., eds.), CRC, Boca Raton, FL, pp. 53-69. 4. Cook, R. J. (1993) Making greater use of introduced microorganisms for biological control of plant pathogens. Annu. Rev. Phytopathol. 31, 53-80. 5. Cook, R. J. (1993) The role of biological control in pest management in the 21st century, in PestManagement: Biologically BasedTechnologies,vol. 18 (Lumsden, R. D. and Vaughn, J. L., eds.), Beltsville Symposium. American Chemical Society, Washington, DC, pp. l&20. 6. Fokkema, N. J., Gerlagh, M., Kohl, J., Jongebloed, P. H. J., and Kessel, G. J. T. (1994) Prospects for biological control of foliar pathogens, in Proceedings qfthe Brighton Crop Protection Conference: Pests and Diseases,BCPC Publications, Major Print Ltd., Nottingham, UK, pp. 1249-1258. 7. Janisiewics, W. J. (1988) Biological control of diseases of fruit, in Biocontrol qf Plant Diseases,vol. 2 (Mukergi, K. G. and Grag, K. L., eds.), CRC, Boca Raton, FL, pp. 228-235. 8. Wilson, C. L, Wisniewski, M. E., El-Gaouth, A., Droby, S., and Chalutz, E. (1996) Commercialization of Antagonistic yeasts for the biological control of postharvest diseases of fruit and vegetables. J. Ind. Microbial. 46,237-24 1. 9. Cook, R. J., Bruckart, W. L., Coulson, J. R., Goettel, M. S., Humber, R. A., Lumsden, R. D., et al. (1996) Safety of microorganisms intended for pest and plant disease control: a framework for scientific evaluation. Biol. Control 7,333-35 1. 10. Carlton. B. C. (1990) Economic consideration marketing and application of biocontrol agents, in New Directions in Biological Controls-Alternatives ,for SuppressingAgricultural Pestsand Diseases(Baker, R. R. and Dunn, P. E., eds.), Liss, New York, pp. 4 19-434. 11. Bravo, A. (1997) Minireview: phylogenetic relationships of Bacillus thuringiensis b-endotoxin family proteins and their functional domains. J. Bacterial. 179, 2793-280 1. 12. Lumsden, R. D. and Walter, J. F. (1995) Development of the biocontrol fungus gliocladium virens: risk assessment and approval for horticultural use, in Biological Control: BeneJitsand Risks(Hokkanen, M. T. and Lynch, J. M., eds.), Cambridge University Press, Cambridge, UK, pp. 263-269. 13. Lewis, J. A. and Papavizas, G. C. (1987) Application of Trichoderma and Gliocladium in alginate pellets for control of Rhizoctonia damping-off. Plant Pathol. 36,438-446.
14. Baker, R. (1982) Induction of suppressiveness,in SuppressiveSoilsand Plant Disease (Schneider, R. W., ed.), American Phytopathology Society, St. Paul, MN, pp. 35-50. 15. Baker, R. (1983) State of the art: plant diseases, in Proceedingsqf the National Znterdisciplinary Biological Control Conference(Battenfield, S. L., ed.), Cooperative State Reservation Service, U. S. Department of Agriculture, Washington, DC, pp. 14-22. 16. Baker, R. and Scher, F. M. (1987) Enhancing the activity of biological control agents, in Innovative Approaches to Plant DiseaseControl (Chet, I., ed.), Wiley, Toronto, Canada, pp. l-l 7.
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17. Dubos, B. (1987) Fungal antagonism in aerial agrobiocenoses, in/nnovativeApproaches to Plant Disease Control (Chet, I., ed.), Wiley, Toronto, Canada, pp. 107-I 35. 18. Hemming, B. C. and Houghton, J. M. (1993) Influence of biotechnology on biocontrol of take-all disease of wheat, in Biotechnology in Plant Disease Control (Chet, I., ed.), Wiley-L&, New York, pp. 15-38. 19. Wilson, C. L. and Wisniewski, M. E. (1994) Large scale production and pilot testing of biological control agents for postharvest diseases, in Biological Control of Postharvest Disease, Theory and Practice (Chet, I., ed.), CRC, Boca Raton, FL, pp. 89-100. 20. Cate, R. (1990) Biological control of pests and diseases: integrating a diverse heritage, in New Directions in Biological Control: Alternatives for Suppressing Agricultural Pests and Diseases (Baker, R. R. and Dunn, P. E., eds.), Liss, New York, pp. 333-344. 21. Lumsden, R. D. and Lewis, J. M. (1989) Selection, production, formulation, and commercial use of plant disease biocontrol fungi, problems and progress, in Biotechnology of Fungi for Improving Plant Growth (Whips, J. M. and Lumsden, R. D., eds.), Cambridge University Press, Cambridge, UK, pp. 17 l-l 90. 22. El-Ghaouth, A. E., Wilson, C. L., and Wisniewski, M. E. (1995) Sugar analogs as potential fungicides for postharvest pathogens of apple and peach. Plant Dis. 79, 254-258. 23. Fokkema, N. J. (1976) Antagonism between fungal saprophytes and pathogens on aerial plant surfaces, in Microbiology ofAerial Plant Surfaces (Dickinson, E. and Preece, F., eds.), Academic, New York, pp. 487-506. 24. Katan, J. (1985) Solar disinfestation of soils, in Biology and Management of Soilborne Plant Pathogens (Parker, C. A., Rovira, A. D., Moore, K. J., Wong, P. T. W., and Kollmorgen, J. F., eds.), APS, St. Paul, MN, pp. 274-278. 25. Blakeman, J. P. and Fokkema, N. J. (1982) Potential for biological control of plant diseases on the phylloplane. Annu. Rev. Phytopathot. 20, 167-l 92. 26. Olivier, J. M. (1983) Les organismes antagonistes d’agents phytopathogenes, in Faune et Flore Auxiliaires en Agriculture. ACTA, Paris, pp. 145-164. 27. Chet, I. and Baker, R. (1981) Isolation and biocontrol potential of Trichoderma hamatum from soil naturally suppressive of Rhizoctonia solani. Phytopathology 71,286-290. 28. Falk, S. P., Gadoury, D. M., Cortesi, P., Pearson, R. C., and Seem, R. C. (1995) Parasitism of uncinula necator Cleistothecia by the mycoparasite Ampelomyces
quisqualis. Phytopathology
85, 794-800.
29. Galper, S., Sztejnberg, A., and Lisker, N. (1985) Scanning electron microscopy of the ontogeny ofAmpelomyces quisqualis pycnidia. Can. J. Microbial. 31,961-964. 30. Taber, R. A., Smith, D. H., Petit, R. F., and Johnson, J. D. (198 1) Potential for biological control of Fulvia,fulvum by Hansfordia in Texas. Phytopathology 71, 908-912. 3 1. Falk, S. P., Gadoury, D. M., Pearson, R. C., and Seem, R. C. (1995) Partial control of grape powdery mildew by the mycroparasite Ampelomyces quisqualis. Plant
Dis. 79,483-490.
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32. O’Neill, T. M., NIV, A , Elad, Y., and Shttenberg, D (1996) Btological control of Botrytzs cznerea on tomato stem wounds with Trtchoderma harztanum in Israel Eur J Plant Path01 102,6355643 33 Jackson, M and Schtsler, D. H. (1992) The composition and attrtbutes of Colletotrzchum truncatum spores are altered by the mutational envtronment Appl Envtron Mtcrobtol. 58,2260-2265. 34 Phthpp, W D and Cruger, G. (1979) Parasitismus von Ampelomyces qutsqualzs auf Echlen Mchltauptlzen an Gurken und andern Gemtisearten 2 PfZanzenkr Pflanzenschutz 86, 129-142 35. Engelkes, C. A , Nuclo, R L , and Fravel, D. R. (1997) In effect of carbon, mtrogen, and C N ratto on growth, sporulatton, and btocontrol efficacy of Talaromyces jlavus Phytopathology 87,500-508 36 Hofstem, R and Fridlender, B (1994) Development of production, dehvery, formulation and dehvery systems for biohnrgtcides, m Brtghton Crop Protectron Conference Pests and Dueases, BCPC Publications, Major Print Ltd , Nottmgham, UK, pp 1273-l 280. 37 Abu-Foul, S , Raskm, V. I , Sztejnberg, A , and Marder, J B (1996) Disruption of chlorophyll organization and function m powdery mildew dtseased cucumber leaves and its control by the hyperparasite Ampelomyces quzsqualts Phytopathology 86, 195-l 99 38 SzteJnberg, A , Galper, S., Mazar, S , and Ltsker, N (1989) Ampelomyces quzsqualzs for biologtcal and integrated control of powdery mildew m Israel J Phytopathol. 124,285-295 39 Zimand, G , Elad, Y , and Chet, I. (1996) Effect of Trrchoderma harzranum on Botrytts ctnerea pathogenictty Phytopathology 86, 1255-1260 40 Sutton, J C , LI, D., Pang, G , Yu, H., Zhang, P , and Valdebemto-Sanhueza, R M. (1997) Gltocladtum roseum. a versattle adversary of Botrytts cwerea m crops Plant Dts 81,3 16-328 41 Wtlson, C L and Wtsmewskt, M E., eds (1994) Bzologzcal Control OfPostharvest Dtsease of Frutts and Vegetables-Theory and Practtces CRC, Boca Raton, FL 42 Jamsiewicz, W J , Usall, J , and Bors, B (1992) Nutrittonal enhancement of btocontrol of blue mold on apples Phytopathology 82, 1364-l 370. 43 Elad, Y , Zimand, G , Zaqs, Y , Zuriel, S , and Chet, I (1993) Use of Trtchoderma harztanum in combmatton or condmons alternation wtth fungictdes to control cucumber gray mold (Botrytzs cznerea) under commercial greenhouse condittons Plant Pathol. 42,324332 44 Elad, Y., Shtienberg, D., and Niv, A. (1994) Trichderma hrzzanum T39 integrated with fungicides: improved btocontrol of gray mold, m Brighton Crop Protectton Conference Pests and Dweases, BCPC Publications, MaJor Print Ltd , Nottingham, UK,pp 1109-1114 45 Daoust, R A and Hofstein, R (1996) Ampelomyces quzsqualts, a new biofungicide to control powdery mildew m grapes, m Brtghton Crop Protectton Conference Pests and Diseases, BCPC Publications, MaJor Print Ltd , Nottingham, UK, pp 33-40.
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46 Lmdow, S. E., McGourty, G., and Elkms, R (1996) InteractIons of antlblotlcs with Pseudomonasfluorescens strain a506 m the control of fire bhght and frost mJury to pear. Phytopathology 86, 841-848. 47 Federal register EPA (1989) Data Requirements for Pesticide Registration, Final Rule. 53, 15,952-l 5,999. 48 Federal register, EPA ( 1995) Candzda oleophlla Isolate I- 182 (ASPIRE) Exemptlon from the Requn-ement of a Tolerance. 60, 11,032-l 1,033. 49. Katz, M (1997) Powdery mildew. biological enhances growers’ options. Grape Grower
29,4-7
50 Cavanaugh, P (1997) New blofunglclde reduces resistance, late sulfur. Am. Vzneyard 6,3-5
5 1 Hudson, R A (1997) Compatibility of Ampelomyces quxqulzs spores with commercial chemical products for use in IPM programs Phytopathology 87, S45. 52 Sundhelm, L and Kreklmg, T (1982) Host-parasitic relationships of the hyperparasite Ampelomyces quzsqualts and Its powdery mildew host Sphaerothzca fullgznea Phytopathology 104,202-2 10 53 Jarvls, W. R. and Klmsby, K. (1977) The control of powdery mildew of greenhouse cucumber by water sprays and Ampelomyces qulsqualzs Plant Du Rep 61,728-730
54 SzteJnberg, A , Galper, G., and Lisker, N (1990) Condltlons for pycmdlal production and spore formation by AmpelomycesquzsqualzsCan J Mcroblol 36, 193-198 55 Falk, S. P , Pearson, R C , Gadoury, D. M , Seem, R C , and SzteJnberg, A (1996) Fusarlumprollferatum as a blocontrol agent against grape downy mildew Phytopathology 86, 101&1017 56 Droby, S , Chalutz, E , Wlsmewskl, M E , and Wilson, C E (1996) Host response to mtroductlon of antagonistic yeasts used for control of postharvest decay, m Mzcroblology ofAerza1 Plant Surfaces (Moms, C E , Nlcot, P , and Nguyen-The, eds ), Phytopathology Press, St Paul, MN 57 Wilson, C L , El-Ghaouth, A E., Chalutz, E., Droby, S., Stevens, C , Lu, J Y , Khan, V , and Arul, J (1994) Potential of induced resistance to control postharvest diseases of fruits and vegetables Plant Du 78, 837-844 58. Chapple, A C , Downer, R. A, and Hall, F R (1993) The effect of spray adJuvants on swath patterns and droplet spectra for a flat-fan hydraulic nozzle. Crop Protection 12,579-590
59. Chapple, A. C. and Bateman, R. P (1997) Application systems for mlcroblal pesticides. necessity not novelty, m Brztzsh Crop Protection Councd Symposium Mzcrobzal ZnsectzczdesNovelty or Necesszty?(Evans, H F , ed ), BCPC Publlcatlons, Major Print Ltd , Nottingham, UK, pp 18 l-l 90. 60 Phlllpp, W D , Beuther, E , Hermann, D , Klmkert, E , Oberwalder, C , and Schmldke, M (1990) Formulation of the powdery mildew hyperparaslte Ampelomyces qulsqualzs J Plant Dls Protectzon 97, 120-132 61 Gubler, W. D., Thomas, C. S., Weber, E., Luvisl, D., Leavitt, G , and Smith, R. (1997) Use of a weather station based disease risk assessment for control of grapevine powdery mildew m California Phytopathology 87, S36
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62 Whtpps, J. M (1992) Status of biologtcal disease control Hortudtural Blocontr-ol Scz Technol. 2,3-24. 63 Lumsden, R D , Lewis, J A , and Fravel, D R (1995) Formulation and deltvery of btocontrol agents for use against sotlborne plant pathogens, m Bloratlonal Pest Control Agents Formulattolz and Delwery (Hall, F R. and Barry, S , eds ), Symposium Series, American Chemtcal Society, Washmgton, DC, pp 16&l 82 64 Perlak, F J , Deaton, R W , Aremstrong, T A, Fuchs, R L , Sums, S R , Greenplate, J T., and Ftschhoff, D A (1990) Insect reststant cotton plants Brotechnology 8,939-943 65 Broghe, K., Broghe, R , Benhamou, N , and Chet, I (1994) The role of cell wall degrading enzymes m fimgal dtsease reststance, m Biotechnology In Plant Dzsease Control (Chet, I , ed ), Wiley-Ltss, New York, pp 139-156 66 Chet, I , Barak, Z , and Oppenhetm, A (1994) Genetic engmeermg of mtcroorgamsms for improved biocontrol acttvrty, in Bzotechnology zn Plant Disease Control (Chet, I , ed ), Wtley-Lrss, New York, pp 21 l-235
Biological
Control of Seedling Diseases
K. Prakesh Hebbar and Robert D. Lumsden 1. Introduction Seedlmgs of economically important crop plants are attacked by various soilborne pathogenic fungi, such as Pythium, Fusanum, Rhlzoctorua, Phytopthora, and others, which cause either seed rot before germmation or seedling rot after germmation, resultmg m billions of dollars m cumulative crop losses. These diseases are often termed pre- and postemergence damping-off, or seedlmg blights Greenhouse crops grown in soilless cultures, as well as field crops, are susceptible to soilborne fungal pathogens, resulting m considerable economic losses.Currently, the most widely used control measure for suppressing soilborne diseases IS the use of environmentally hazardous fungicidal treatment of seed, seedlings, or soils. However, problems encountered, such as development of pathogen resistance to fungicides, mabillty of seed-treated fungicides to protect the roots of mature plants, rapid degradation of the chemicals, and a requirement for repeated applications, have given impetus to alternative remedies (2). One approach to address this problem is to use naturally occurrmg and environmentally safe biological control microorganisms, used alone or m conluncnon with integrated pest management (IPM) strategies (2). Several biological control agents have been commercialized or have been registered for commercial field trials (3) However, a major problem encountered m the area of biological control is the mconsistencies m performance of biocontrol products (4). According to Bowen and Rovtra (5), rapid migration to newly formed root surfaces from the point of inoculation, as well as rapid growth rates, can also be helpful in improvmg the performance of biocontrol agents Suslow and Schroth (6) have reported, m a dose response study, that the mmtmum number of viable cells needed for uniform colonization and plant growth promotion m From Methods m Biotechnology, vol 5 Blopestmdes Use and Debvery Edtted by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
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sugarbeets with Pseudomonasfluorescens was IO5 bacteria/seed or 10’ bacteria/g dry wt moculum. Failure m moculum trials may be caused by selection of moculants that do not have some of the above charactertstics (7). This may also be caused by factors such as lack of knowledge related to the ecology of btocontrol agents, poor sot1colomzatton and persistence, and limited dehvery technology currently available. The obJeCtiVe of this chapter is to describe the successful discovery and commercial development of two btological control agents: a bacterium, Burkholderra cepacla; and a fungus, Ghocladium wrens. 2. Examples of Biological Control Agents Examples of bacteria that are currently commercially available are Gramnegative B cepacza (Deny TM, CCT, Carlsbad, CA), and Agrobacterlum radzobacter (Nogall TM, Bro Care Technology, Australia) and Gram-positive Baczllus subtzlzs (Kodiak HBTM and EptcTM, Gustafson) and Streptomyces gnseovwcd~s (Mycostop TM,Kemira OY, Finland). The fungal btocontrol products available commercially are Glzocladzum wrens (SoilGardTM, ThermoTrilogy, Columbia, MD) and Trichoderma harzranum (T22TM and Root ShteldTM, Bioworks, Geneva, NY). Most of the above mentioned products are effective m controlled envtronments, such as greenhouses, but only a few of these products have been used extensively for biologtcal suppression of fungal diseases m major fruit (Nogall) and field crops (Kodiak) (3). This chapter wtll discuss the discovery and development of two biocontrol agents: a bacterium, B cepacla, and a fungus, G wrens. 2.7. Burkholderia 2 1.1. Ecology
cepacia
Studies of corn monoculture soils in the midwestern United States(8) and m France (9) showed that high populations of B. cepacza (syn Pseudomonas cepacza) (IO), a ubiquitous sot1bactermm, were associatedwith the rhizosphere and roots of corn, In addition, successive corn culttvation increased populations of B. cepacla (9). The rhizosphere/nonrhizosphere (R/S) population ratio was 4000, indicatmg its affimty for corn roots. When applied as seed moculants, B cepacza strains isolated from corn colomzed the rhizosphere and roots of corn extensively, with seed moculum levels as low as 10 bacteria/seed Within 2 wk, populattons proliferated to 10’ colony formmg units (CFU)/g dry wt of root (II). B. cepacza 1s also an efficient colonizer of roots and rhizosphere of radish (12), pea (231, sunflower (14), and soybean (IS). Although B cepacia has been described as a phytopathogen causing sour skm of onion bulbs (16), and also as a secondary pathogen m humans with cystic fibrosis (27), strains isolated from the rhtzosphere of corn do not cause necrosis of onion tissue (18), and are quite different from the chmcal strains (19).
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2.1.2. Mode of Action B. cepacia strains isolated from the rhizosphere of corn have a broad-spectrum antifungal activity against a range of fungal pathogens (18). Pyrrolnitrin has been reported as the major metabolite responsible for the broad-spectrum antifungal activity of B cepacia (5,12,20). On the contrary, the reference strain ATCC 254 16, an onion pathogen, does not produce pyrrolmtrm (21) Recent reports indicate that, in addition to pyrrolnitrin, B. cepacia produces antifungal compounds such as siderophores (22-24) and chlorinated phenylpyrrole antibiotics (29, as well as the hydrolytic enzyme P-1,3-glucanase (26).
2.1.3. Biological Control Numerous reports now exist on the isolation and utilization of B cepacza for biological control of vartous sorlbome fungal pathogens in different crops (22,24,18, 21,23,27-31) In growth chamber studies, Hebbar et al. (28) determmed that the majority of sot1strains of B. cepacia were unable to suppressearly corn seedling infection by Fusarium moniliforme, but those isolated from corn roots could do so. Isolates of B cepacaa from lettuce roots, when used as seed treatments,reduced radish seeddamping-off causedby Rhizoctonia solam AG4 by 50% (12). Although B. cepacia ISeffective againsta wide range of soil pathogens,its success asa seedtreatment is determmed by various factors, such astotal number of bacteria addedto coat the seeds,soil temperature,and, in somecases,the plant cultivar used. In greenhousestudies,the optimum concentration of B. cepacia necessaryto reduce seedlingdamping-off in corn causedby acombmation of three pathogens(Fusanum graminearum, Pythium ultimum, andPythium arrhenomanes), was determmed to be 1OSCFU/seed(30). In the samestudy,the optimum temperature(25°C) for B. cepacia to be effective was higher than that (18’C) for the fungal biocontrol agent G. virens. Kmg and Parke(28) determined that, although the efficacy of B. cepacza to suppress Aphanomyces eutezches root rot andPythium damping-off m peaswas not limited to a single cultivar, the differential effects of biocontrol were related to the degree of suscepttbthtyto the pathogen of eachof the four cultivars tested. Although B. cepacia is consideredas a biocontrol agent with potential for largescaleapplication, there is only one commercial product available, marketed by CCT under the trade nameDeny. Recently,promising resultswere obtained (32) m extensive field trials conductedby Agrium (Saskatoon,Canada)to evaluate, the feasibility of using B. cepacia strain Ral-3 for biological control and growth enhancementof conifer seedlings. 2.2. Gliocladium 2.2.1. Eco/ogy
virens
The fungus G. wrens Miller, Giddens, and Foster (=Trichoderma wrens, Miller, Giddens, Foster, and von Ark) was originally isolated from a sclero-
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tmm of the plant pathogemc fungus Sclerotinza manor burled and recovered from a Beltsville, MD, soil G vzrens 1snative to all parts of the United States and 1swidely distributed throughout the world (33,341. G vzrens is a hyphomycete with no confirmed sexual stage The possible sexual stage is Hypocrea gelatznosa (33,35). It proliferates as asexual conidta that are held m masses of moist spores. It survives as vegetative segments of the mycehum, termed chlamydospores, usually embedded m organic matter. The spores are not airborne and are dispersed only as spore suspensions m water, or carried m sot1 or m organic debris Recently, molecular evidence Indicated that G vzrens is more closely related to Trzchoderma than to the type spectes of the genus Glzocladzum. This supports suggestions to refer to the fungus as T wrens, rather than G wrens (35). Because of the prevalence m the literature for the established name, G wrens, the authors prefer to use this name. However, the probable relationship to Trzchoderma 1srecognized. 2.2.2.
Mode of Action
G wrens is a common sot1 saprophyte, and, as with many other sotlborne fungi, produces several antibiotic metabolites (36-41) that are thought to enhance tts soil competittveness The metabohte most likely associated with control of Pythium and Rhtzoctonia damping-off is gltotoxm, an eptpolythiopiperazine-3,6-dione antibiotic (36,40,42, 42a). Ghotoxm has antibacterial, antifungal, antiviral, and antttumor activity It also interferes with phagocytic cells, and is unmunosuppressive (41). Smce gliotoxin has moderate mammahan (rats) toxtctty (50 mg/kg) (41), mgestion directly by an animal or human 1sof some concern. However, thorough evaluatton of formulattons indicated only traces of gltotoxin m the product (43), and the formulation is not toxic to rats (44). Consequently, the wheat-bran-based product would not be harmful tf ingested. Moreover, gltotoxm 1sproduced after mcorporation of the granular product mto the soil, remains active for a short period of ttme, and is inactivated (Lumsden, unpublished results). A defimttve role for ghotoxm mvolvement m the mechanism of antagomsm is supported by recent mutattonal analysts studies of G wrens (G-20 = GL-21) (45). In that case, at least for action of Gl-21 against P ultimum, about 60% of the biocontrol efficacy of the wild-type strain was lost when strains were mutated to no longer produce glrotoxm. The remammg bto-control effecttveness might realisttcally be attributed to competition of G wrens with P ultimum for nutrients. Conversely, other mutational analysis evtdence, m the case of R. solani, suggests that competition for nutrients might account for a greater effect on achieving biocontrol than production of antibiotic metabohtes (46)
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2.2.3. BiologIcal Control Several reports have been published on btologlcal control of a wade range of sotlborne fungal pathogens by G vzrens under both field and greenhouse condmons. Recently, the development of G vzrens for damping-off disease control m greenhouse applications was described (47). The commercial development of G vzrens as a granular formulatron, wrth the trade name SotlGard, was accompltshed by a process that included drscovery of the btocontrol fungus, product development, marketing assessment, product formulattons, process development, extensive efficacy assays, regtstratton wtth the U. S. Environmental Protection Agency (EPA), scale up, and test marketing. The biologtcal control properties of the fungus, G vixens, were aimed at controllmg damping-off diseases of seedlings caused by P ultlmum and R soianl m greenhouse production of seedlings and bedding plants (47). The biological control efficacy of G vzren~ was tested extensively and determmed to be consistent and reliable when used as prescribed for control of damping-off m greenhouse apphcattons (2,43,47-49) Also, G. vzrens reduced disease caused by R solanl on potato (SO) and ornamental crops (48,49) In field trials, appltcatton of G vzrens reduced the mctdence of southern blight caused by Sclerotzum rolfszi in carrots and tomatoes, and increased yield (51). Preliminary results have shown that seed treatment with G virens reduced damping-off in corn caused by a combinatton of P. ultimum, P. arrhenomones, and F gramznearum both in greenhouse (30) and field trials (W. Mao, personal communication). 3. Production and Application of Biocontrol Agents Certain crtterta were considered important in the early stages of development of G. vzrens and B cepaczaas brocontrol agents (4,s). For G vzrens, thts mcluded a bioassay method for selectmg the best strain of G wrens, which also considered: the use of a commercially available soilless medium, used m commercral glasshouses where the disease problems (damping-off) occur; the study of appropriate pathogens, such as P u&mum and R. solam, which are important in greenhouse operations in which the use of a btologrcal control agent would probably be most successful because of fairly uniform culture condrttons; selection of indigenous microorganisms to the United States, because nomndrgenous mlcroorgamsms might be conceived as more likely problems for the United Statesenvironment; the potential for the use of a single isolate of a btocontrol agent for control of both pathogens would be preferred over a mixture of isolates; and the utilizatron of high-value crops, important m the ornamental productton industry to defray the cost of development and registration Similarly, the above logic was also used m the development of B. cepaczaas a btocontrol agent. However, the crop was a field crop, corn, and
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the targeted pathogens were Pythzum and Fusarium spp (8,11,28). On the basis of these factors, it would make the process for registration and commerciahzation of an agent for control of plant diseaseseasier. 3.7. Liquid Fermentation Major advances have been made m the production of biocontrol agents using hqutd fermentatton (52). The strategy used for large-scale production of Grampositive bacterial agents (Baczllus spp) has been to obtain heat- and desiccation-resistant endospores of bacteria or chlamydospores of fungi. Large-scale production of the resistant chlamydospores of fungal antagonists, such as Trzchoderma and Glzocladzum spp are now possible using llqutd fermentation (53). Although large-scaleproduction of Gram-negative bacterial agents(B. cepacla and P f2uorescen.s) is feasible, a major problem is encountered because of then sensitivity to desiccation. This constraint greatly affects the next step, which IS the delivery and application technology 3.2. Formulation
Development
Upon selection of an antagonist of choice, an appropriate formulation of the biocontrol agent for ease of preparation, application, and maximum efficacy should be chosen. Formulation is a key to product success, because it can determine success of delivery, shelf life, and stability of its effectiveness against plant pathogens. The first formulation for G wrens was based on alginate-wheat-bran granules (prill) (7,54), and was called GlioGardTM. Later in product development, certain quality control problems were encountered m the scale-up process. Difficulty was encountered because of the holding times for biomass, and for drying the alginate prill preparations m large volumes. For this reason, and because of an increase m the cost of alginate, the formulation was modified by including dextrm as a binder, reducing the algmate content, and preparing the biomass mixture by a fluid-bed granulation method. These changes did not affect the shelf life and efficacy characteristics, and thus were adopted for a modified product, SoilGard (47). Quality control 1sessential for formulatton development. A simple, but welldefined quality-control program should be m place for comparison of different formulations, and should examine, among other factors, viabihty, stability, and efficacy (43). If a quality control program is not m place during formulation research, product development can be severely delayed, which will ulttmately impact profitability. Quahty control is also extremely important during commercial productton of biocontrol agents (43). With favorable results obtained m detailed efficacy trials (49), additional trials were expanded to include several other cooperators, to ensure that results could be replicated (43). When similar results were obtained, trials were con-
Biological Control of Seedling Diseases
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ducted with several bedding-plant grower cooperators using different protocols (43). With the exception of artrficral mfestatron with pathogens, whrch was used in the earlier trials, researchers were at liberty to use whatever plants they desired, and their own apphcatton schedules. The design of the trials in step arrangement allowed for less control m the way the product was handled with each phase of testing. By the time commercral growers were included m the trials, natural mfestatron was used to determine efficacy, and the grower was srmply given the product with a basic set of mstructrons, srmilar to those now provided on the product label. So far, other than a liquid-based or peatbased formulatron, further progress has not been achieved m formulatmg B cepacia strains (G. Growell, CCT, personal commumcation). 3.3. Application
of Biocontrol
Agents
The most commonly used methods for delivermg btologrcal control agents, especrally under controlled greenhouse conditions, are soil amendments usmg granulated formulations (SorlGard) or drenching with liquid formulations (Deny). Seed applications of dry formulatron have been successfully used for field crops such as cotton and peanuts (Bacillus spp, Kodiak). Seed apphcatron of G vzren~IS currently bemg investigated in the Btocontrol of Plant Diseases Laboratory (US Department of Agriculture, Agrrcultural Research Service). Preliminary results have shown that seed treatments with dry fungal biomass rich m chlamydospores are equal to, or better than, fungrctdes m reducing damping-off m corn (30). However, delivery of Gram-negative bacterial agents as seed treatments for field crops is still a major problem. Brocontrol agents, such as P.fluorescens or B. cepacia, coated on the seeds,have a short shelf hfe (at room temperature), and are readily killed by desiccation. Unless methods are found for their delivery as seed apphcattons, then large scale use may not be feasible However, liquid formulattons (Deny) are bemg tried usmg drip nrtgatton for a few high-value crops, such as strawberry and melons. 3.4. Registration
of Biocontrol
Agents, G. virens as Example
Regrstratron of G virens with the EPA was mtttated by W. R. Grace (now Therm0 Trilogy, Columbia, MD) (44). The EPA reviews applications and regulates mrcroorganisms used as biocontrol agents if they are genettcally engineered, nonmdtgenous to the United States, or if they will be field-tested on more than 10 acres (4.05 ha) of land or 1 acre surface of water (0.41 ha) (55). Subdivision M of the EPA Pesticide Testing Gurdelmes (56) treats mrcrobial agents for the control of plant pests in ways similar to those for chemical pesticides. Companies applying for registration must provide extensive mformation for approval for commercial use of microbial pesticide products. Product testing 1sset up in a tier systemthat recogmzesthe mherent rusksand degrees
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of exposure associatedwith different usesof pesticides In addition to production and taxonomrc data, long- and short-term effects on a variety of orgamsms,mcludmg plants, ammals, and other nontarget organisms, may be necessary. Three formulattons of G wrens (Gl-2 1) were approved by the EPA WRCGL-2 1, a manufacturmg-use product (fungal biomass), can be used m formulations of btocontrol products. WRC-AP- 1 (GhoGard) is an end-use formulated prtlled product containing calcmm algmate, wheat bran, and proprietary additives to prolong shelf life. The prtlls or granular material is mixed with sot1or soilless plant growmg media at least 1 d prior to planting, or incorporated mto the medium surface m plant beds prior to, or at, planting. The formulation 1s used at the rate of l-l 5 lb/yd3 (approx 1 g/L) of media when mixed, or at the rate of 0.75-l ounce/sq ft when applied to the bed surface. WRC-AP-2 (SoilGard) is an improved granulated product, with somewhat improved efficacy, and which is more economical to manufacture. GhoGard is no longer being produced, and is replaced on the market with SoilGard (47). 3.5. Compatibility of Biological Agents with Chemical Pesticides and Other /PM Strategies Recently, one of the major endeavors to improve the efficacy of btologtcal control agents, has been to use them m an IPM strategy, such as sot1solarizatton (57,58), or by using btocontrol agents resistant or tolerant to chemical pesticides (59,60) Initial results from field trials to evaluate suppression of the southern blight pathogen, S ~olfszz,m bell pepper, mdtcated that the biocontrol fungus, G wrens, was sensitive to so11solarizatton, and therefore could not be used m this combmatton. In contrast, the temperature tolerant biocontrol fungus Tularomycesflavus has been used successfully m combmatton with soil solarizatton (58). Soil solartzation, followed by the application of btocontrol agents, may improve disease suppresstveness. Seedling bioassays with corn indtcated that the btocontrol bactermm, B cepacia, could be used m combination with chemical pesticides to improve seedling emergence (9). Seedling vigor was better, when corn seedswere treated with thtram fungicide m combtnation with a peat-based formulation of B cepacia, than when either treatment was used alone. Btological agents, espectally those that are root-assoctated microorgamsms, may perform better than chemtcal or physical treatments of the soil. This ts because of then ability to colomze root tissue and have an effect on the deeper layers of the so11profile. In addmon, fungicides can protect plant seedlmgs only for a short duration, and the effect of soil solartzatton 1slimited in the upper few centimeters of the solI. Although chemical fungtctdes or soil solartzatlon has been shown to be effictent m suppressmg dampmg-off diseases on then own, there is a defimte advantage m combmmg these strategies with btocontrol agents.
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4. Current Status and Future Prospects Despite problems associated with the shelf life and delivery of blological agents, progress has been encouraging in terms of their acceptance as alternatives to chemical seed treatments when used alone or in conjunction with chemicals m an IPM strategy Currently, these questions are being asked. Can pathogens develop resistance to biocontrol agents; can their effectiveness be improved by combmmg two or more biological agents; will their effectiveness be restrlcted to certain kinds of environments; and 1sblologlcal control economically feasible? Commercialization of biocontrol agents 1sdependent on marketing assessment and determination of market availability and profit margins. Several factors should be considered, including the patentability of the formulation or strain of the blocontrol agent; the need m agricultural production systems for safe, reliable, nonchemical treatments for controlling plant diseases; the requirement for simple, mexpenslve fermentation systemsto produce biomass of blocontrol agents m large commercial scale fermenters; and the ability of biological pest control agents to be generally less damaging to the envlronment, and cheaper to develop, register, and market than chemical control compounds. Considering all of these factors, biological control products are begmmng to be recognized as commercially feasible for agricultural markets, and for plant protection strategies in general. The commerclahzation of the two blologlcal products mentioned in this chapter (Deny and SollGard) are good examples of how successful blologlcal control projects can matenahze, if a logical step by step approach, from the mltlal discovery, and ecological study, to the final development, 1sused. Also, close cooperative work between pnvate companies and public research institutions facilitates development of new and mnovatlve btocontrol products. 5. Note Mention of a trademark or proprietary product does not constitute a guarantee or warranty of the product by the USDA, and does not imply approval to the exclusion of other products that may also be suitable. References 1. Cook, R J. and Baker, K. F (1983) Nature and Practzce of Bzologzcal Control of Plant Pathogens APS, St.Paul, MN. 2 Lumsden, R D and Locke, J C ( 1989) Blologlcal control of damping-off caused by Pythum ultlmum and Rhuoctonza solam with Glzocladzum wrens m soilless mix Phytopathology 79,361-366 3. Lumsden, R. D., Lewis, J. A., and Fravel, D. R. (1995) Formulation and delivery of blocontrol agents for use against soilborne plant pathogens, m Bloratlonal Pest
712
4
5 6 7 8
9
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13 14. 15
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Control Agents (Hall, F R. and Barry, J. W , eds ), American Chemtcal Society, Washmgton, DC, pp. 16&l 82 Lumsden, R D and Lewis, J A. (1989) Selection, productton, formulation and commerctal use of plant disease biocontrol fungi, problems and progress, m Btotechnology ofFungifir Improvtng Plant Growth (Whtpps, J. M. and Lumsden, R. D , eds ), Cambridge University Press, Cambridge, UK, pp 17 I-l 90 Bowen, G D and Rovira, A D (1976) Mtcrobtal colonization of plant roots Annu Rev Phytopathol 14, 121-144 Suslow, T V and Schroth, M N (1982) Rhrzoctoma of sugar beet effects of seed apphcatlons and root colomzatton on yield Phytopathology 72, 199-206 Kloepper, J W., Ltfshttz, R., and Zablotowtcz, R. M (1989) Free-living bacterial mocula for enhancing crop producttvtty Trends Btotechnol 7,3944 Hebbar, K P., Davey, A G , and Dart, P J ( 1992) Rhtzobacterra of corn antagonistic to Fusartum montforme, a sotlbome fungal pathogen tsolatton and tdenttfication Sod Btol Btochem 24, 978-987. Hebbar, K P , Martel, M. H., and Heulm, T (1994) Burkholderta cepacta, a plant growth promotmg rhrzobacterial assoctate of corn, in Improvtng Plant Producttvzty wzth Rhzzosphere Bacterza (Ryder, M H., Stephens, P M , and Bowen, G D , eds.), Proceedzngs, Thud International Workshop on Plant Growth Promoting Rhtzobacterta, Adelaide, Austraha, pp 201-203 Yaabucht, E , Kosako, Y., Oyalzu, H , Yano, I , Hotta, H , Hastmoto, Y , Ezakt, T , and Arakawa, M. (1992) Proposal of Burkholdena gen Nov and transfer of seven species of the genus Pseudomonas homology Group II to a new genus, wtth type species Burkholderza cepacra (Pallerom and Holmes, 1981) comb Nov Mtcrobtol Immunol 34, 125 1-l 275 Hebbar, K P , Davey, A. G., Merrm, J , McLaughlin, T. J., and Dart, P J (1992) Pseudomonas cepacta, a potenttal suppressor of corn sotlborne diseases Seed moculatton and corn root colomzatton Sod B1o1 Biochem 24, 999-l 007 Homma, Y , Sata, Z , Htrayama, F , Konna, K , Shnahama, H., and Suzuki, T. (1989) Productton of anttbtotrcs by Pseudomonas cepacra as an agent for biological control of sotlbome plant pathogens. So11Btol Btochem 21, 723-728 Parke, J. L. (1990) Population dynamics of Pseudomonas cepacta m the pea spermosphere m relation to blocontrol of Pythzum Phytopathology 80, 1307-l 3 11 Hebbar, K P , Berge, O., Heulm, T , and Smgh, S P (199 1) Bacterial antagonists of sunflower (Helzanthus annuus L) Fungal pathogens Plant Sod 133, 13 l-140 Hebbar, K P , Hackett, J. D , Fravel, D R , and Lumsden, R D (1995) Assoctatton of Burkholderta cepacta and Pseudomonas with corn and soybean roots and their role m suppressmg pre-emergence damping-off of soybean Abs Phytopath01 85, 1136 Burkholder, W H (1950) Sour skin, a bacterial rot of onion bulbs Phytopathology40,115-117 Lessee, T. G , Hendrtckson, W., Manning, B D , and Devereux, R (1996) Genomtc complextty and plasttcrty of Burkholderta cepacta FEMS Mcrobtol Lett 144, 117-128
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18 Hebbar, K. P , Atkinson, D., Tucker, W , and Dart, P J (1992) Suppression of Fusarcum monrlrforme by corn root-associated Pseudomonas cepacla SolI Blol Bzochem 24, 1009-l 020 19. G~lhs, M., Van, V T., Bardm, R., Goor, M., Hebbar, P., Wrllems, A , et al. (1995) Polyphastc taxonomy m the genus Burkholderza leadmg to an emended descriptron of the genus and proposition of Burkholderza vletnamlensls sp Nov. for N2-fixing isolates from rice m Vietnam Int J Systematzc Bacterial 45,274-289 20 Jamsiewrcz, W J and Roitman, J (1988) Biological control of blue mold and grey mold on apple and pear with Pseudomonas cepacla Phytopathology 78, 1697-1700 21. Homma, Y., Chtkuo, Y , and Ogoshl, A (1990) Mode of suppression of sugar beet damping-off caused by Rhlzoctonla solam and Aphanomyces cochllodes by seed bactertzatton with Pseudomonas cepacla, in Plant Growth Promoting Rhczobacterza-Progress and Prospects (Keel, C., Koller, B , and Defago, G , eds ), Proceedzngs, Second Internattonal Workshop on Plant Growth Promoting Rhtzobacteria, Interlaken, Switzerland, pp. 115-l 18. 22. Barelmann I , Meyer, J M , Tarez, K., and Budztktewtez, H (1996) Cepaciachelm, a new catecholate siderophore from Burkhoiderla (Pseudomonas) cepacla. Z Naturforschung
51,627-630
23 Smirnov, V V , Kiprianova, E. A , Gargulya, A D , Dodatko, T A , and Ptlyaschenko, I I (1990) Anttbtotic activity and siderophores of Pseudomonas cepacla Appl Blochem and Mxroblol
26, 5843.
24 Meyer, J. M , Hohnadel, D., and Halle, F (1989) Cepabactm from Pseudomonas cepacla, a new type of siderophore J Gen Mlcroblol 135, 1479-1487. 25 Rottman, J N , Mahoney, N E., Janistewtcz, W J., and Benson, M (1990) A new chlormated phenyl pyrrole antrbiotic produced by antifungal bacterium Pseudomonas cepacla J Agrlc
Food Chem 38,538-541.
26 Fravel, D R , Marois, J. J , Lumsden, R D., and Conmck, W J , Jr (1985) Encapsulation of potential btocontrol agents m an algmate-clay matrix Phytopathology 75,774-777 27. Cartwrtght, K. D and Benson, D M (1995) Optimization of biological control of Rhizoctoma stem rot of Pomsetta by Paecllomyces ldaclnus and Pseudomans cepacla. Plant Dzs 79, 30 l-308 28 King, E B and Parke, J. L (1993) Btocontrol of Aphanomyces loot rot and Pythzum damping-off by Pseudomonas cepacza. Plant Dls 77, 1185-l 188 29 Lumsden, R. D , Garcia, E R., Lewis, J A., and Frtas, T G. A (1987) Suppression of damping-off caused by Pythzum spp m soil from the indigenous Mexican Chmampa agricultural system. Soul Bzol. Blochem 19, 50 l-508 30. McLaughlin, T. J , Quinn, J P., Betterman, A., and Bookland, R. (1992) Pseudomonascepacla suppression of sunflower wilt fungus and role of antifungal compounds m controlling dtsease. Appl Envzron. Mlcroblol 58, 1760-l 763 3 1, Renato-de-Frettas, J and Germida, J. J. (1991) Pseudomonas cepacla and Pseudomonasputlda as winter wheat inoculants for btocontrol of Rhzzoctonla solam Can J Mlcroblol 37,780-784.
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32 Reddy, M S., Funk, L M , He, D N , and Pedersen, E A (1996) Status on commerclal development of Burkholderla cepacza for bIologIca control of fungal pathogens and growth enhancement of comfer seedlings for a global market, m Advances zn Bzologzcal Control of Plant Diseases (Whehhua, T , Cook, R J , and Rovira, A., eds ), Proceedings, International Workshop on BIological Control of Plant Diseases, BelJmg, May 22-27 33 Domsch, K H , Cams, W , and Anderson, T (1980) Cornpendzum of Sozl Fungi, vol 1 Academic, London 34. Farr, D F , Bills, G F , Charnuns, G P , and Rossman, A Y. (1989) Fungi on Plants and Plant Products zn the Unzted States American Phytopathologlcal Society, St Paul, MN. 35 Samuels, G J and Rehner, S A. (1993) Toward a concerpt of genus and species of Trzchoderma, m Pest Management Bzologzcally Based Technologzes (Lumsden, R D and Vaughn, J. L., eds.), American Chemical Society, Washmgton, DC, pp 186-l 88 36 Aluko, M 0 and Hering, T. F (1970) The mechamsms associated with the antagomstlc relationship between Cortzczum solanz and Glzocladzum wrens Trans Br Mycol Sot 55, 173-179 37 Howell, C R and Stlpanovlc, R D (1983) Ghovirm, a new antibtotlc for Glzocladzum wrens, and Its role m the bIologIca control of Pythzum ultrmum Can J Mzcrobzol 29, 321-324. 38 Jones, R W and Hancock, J G (1987) ConversIon of vmdm to vlrldlol by vlrldmproducing fungi Can, J Mzcrobzol 33,963-966 39 Lumsden, R D , Locke, J C., Adkms, S T , Walter, J F , and Rldout, C J (1992) Isolation and locahzatron of the antlbiotlc ghotoxm produced by Gliocladzum wrens from alginate prrll m so11and soilless media Phytopathology 82,23&235 40 Lumsden, R D , Rldout, C J , Vendemla, M E , Hamson, D J , Waters, R M , and Walter, J F (1992) Characterlzatlon of major secondary metabohtes produced m sollless mix by a formulated strain of the blocontrol fungus Glzocludzum wrens Can J Mzcrobzol 38, 1274-1280 41 Taylor, A (1986) Some aspects of the chemistry and biology of the genus Hypocrea and Its anamorphs, Trzchoderma and Glzocladzum Proc Nova Scotia Inst Scz 36,27-58 42 Roberts, D P and Lumsden, R D (1990) Effect of extracellular metabolltes from Glzocladzum wrens on germmatlon of sporangla and mycellal growth of Pythzum ultzmum Phytopathology 80,46 l-465 42a. Warmg, P , Elchner, R D , and Mulbacher, A (1988) The chemistry and biology of the unmunomodulatmg agent ghotoxm and related eprpolythlodloxoplperlzmes Med Res Rev 8,499-524 43 Mintz, A and Walter, J F (1993) A private Industry approach development of GhoGardTM for disease control m horticulture, m Pest Management Bzologzcally Bused Technologres (Lumsden, R D and Vaughn, J L , eds ), American Chemlcal Society, Washmgton, DC, pp 398-403. 44 Lumsden, R D , Locke, J C , and Walter, J F. (1991) Approval of Glzocludzum wrens by the U S Envlronmental Protectlon Agency for blologlcal control of Pythlum and Rhlzoctoma dampmg-off. Petrza 1, 138
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45 Wtlhtte, S E., Lumsden, R D , and Straney, D. C (1994) Mutational analysts of gliotoxm productton by the biocontrol fungus Gltocladtum wrens m relation to suppression of Pythmm damping-off Phytopathology 84,816-82 1. 46 Howell, C R and Stipanovic, R. D. (1995) Mechamsms m the biocontrol of Rhtzoctonta solani-mduced cotton seedlmg disease by Gltocladtum wrens antibiosts Phytopathology 85469-472 47 Lumsden, R D., Walter, J. F., and Baker, C. P (1996) Development of G/locladtum vzrens for dampmg-off disease control Can J Plant Path01 18, 463-468. 48. Lumsden, R D. and Vaughn, J. L. (1993) Pest management’ biologically based technologies, m Proceehngs ofBeltsvtlle Symposzum XVIII, Beltsville, MD, May 2-6, American Chemtcal Soctety, Washington, DC, p. 435 49. Lumsden, R. D., Locke, J. C , Lewis, J A., Johnston, S. A , Peterson, J. L , and Rtstamo, J. B (1990) Evaluation of Gfzocladtum wrens for biocontrol of Pythmm and Rhtzoctoma dampmg-off of bedding plants at fout greenhouse locations Brol. Cult Control Tests 590 50 Beagle-Ristamo, J. E and Papavizas, G. C (1985) Biological control of rhtzoctoma stem canker and black scruf of potato Phytopathology 75, 560-564 51 Rtstamo, J B., Lewis, J. A., and Lumsden, R D. (1994) Influence of isolate of Gltocladtum vtrens on sclerotra of Sclerotwm rofin, soil mtcrobiota, and the incidence of southern blight Phytopathology 81, 1117-I 124 52 Jackson, M and Schisler, D H (1992) The composttton and attributes of Colletottwhum truncatum spores are altered by the mutational environment Appl Envtron Mtcrobtol 58,226@-2265. 53 Eyal, J., Baker, C F , Reeder, J D , Devane, W E , and Lumsden, R D (1997) Large scale productron of chlamydospores of Gltocladtum wrens strain Gl-2 1 m submerged culture. J. Zndust Mtcrobtol Brotechnol 19, 163-l 68 54 Lewis, J A and Papavizas, G. C. (1987) Application of Trtchoderma and Gllocladrum in alginate pellets for control of Rhizoctonia dampmg-off Plant Path01 36,438-446 55. Betz, F , Rispm, A , and Schneider, W (1987) Biotechnology products related to agrtculture Overview of regulatory decisions at the U S. Envnonmental Protection Agency. ACS Symposium series 334, American Chemical Society, Washington, DC, pp 3 16-327 56 (1989) Data requirements for pesticide registration; final rule. Federal Register 53, 15,952-15,999 57. Ristamo, J. B., Perry, K B., and Lumsden, R. D. (1996) So11 solarization and Gltocladtum wrens reduce the mcrdence of southern blight (sclerotrum rolfirr) m bell pepper m the field. Btocont Sci and Technol 6,583-593 58 TJamos, E. C. and Fravel, D. R. (1995) Detnmental effects of sublethal heatmg and Talaromyces flavus on microsclerotia of Verttctlltum dahltae Btol Control 85,388-392. 59 Papavtzas, G C , Lewis, J A , and Abd-El Moity, T. H (1982) Evaluation of new biotypes of Trtchoderma harztanum for tolerance to benomyl and enhanced biocontrol capabilities. Phytopathology 72, 126-132
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60 Postma, J and Luttrkholt, A. J. G (1993) Selectton of benomyl-resrstant Fusarcum tsolates for ecologrcal studies on biological control of Fusarzum welt of carnation Neth J Plant Path01 99, 175-188 61 Burkhead, K D , Schtsler, D A , and Slmmger, P J (1994) Pyrrolmtrm productron by biologtcal control agent Pseudomonas cepacla B37w m culture and colomzed wounds of potatoes Appl Envwon hkcroblol 60,203 I-2039 62. Frrdlender, M Inbar, J., and Chet, I (1993) Btologrcal control of soilborne plant pathogens by beta-l ,3-glucanase-producing Pseudomonas cepacra. So11Bzol 63 Mao, W., Lewis, J A, Hebbar, K. P , and Lumsden, R D. (1997) Seed treatment with a fungal or a bacterral antagomst for reducmg corn dampmg-off caused by species of Pythzum and Fusarwm Plant Dis 81,450-454.Blochem 25, 1211-1221.
Joint Action of Microbials Claude Alabouvette
for Disease Control
and Philippe Lemanceau
1. Introduction
During the past 20 yr, more attention than ever has been given to the development of btological methods to control plant diseases.Indeed, the concern for food of high quality, wtthout residues of pesticides, and for a sustainable agrtculture that will preserve the fertthty of soil, and prevent the pollutton of the environment, has stimulated research dealmg with btological control At the same ttme, progress made m molecular technology has provided tools to study the modes of action of btocontrol agents. It 1snow possible to understand the mechanisms by which an antagonist can hmtt either the density or the activity of the target pathogen, and can induce resistance of the host plant. This knowledge should help to identify the environmental condmons favorable for application of biocontrol, and improve efficiency and consistency of biocontrol methods. Until now, practical apphcatton of btological control has been limited to a very few commerctal products effective against a limited number of pathogens in a few crops. One strategy to make biological control successful would be to associate in a single product several btological control agents having complementary or even synergistic modes of action against the same pathogen, or having antagonistic effects on several pathogens affecting the same crop. Usually, biological control agents have been selected for their efficacy toward a given pathogen, and therefore have a limited spectrum of targets. This target specificity is a disadvantage for practtcal use of these biocontrol agents, smce they have to be compattble with the pesttctdes required to control other pests and diseases affecting the same crop. An associatton of mtcroorganisms able to control several diseaseswill represent a great advantage for practical application of biological control Association of several microorganisms in a single product would also improve the consistency of the control. Indeed, btologtcal From Methods m Biotechnology, vol 5 B/opeshodes Use and Debvery Edlted by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
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control IS often considered as less conststent than chemtcal control. Even tf It IS not always true, one must admit that brologrcal control 1smore dependent on envtronmental factors than chemical control. The idea to utthze combmatrons of antagomsttc mtcroorgamsms came from the study of soulsthat are naturally suppressive to diseasesinduced by sotlborne plant pathogens. Indeed, the control provided by the complex mteractrons responsible for sot1suppresslveness 1salways more consistent and stable with time than the control provided by a gtven strain of antagomstrc mtcroorgamsm, Isolated from the suppresstve so11 and mvolved m the mechanisms of suppressron. In this chapter dealing with Joint action of mtcrobtals for disease control, the first part will be dedrcated to a summary of knowledge resulting from the study of soils suppressive to fusarmm w&s, m order to show the great complextty of mechanisms responsible for consrstent control of a disease The chref modes of action by which antagomsttc mtcroorgamsms control diseases~111be presented m the second part Then, examples of the beneficial effects of assoclatton of several mtcroorgamsms having different modes of action will be presented, before dtscussmg prospects for then application as blologtcal control products, 2. An Example of Joint Action of Microbials: Soils Naturally Suppressive to Fusarium Wilts Suppressive soils are soils m which diseaseincidence or diseaseseventy remams low despite the presenceof the pathogenand environmental conditions favorable to diseaseexpressionon a susceptiblevartety of hostplant. Soils suppressiveto someof the most tmportantdiseasescausedby sotlbomeplant pathogenshave beendescribed, mdrcatmgthat so11suppresstvenessISnot a rare phenomenon(Z-3). Among the bestknown examples are soils suppressive to msarium wilts. The study of these ~011s demonstrated clearly that suppresstvenessIS based on mteractronsamong several mtcroorgamsmshaving different modesof action and acting togetherto conststently control the disease.The followmg summary of studiesdealing with soils suppressive to fusarrum weltswill not only illustrate the complex@ of mechanismsmvolved, but also the dtfficulty m reproducing sucha phenomenonby mtroducing selectedstrains of antagomsttcrmcroorgamsm m a conducive sot1 The first reports of fusartum-wilt-suppressive soils were made by Stover (4) m Central America, where banana planted m soils having a high content m Montmortllomte-type clays were less affected by the Panama disease than banana planted m solIs from another type Later, Smith andSnyder(5,6), studymg a suppressive sot1from California, made the observatton that thts so11was rich m Fusarium oxysporum, leading Toussoun (7) to state that soils suppressive to fusarmm wilts induced by pathogenic F oxysporum harbor high levels of saprophytrc fusarra. But It was still unclear whether so11suppressrveness was linked to sot1ablotrc characterrsttcs or to the sot1mtcroflora. Louvet et al.
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(8) were the first to establish the microbial nature of soil suppressiveness to fusarium wilts They demonstrated that suppressiveness disappears after heat treatments that destroy most of the microorgamsms, and is restored by mtroducmg a small proportion of the suppressive soil mto the heat-disinfested suppressive soil. It was also possible to make a conducive soil suppressive by mixmg 10 p 100 of suppressive soil in it. This global transfer of suppressiveness is achieved by the introduction of a sample of suppressive microflora mto the conducive soil. To determine the role of each population constitutmg the mixture, Rouxel et al. (9) isolated different types of microorgamsms from the suppressive soil and reintroduced them mto the heat-treated soil. Results showed that nonpathogemc F oxysporum and Fusarwn solam wet e involved m the mechanisms of soil suppressiveness, but the mechanisms by which the soils suppress disease remam obscure. Constdermg that addition of glucose to the suppressive soil made it conducive and stimulated the germination of chlamydospores of F oxysporum, Alabouvette et al (10) suggested that competition for carbon (C) could be one of the mechanisms by which soils suppress fusartum wilts. Alabouvette et al. (22) also demonstrated that the microbial biomass was greater and more responsive to glucose amendment m a suppressive than in a conducive soil, and concluded that both the general suppression caused by the activity of the total biomass of the soil and the specific suppression caused by the activity of the nonpathogemc Fusana were responsible for the suppressiveness of the soils from the Chlteaurenard area (12) At the same time, Kloepper et al. (13), studying the role of the populations of fluorescent pseudomonads m the rhizosphere of plant, suggested that they could contribute to control diseases.Following the same track, Scher and Baker (14,15) established that either a fluorescent strain of Pseudomonas sp, isolated from a suppressive soil, or its siderophore, can causea conducive soil to become suppressive to fusarmm wilts. Based on the fact that addition of a strong u-on (Fe)-chelator (EDDHA) also made a conducive soil suppressive, it was concluded that competitton for Fe was the chief mode of action of the siderophoreproducmg pseudomonads. Finally, Elad et al. (16,17), having established that the growth of germ tubes arising from chlamydospores was reduced m the presence of siderophore-producing pseudomonads, concluded that competition for Fe was the mechanism responsible for soil suppressiveness to fusarmm wilts. Almost at the same time, Schneider (18) isolated nonpathogemc strains of F. oxysporum from suppressive soils m California, and demonstrated that their addition to a conducive soil infested with F oxysporum f.sp. aplz contributed to hmttmg the severity of fusarium wilt of celery. Later, Pauhtz et al. (19) estabhshed that a Metz sandy loam from the Salmas Valley, suppressive to fusarium wilt of several crops, supported large populations of nonpathogemc F oxysporum, and suggested that they could contribute to soil suppressiveness.
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Together, these data pointed clearly to the role of nonpathogemc fusarta and fluorescent pseudomonads m the suppresston of fusarmm writs m suppressive soils, and tt was necessaryto consider the role of both types of microorganisms. Park et al. (20) and Mandeel and Baker (21) considered the Joint action of nonpathogentcfusarta and fluorescent pseudomonadstn the mechanismsof suppression of t%sanumwelts,but the clearestdemonstrationof the postttve mteracttonbetween theseantagonistswas provided by Lemanceauet al. (22,23; see Subheading 4.). As demonstrated for soil suppressive to htsarium wilts, examples of sot1suppressive to other diseasesalso showed that several mtcroorganisms acting together or successively,and having different modes of action, are responsible for disease suppression.Therefore, microbtal assoctattonsmay be proposed to mimic the complex mteracttonsexisting m suppresstvesoils and achteve btological control 3. Modes of Action of Biological Control Agents To improve efficacy and consistency of btologtcal control, mtcrobtal assoclattons can be proposed However, the btocontrol agents have to be chosen m conJunctton with then modes of actton, whtch should not exclude each other, but, on the contrary, show a complementary or even a synergistic effect. Diseasecontrol may result from a dtrect antagontsmdirected against the pathogen,especiallydunng its saprophyttcgrowth phase,or from an indirect action through induced reststanceof the hostplant. The chief modes of action by whtch antagomsttc mtcroorgarusmscould control diseaseswill be reviewed quickly, keeping m mind that a smgle stramof btocontrol agent may expressseveral modes of actions. 3.1. Microbial
Antagonism
Mtcrobial antagonism implies direct interactions between two mtcroorgantsms that share the same ecologtcal niche. Three mam types of direct mteracttons may be characterrzed: parasitism, competition for nutrtents, and anttbiosts. These mteractions are not exclustve of each other; on the contrary, a gtven strain may possessseveral modes of actions, and tt IS often difficult to dtstmgutsh the relative tmportance of each of them m the efficiency of the observed antagomsm. Microbial antagonism occurs mostly during the saprophyttc phase of plant pathogens, and contributes to reducing the moculum density and/or the saprophyttc growth of the pathogen in the so11and at the root surface, resultmg in a decrease of the probabthty for the pathogen to achieve successful mfecttons of the host plant. 3.1.1. Parasitism Parasitism of plant pathogen by other mtcroorgantsms, including vnuses, IS a well-distributed phenomenon, but its significance in relation to btological control of plant diseases 1sstill controverstal.
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Many fungi contam vu-uses or vu-us-hke particles, and m a few cases this parasitism has been associated with reduced virulence of the pathogen. The best example ISthat of Cryphonectria parasitica, hypovirulent strains of which are being used as blologlcal control agents m several countries (24). Mycoparasltes, such as Conzothyrzum minitans and Sporldesmium sclerotlvorum, have been tested as blocontrol agents, and some of them are efficient in controlling diseases caused by Sclerotuzla spp and other sclerotiaforming fungi (25,26). The parasitic activity of strains of Trzchoderma sp has been extensively studled, and plays a major role in the antagonism expressed against Rhzzoctonza solani (27). But discrlmmation between parasitism and other modes of action 1sdifficult to establish, since cell-wall-degrading enzymes, such as chltinases and glucanases, are mvolved m the process of parasitism. Most strams of Trlchoderma spp possessseveral modes of action contributing to their blocontrol activity (28). Whether parasitism is one mode of action that can be deliberately associated with other modes of action to improve efficacy of blologlcal control has not yet been investigated. 3.1.2. Competition for Nutrients Because so11IS an ohgotrophic milieu, and because so11microorganisms and plant pathogens are heterotrophic, competition for C and energy IS strongly expressed m SOIL 3 1.2.1
COMPETITION
FOR CARBON
As already stated (see above), competltlon for C IS one of the mechanisms responsible for so11suppresslveness to fusarmm wilts. Competltlon for C IS expressed m every soil, and ISconsidered responsible for the well-known phenomenon of funglstasls, which describes the mhlbltlon of fungal spore germlnation m soil (29,30). Energy deprivation in sol1 is also partly responsible for “general suppression of a pathogen that is directly related to the total amount of mlcrobiologlcal activity at a time critical to the pathogen” (2). This general suppression results from the combined activity of several microbial populations, and, even if the mechanisms are not clearly understood, application of mlcroblal assoclatlons will increase the intensity of competltlon for nutrients. Any specific antagonism IS expressed on this background of general suppression, and any blocontrol agent apphed to sol1 will be submitted to soil fungistasis. Some species or strains of antagonists are more competltlve than others, and should be selected for biological control. For example, Couteaudler and Alabouvette (31) have shown that a great diversity exists among strains of nonpathogemc F. oxysporum in relation to their ability to utilize C efficiently. A slgmficant correlation was established between the ability of several strains
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of nonpathogemc F oxysporum to mhrbtt the germmatron of the pathogen m the rhlzosphere, reduce drseaseIncidence of fusartum writ of flax, and compete efficiently for C, with the pathogenic F oxysporum m sot1 (32). Competitton for C has also been involved in the determtmsm of the antagonism expressed by different strains of Trcchoderma sp against several plant pathogens, especially F. oxysporum (33). 3.1 2.2. COMPETITION FOR MINOR ELEMENTS
Competttion for minor elements also frequently occurs m so11 As already stated (see above), competmon for Fe 1sone of the modes of action by whtch fluorescent pseudomonads hmtt the growth of pathogenic fungi and reduce disease incidence or severity. Under conditions of Fe stress,these bacteria synthesize stderophores, called pseudobactms or pyoverdms, which show a higher affinity for Fe3+than fungal srderophores. Numerous studies have associated the bacterial antagonism to pseudobactm synthesis, and several review papers are available (34-3 7). Other micronutrtents (Cu, Mn, Zn) also play a role in controllmg diseases induced by soilborne pathogens. Then- mode of action is not clearly established, but they contribute to some extent to sot1suppresstveness (38). The most important point to stress 1sthat competrtton for a given nutrient IS not exclusive from competmon for another nutrient, and, therefore, assoctatron of two antagomsttc mtcroorgamsms competing with the pathogen for two dtfferent nutrients may result m an increased efficacy of biocontrol. Moreover, competttton for nutrients 1snot exclusive from other modes of action, and may play an important role m the effictency of a btocontrol agent, even tf another mode of action has been investigated 3.1.3. Antibiosis Antrbtosts is the antagonism resulting from the production by one mtcroorgamsm of secondary metabolites toxic for another mrcroorganism. Antrbrosis 1sa very common phenomenon responsible for the btocontrol activity of many organisms, such as Pseudomonas spp, Bacillus spp, or Trlchoderma spp developed as btocontrol agents. A variety of different anttbtottcs, bactertocms, enzymes, and volatile compounds have been described, and are Involved m the suppressron of different pathogens. Several review articles are available (39-42). A given strain of brocontrol agent may produce several types of antifungal compounds, effective against certain species of fungal pathogens. For example, the production by fluorescent Pseudomonas sp of phenazmes and 2-4-dtacetylphloroglucmol was shown to be the prrmary mode of antagonism agamst Gaeumannomyces gramznzs var. triticz (43-45), but 2-4-dtacetylphloroglucmol and cyanide were
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mvolved in the antagonism expressed against Chalura elegans (44,46,47). On the contrary, these secondary metabolites have not yet been implicated m the inhibition of the growth or activity of F oxysporum (37). Since a given strain often produces several of these metabolites, the best procedure to demonstrate the involvement of a given molecule in the antagonistic activity of the biocontrol agent is to produce mutants affected m their ability to synthesize the molecule, and to demonstrate that the deficient mutant is no more able to control the disease (41). But it is important to emphasize that a single antifungal metabohte generally does not account for all the antagomstic activity of a biocontrol agent (40). Therefore, it may be very useful to associate several strains of btocontrol agents producing different types of antifungal metabolites, to improve the efficacy or enlarge the acttvity spectrum of biological control. 3.2. Induced Systemic Resistance More and more studies are devoted to the resistance induced m the host plant by apphcatton of btocontrol agents. Induced systemic resistance classically occurs when an inducing agent is applied prior to challenge maculation with a pathogen, resulting in reduced diseasem compartson to the nomnoculated control. Kuc et al. (48) reported systemic protection of cucumber against Colletotricum orbzculare when the cotyledons or the first leaves of the plant were premoculated with the same pathogen. It has also been well established that the premoculatton of an host plant with an incompatibleforma speczalzs or race of F oxysporum will result in reduced disease severity when the plant IS moculated with the compatible pathogen (49). Therefore, it was suggested that the nonpathogemc fusaria used to control fusarium welts may be effective through induced resistance (22). Using one experimental design wtth a split-root system, which allowed application of the biocontrol agent on one side and the pathogen on the other side, Ohvam et al. (50) demonstrated that mduced systemic resistance contributes to the biocontrol efficacy of a nonpathogemc strain of F oxysporum The fluorescent pseudomonads, selected for their plant-growth-promotmg capacity or for their biocontrol activity, have been shown to induce systemic resistance in the plant (51). The first evidence was given by Van Peer et al. (52), who demonstrated that root colomzation of carnation by a stram of fluorescent Pseudomonas sp resulted in an accelerated and increased accumulation of phytoalexms m the stem of carnation after moculatton with F oxysporum f.sp. dianthl. Many other biocontrol agents are able to induce resistance m the host plant, and several recent review papers are available (48,51,53). Induced resistance is not exclusive from other modes of action, and may exert a complementary
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effect to microbial antagonism. Indeed, direct antagonism usually limits the saprophytic growth of the pathogen, resulting m a decreased number of infection sites, and induced resistance ltmrts the growth of the pathogen during its parasitic phase inside the plant. Because the control resulting from an associatton of several modes of action is generally more effective and consistent than the control provided by a single mode of action, it would be interesting to associate several modes of action m combmmg several microorgamsms for biologrcal control. 4. Associations of Microorganisms for Biological Control and Growth Promotion 4.7. Microbial Associations for Biological Control One of the best-documented examples of a microbial associatton used to improve efficacy and consistency of btological control is provided by the association of strains of nonpathogemc F. oxysporum with strains of fluorescent Pseudomonas spp, tsolated from soils suppressive to fusartum wilts. From a theoretical point of vrew, competition for C between pathogemc and nonpathogemc F oxysporum, the existence of which has been demonstrated in the suppressive soils from Chiteaurenard, was not contradictory with the existence of competmon for Fe, as demonstrated m the suppressive soils from the Salinas Valley. Therefore, considering the two hypotheses, Lemanceau et al (54) established that both competition for C and competmon for Fe drd exist m the suppressive soils from Chateaurenard, even if the populatrons of fluorescent Pseudomonas spp isolated from the suppressive soil were not more competitive for Fe than the populations isolated from a conductve sot1 (54). Addition of C with EDDHA in a conducive soil resulted m an intermediate level of receptivity between the htgh conduciveness observed after addition of C and strong suppressiveness after addition of EDDHA (55). These observations prompted the hypothesis of a complementary effect of nonpathogemc F oxysporum with fluorescent Pseudomonas spp. Indeed, followmg a specific screening procedure, Lemanceau and Alabouvette (56) isolated from the suppressive soil strains of fluorescent Pseudomonas spp able to improve the efficacy of biological control achieved by the application of a strain of nonpathogemc F oxysporum. Park et al. (2U), followmg another approach, also showed that interactions between Pseudamonasputzda and strains of nonpathogemc F. oxysporum could achieve biocontrol of fusarmm wilts. The mechanisms of this beneficial mteraction remained obscure until Lemanceau et al (22,23), using a siderophore-deficient mutant ofP putzda strain WCS358, demonstrated that competition for Fe resulting from the activity of the bacterial strain enhanced the efficacy of competition for C between strains of F. oxysporum. Indeed, the growth yield of a stram of F oxysporum growmg on a single source
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of C was greatly reduced m the presence of the bacterial siderophore pseudobactm 358. Moreover, it was shown that the nonpathogemc strain Fo47 was less sensitive to pseudobactm-mediated Fe competition than the pathogenic F. ox~~~orurn f.sp. dzanthi strain WCS816. These data together demonstrated that competition for Fe, resultmg from stderophore production by Pseudomonas spp renders more severe competrtton for C, resulting from the activtty of both the total biomass and the nonpathogenic F oxysporum. These mechanisms, which exist in naturally suppressive souls,may be used to achieve biological control of fusarium wilts by introduction of selectedstrams of nonpathogemc F oxysporum associated with fluorescent Pseudomonas spp mto conducive substrates. Several experiments carried out under commercial-type conditions have demonstrated the validity of such an approach. The control provided by the association of the nonpathogemc F oxysporum strain Fo47 with the P fluorescens strain C7 was always better and more consistent than the control achieved by either one or the other biocontrol agent (56,57). Fungi other than F. oxysporum can be associated to fluorescent Pseudomonas spp to achieve biological control of fusarium wilts. Coinoculation m pot bioassays ofAcremomum rutdum and Verticillium lecanil with different strams of Pseudomonas spp, significantly suppressed disease,compared with the control treatment, if the microorganisms were applied m moculum densities that were ineffective m suppressmg disease as separate inocula (58). Nonpathogemc strains of F. oxysporum have also been associated with other bacteria, such as Bacillus sp, but, rn the case of fusarium wilt of chickpea, the association of a strain of Baczllus sp did not improve the control achieved by a strain of nonpathogenic F. oxysporum (59). Other microbial associations, such as Trichoderma spp with Pseudomonas spp have also been studied to improve efficacy of biological control, but the results were often contradictory and ~111be discussed below (see Subheading 5.). On the contrary, several studies have demonstrated that association of bacteria with mycorrhizal fungi have a beneficial effect on plant growth. 4.2. Microbial Associations for Plant Growth Promotion The roots of most terrestrtal plants are inhabited by symbiotic fungi forming specialized structures known as mycorrhizas. Based on the mteractions established between the fungus and the plant root, two mam types of mycorrhtzas are distmguished: the ectomycorrhizas and the vesicular-arbuscular mycorrhizas.In both cases,the association between the fungus and the root occurs m the soil, and therefore can be influenced by other soilborne microorganisms Recently, some beneficial associations have been described. A recent review by Garbaye (60) shows how the symbiotic establishment of mycorrhizal fungi on plant roots is affected in various ways by the other micro-
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organtsms of the rhtzosphere Some bacteria, mostly fluorescent pseudomonads, consistently promote mycorrhtzal development. These bacteria have been called mycorrhizatton helper bacteria (MHBs) Several modes of action have been proposed to explain these postttve mteractions between bacteria and a mycorrhtzal fungus: The bactermm prohferatmg tn the rhizosphere before any mvolvement of the symbtottc fungus improves the recepttvity of the root to the mycorrhrzal formation; the bacterium interferes with the plant fungus recogmtion mechamsms, which are the first steps of the mteractton process leadmg to the symbtosts, the bacterium helps the growth of the fungus in its saprophytic stage in the rhizosphere, or on the root surface; the metabolic activtty of the bacterium multtplymg m the rhtzosphere modifies the physicochemical properties of the soil m a way to facilitate mycorrhizal mfectton, the bacterium triggers and accelerates the germination of the spores or other dormant propagules specialized m the conservation of the fungus m the soil. Whatever the mechanism, the use of helper bacteria as an adjuvant of fungal moculum is considered m order to improve mycorrhtzatton of trees There are also several papers reporting the synergtsttc effect of the association of VA-mycorrhiza with nitrogen (N)-fixing bacteria For example, Azcon et al. (61) described selecttve interacttons between different species of mycorrhizal fungi and strains of Rhizoblum meliloti apphed to Medzcago satwa. Depending on the combmatton of strains tested, there was a significant increase of the concentration and/or content of N m the shoots. This increase may be a consequence of a phosphorus-mediated sttmulation of N-fixation by VA-mycorrhiza, but m other cases the increase m mtrogen content seems to reflect a VA-mycorrhtzal-mediated enhancement of N uptake from the soil. In another example, Paula et al. (62) reported synergistic effects of VA-mycorrhtzal fungi and drazotrophtc bacteria on nutrition and growth of sweet potato Tuber production and N and phosphorus accumulatton were increased when diazotrophtc bacteria were applied together with VA-mycorrhtza-fungal spores. Thts beneficial effect seems to be caused by an enhanced mycorrhization of the plant in the presence of the bacteria. These few examples show that assoctatton of several mtcroorgamsms IS not only useful for biocontrol of plant drseases, but tt may also contribute to enhance plant growth.
5. Use of Microbial Associations for Biological Control: Prospects and Constraints Although experiments conducted under commerctal-like condtttons have shown great mterest m using microbtal assoctations to improve efficacy and consistency of btological control, practical appltcations of these mixtures need
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further mvestlgatlon. It 1s first necessary to evaluate the compatlbilrty of the microorganisms under various envlronmental condltlons, and, second to develop production and formulation processes leading to a commercial product easy to handle and apply. 5.1. Compatibility
Between Microorganisms
To show an additive effect, the mlcroorgamsms to be associated must be fully compatible. They must establish together m the rhlzosphere of the host plant, without excluding each other by competltlon or antiblosls. This compatlblllty may be influenced by environmental condltlons, as shown by the contrasting data resulting from the assoclatton between strains of Trzchoderma spp with fluorescent pseudomonads Dandurand and Knusden (63) failed to demonstrate any beneficial effect of the associatlon of a strain of Pseudomonasfluorescens with a strain of Trlchoderma harzzanum m controllmg Aphanomyces root rot of peas, although the presence of the bacteria stimulated the hyphal growth of the fungus orlgmatmg from the coated pea seeds. Hubbard et al (64) reported that a strain of Trzchoderma hamatum applied as comdla to pea seedswas effective in controllmg seed rots caused by Pythzum spp in some soils, but not m other soils. This failure was a result of the antagonism exerted by fluorescent pseudomonads that colomze seed coats and lyse germlmgs of T hamatum on treated seeds This antagonism between fluorescent pseudomonads and T. hamatum was controlled by Fe avallabihty m the soil, and addition of ferrous oxalate to soil permitted T hamatum to protect pea seeds. In vitro experiments confirmed that extracellular compounds produced by fluorescent pseudomonads, under condltlons of Fe deprivation, were responsible for mhlbltlon of T hamatum, and suggested that pseudomonads mhlblt T hamatum through the production of slderophores. Studying the interactions between fluorescent pseudomonads and VA mycorrhlzal fungi, Pauhtz and Lmdermann (65) failed to show any beneficial effect of the VA mycorrhizal fungi on the population density and activity of the fluorescent pseudomonads. The mteractlons depend both on the fungal species and the bacterial strain. The population density of the bacteria was lower m the rhizosphere of cucumber roots colonized by Globus intraradices than m nonmycorrhizal plants. But this difference was not detected when the mycorrhizal fungus was Globus etunacatum. If some strains of fluorescent pseudomonads delayed the germination of G etunicatum spores, none of the bacterial strains affected the colomzation of cucumber roots by the mycorrhlzal fungus These results show how complex and specific are the mteractlons between several strains of microorganisms benelklal for plant growth. It is therefore impossible to draw any general conclusion.
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Havmg selected mdependently, two efficient microorgamsms do not guarantee that their association will result m an increased beneficial effect. The best approach to create effective combinattons of beneficial microorganisms IS to isolate the candidate microorgamsms from the same ecological niche, and to develop specific screening procedures. For example, the nonpathogemc F. oxysporum strain Fo47 and the P jluorescens strain C7 have been isolated from the same suppressive soil, and then selection has been conducted in a biotest m which the two mtcroorgamsms have been confronted alone or together to the host plant and its pathogen (56). Only 8% of the bacterial strains associated with Fo47 increased the biocontrol capacity of the nonpathogemc F oxysporum. Then their compatibihty has been studied under various environmental conditions, m soil and m rockwool, m the rhizosphere of different plant species (66). Moreover, it has been established that the nonpathogemc F oxysporum strain Fo47 was much lesssusceptibleto the pseudobactm produced by a strain of P.Juorescens than a strain of F. oxysporunzf.sp. dzanthi (23). More attention should be given to the natural associations of microorganisms m order to select antagonists that could be used m combmations.
5.2. Development of Microbial Products Development of microbial products based on association of microorgamsms has not yet been achieved Obviously, the microorganisms will have to be produced separately by liquid or solid-state fermentation, but the question is whether they can be mixed m a single formulation, or have to be formulated and stored separately, to be mixed at the moment of application. Fermentation and formulation processes represent important steps in the development of a biocontrol product. Indeed, not only should a high biomass be produced at the lowest cost, but the properties of this biomass, i.e., tts capacity to control the disease, must be conserved during the processing and the storage Several review papers are available that discuss the principal requirements for producmg and formulatmg an active biomass (67,68). Obvtously conditions of production and formulation are different for fungi and bacteria, but, even for the same species, the results may differ from one strain to another. For example, Hebbar et al. (69) showed that the proportton of comdia vs chlamydospores of F oxysporum erythoxzll, used to control coca, varies according to the composition of the growth medium, and, for the same medium, varies from one strain of F oxysporum to another Formulatton of mtcroorgatnsms as seed coating requires spectfic conditions to preserve the viability of the microorgamsms, and to enable then growth in accordance with seed germmatton. The water activity 1san important factor to control, and it would be difficult to determine conditions favorable to the survival of a mixture of bacteria and fungi at the seed surface.
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At the present time, cultures grown in hydroponics on artificial substratum (rockwool) represent an unique opportunity to apply microbial associations. In hydroponics, the microorganisms can be applied through the drip irrigation system, as a mixture, or successively, and repeated applications can easily be done. Microbial associations can also easily be applied to potting mixtures. It 1spossible to mtx each microorgamsm with one of the constituents of the mixture, and to use this organic matter as the support of the microorgamsms Peat and bran-peat mixtures are classically used to grow microorganisms, such as Trzchoderma and Glzocladzum, and peat is also used as a vector to apply Bradyrhizobium to seeds (70). This strategy is presently used m this laboratory to prepare a substratum, enriched with growth-promotmg microorganisms, to improve the successof acclimatation of vitro plants. The last step before commercial use of such microbial mixtures will be registration, and one must admit that it would probably be more difficult to prove the mocuity of a mixture than that of a single strain of microorganism. Today, there is no example of commerctal application of a biocontrol product assoctatmg several strains of antagonistic microorganisms.
5.3. Association of Several Modes of Action in a Single Strain Recently, another approach has been proposed to make biological control more successful. Rather than associatmg several strains of biological control agents m a single product, it has been proposed to associate several modes of action in a single strain of biocontrol microorganism. Accordmg to Roberts (71), three strategies can be followed to enhance the btocontrol performance of a bacterial strain through genetic engineering: adding biocontrol traits to bacterial biocontrol agents, modifying the regulation of expression of traits important to biocontrol, and enhancing the stability of the biocontrol activity. Several papers report attempts to associatein a given strain 0fP jluorescens or P. putzda the capacity to produce several of the secondary metabolites havmg antifungal properties. The mtroduction of DNA encoding the synthesis of an antagonistic metabolite m a nonproducmg strain usually resulted in an increased disease suppression by the transformed strain, in comparison with the parental strain. For example, insertion of the locus responsible for the synthesis of 2,4-dtacetylphloroglucmol mto nonproducer strains resulted m synthesis of phloroglucinol and increased mhibition of G. gramznzs var trztzcz and R. solani m vitro (43). The strain P3 of P j’haorescens had only a slight activity in controlling black root rot of tobacco, but the recombinant with cyanide-encoding genes from the strain CHAO showed an increased btocontrol activity (46).
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Having demonstrated the synergistic effect of the assoctatton of two chttmolytic enzymes from T. harzzanum with cells of Enterobacter cloacae on the mhtbttion of spore germmatton of several pathogenic fungi, Lorito et al. (72) suggested transformmg the bacteria with the fungal genes encoding cellwall-degrading enzymes to improve the efficacy of those btocontrol bacteria. Today, the large possibilities offered by genetic engineering stimulate this type of research dealmg with improved strains for btological control. However, before practical application of these strains, many problems have to be solved and the successof this strategy will also depend on the acceptance by the public of the use of transgemc mtcroorganisms. 6. Conclusion Biological control of plant diseases,especially of plant diseasesinduced by soilborne pathogens, is presently restricted to a ltmtted number of commerctal preparations based on a single antagonistic microorganism Most, if not all, of the biocontrol agents control plant pathogens through several modes of action, havmg a complementary beneficial effect. Since a single antagonist does not possessall the possible modes of action, tt would be very Interesting to assoctate several antagonists, to improve efficacy and consistency of btologtcal control. Indeed, m compartson to biological control based on the application of a smgle microorgamsm, natural control of diseases,such as control provided by suppressive soils, appears complex, always involving several microorganisms, and several mechanisms. It seems possible to conclude that the more complex are the mteracttons, the better is the control achieved by the microorgamsms. However, this brief review of the literature shows that there are only a few examples of potential uses of microbial associations for biological control, or for promoting plant growth. Indeed, the selection of compattble antagonists requires a good knowledge of the modes of action of the antagomsts,and also of their ecological behavtor m different soils and m the rhizosphere of several plant species. Much more research 1sneeded before a mixture of beneficial microorganisms will be put on the market. However, as stressed above, there are a few specific niches, such as potting mixes and hydropomcs, m which apphcatton of mtcrobtal associations should be possible m the near future References 1 Baker, K F. and Cook, R J , eds (1974) Biological Control of Plant Pathogens American PhytopathologySociety,St Paul, MN 2 Cook, R J and Baker, K. F., eds (1983) Nature and Practice ofBlologwa1 Control of Plant Pathogens American PhytopathologySociety,St Paul, MN 3 Schneider,R W., ed (1982) Suppresswe Sods and Plant Disease American Phytopathology Society,St Paul, MN
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4 Stover, R H (1962) Fusarial wilt (Panama disease) of bananas and other Musa species CMI Phytopathol Pap 4, 117 p. 5 Smith, S N and Snyder, W C (1971) Relattonshtp of moculum density and soil types to severtty of fusarmm wilt of sweet potato Phytopathology 61,1049-l 05 1 6. Smith, S N and Snyder, W. C. (1972) Germination of Fusarzum oxysporum chlamydospores m soils favorable and unfavorable to wilt estabhshment Phytopathology 62,273-277 7 Toussoun, T A. (1975) Fusarmm-suppressive soils, m Bzology and Control of So&Borne Plant Pathogens (Brnehl, G. W , ed.), American Phytopathology Society, St Paul, MN, pp 145-15 1 8 Louvet, J , Rouxel, F., and Alabouvette, C. (1976) Recherches sur la resistance des sols aux maladies I-Mise en evidence de la nature microbtologtque de la resistance d’un sol au developpement de la fusartose vasculaire du melon. Ann. Phytopathol 8,425-436 9 Rouxel, F , Alabouvette, C , and Louvet, J. (1979) Recherches sur la r&stance des sols aux maladies IV-Muse en Cvtdence du role des Fusarzum autochtones dans la reststance d’un sol a la Fusariose vasculane du Melon. Ann Phytopathol 11, 199-207. 10. Alabouvette, C., Couteaudler, Y , and Louvet, J. (1985) Recherches sur la reststance des sols aux maladies XI-Etude comparative du comportement des Fusarzum spp dans un sol resistant et un sol sensible aux fusartoses vasculaires enrrchis en glucose. Agronomte 5,63-68. 11 Alabouvette, C , Couteaudier, Y., and Louvet, J (1985) Recherches sur la resistance des sols aux maladies XII-Acttvtte resptratotre dans un sol resistant et un sol sensible aux fusarloses vasculaires enrichis en glucose Agronomze 5,69-72 12. Alabouvette, C., Couteaudter, Y , and Louvet, J. (1985) Soils suppresstve to Fusarmm wilt mechanisms and management of suppressiveness, m Ecology and Management of Soil Borne Plant Pathogens (Parker, C A , Rovtra, A D., Moore, K. J., Wong, P. T. W , and Kollmorgen, J. F., eds ), American Phytopathology Society, St. Paul, MN, pp. 101-106. 13 Kloepper, J W , Leong, J , Temtze, M , and Schroth, M N. (1980) Pseudomonas stderophores a mechamsm explaining disease-suppressive soils Cur-r Mtcrobtol 4,3 17-320 14 Scher, F. M and Baker, R. (1980) Mechanism of biological control m a Fusarmmsuppressive soil Phytopathology 70,4 1224 17. 15. Scher, F. M and Baker, R (1982) Effect of Pseudomonasputtda and a synthetic iron chelator on mductton of so11suppresstveness to Fusarmm wilt pathogens Phytopathology 72, 1567-l 573. 16. Elad, Y. and Baker, R. (1985) Influence oftrace amounts of cattons and stderophoreproducing pseudomonads on chlamydospore germination of Fusartum oxysporum. Phytopathology 75, 1047-1052. 17. Elad, Y and Baker, R (1985) The role of competition for iron and carbon m suppression of chlamydospore germination of Fusartum spp by Pseudomonas spp. Phytopathology 75, 1053-l 059
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18 Schneider, R. W (1984) Effects of nonpathogemc strams of Fusarrum oxysporum on celery root mfectlon by F oxysporum f. sp apll and a novel use of the lmeweaver-burk double reciprocal plot technique Phytopathology 74, 646-653 19. Pauhtz, T. C., Park, C S , and Baker, R (1987) BiologIcal control of Fusarmm wilt of cucumber with nonpathogemc isolates of Fusarlum oxysporum Can J Mzcrobzol 33,349-353 20 Park, C S , Pauhtz, T C , and Baker, R (1988) Blocontrol of fusarmm wilt of cucumber resulting from mteractlon between Pseudomonasputlda and nonpathogemc Isolates of Fusarlum oxysporum. Phytopathology 78, 190-l 94 21 Mandeel, Q. and Baker, R (1991) Mechamsms involved m blologlcal control of fusarmm wilt of cucumber with strains of nonpathogemc Fusarlum oxysporum Phytopathology 81,462-469 22, Lemanceau, P , Bakker, P. A. H M , De Kogel, W J , Alabouvette, C., and Schlppers, B (1992) Effect of Pseudobactm 358 production by Pseudomonas putzda WCS358 on suppression of Fusarmm wilt of carnations by nonpathogemc Fusarlum oxysporum Fo47 Appl Enwon Mlcroblol 58,2978-2982. 23 Lemanceau, P , Bakker, P A. H M , De Kogel, W J , Alabouvette, C , and Schlppers, B (1993) Antagonistic effect on nonpathogemc Fusarrum oxysporum strain Fo47 and pseudobactm 358 upon pathogenic Fusarlum oxysporum f sp dzanthz Appl. Environ Mlcrobrol 59,74-82 24 Van Alfen, N K., Jaynes, R A , Anagnostakis, S L , and Day, P R (I 975) Chestnut blight. biological control by transmissible hypovirulence m Endothla parasltlca Science 189,890,89 1 25. Adams, P B and Fravel, D R (1993) Dynamics of Spondesmwm, a naturally occurring fungal mycoparaslte, m Pest Management Bzologlcally Based Technologzes (Lumsden, R D. and Vaughn, J. L., eds ), American Chemxal Society, Washmgton, DC, pp. 189-195 26 Whlpps, J M and Lewis, D H (1980) Methodology of a chitm assay Trans Br Mycol sot 74,41&417 27 Elad, Y., Chet, I., Boyle, P , and Hems, Y. (1983) Parasitism of Trzchoderma spp on Rhlzoctoma solanr and Sclerotrum rolfsu. Scanning electron mlcroscopy and fluorescence mxroscopy Phytopathology 73,85-88 28 Lonto, M., Harman, G E., Hayes, C K., Broadway, R M , Tronsmo, A , Woo, S. L., and DI Pletro, A (1993) Chltmolytlc enzymes produced by Trrchoderma harzlanum antifungal activity of purified endochltmase and chltoblosldase Phytopathology 83, 302-307 29 Lockwood, J L (1977) Funglstasts m solIs Blol Rev 52, l-43. 30 Lockwood, J L (1988) Evolution of concepts associated with sodborne plant pathogens. Annu Rev Phytopathol 26,93-121 3 1 Couteaudler, Y and Alabouvette, C (1990) Quantitative comparison of Fusarlum oxysporum competltlveness m relation with carbon utlhzatlon FEMS Mlcroblol Ecol 74,261-268 32. Alabouvette, C. and Couteaudler, Y (1992) BiologIcal control of fusarmm wilts with nonpathogemc Fusana, m Blologzcal Control of Plant Diseases (TJamos, E C., Cook, R J , and Papavlzas, G C , eds ), Plenum, New York, pp. 415426
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33 Sivan, A and Chet, I (1989) The posstble role of competmon between Trtchoderma harztanum and Fusarmm oxysporum on rhizosphere colonization P&opathology 79, 198-203. 34 Leong, J. (1986) Siderophores* then btochemistry and possible role m the btocontrol of plant pathogens Annu Rev Phytopathol 24, 187-209. 35 Schtppers, B., Bakker, A W , and Bakker, P A H M (1987) Interactions of deletertous and beneficial rhtzosphere mtcroorgamsms and the effect of cropping practices Ann Rev Phytopathol 25,339-358 36 Bakker, P A H M , Van Peer, R , and Schippers, B (199 1) Suppression of sonborne plant pathogens by fluorescent pseudomonads: mechanisms and prospects, m Development tn Agrtculturally Managed-Forest Ecology (Beemster, A B R , Bollen, G. J , Gerlach, M., Ruissen, M. A., Schippers, B , and Tempel, A , eds.), Elsevter, Amsterdam, pp 2 17-230. 37. Lemanceau, P. and Alabouvette, C. (1993) Suppression of msanum wilts by fluorescent pseudomonads. mechanisms and applicattons. Btocontrol Scz Technol 3,2 19-234 38. Hoeper, H. (1996) Importance of physical and chemical soil properties m the suppressiveness of soils to plant diseases Eur J Sot1 Bzol 32,41-58 39. Fravel, D. R. (1988) Role of anttbiosis in the btocontrol of plant diseases Ann Rev Phytopathol 26,75-9 1 40 Loper, J E and Lmdow, S E (1993) Roles of competmon and anttbtosts m suppression of plant diseases by bactertal brologtcal control agents, m Pest Management Biologtcally Based Technologtes (Lumsden, R. D and Vaughn, J L , eds ), American Chemical Socrety, Washington, DC, pp 144-l 55 41. Weller, D. M and Thomashow, L S. (1993) Microbial metabolttes with blological activity against plant pathogens, in Pest Management Btologically Based Technologzes (Lumsden, R D. and Vaughn, J L., eds ), American Chemical Society, Washington, DC, pp 173-l 80. 42. Alabouvette, C., Hoeper, H., Lemanceau, P., and Steinberg, C (1996) Soil suppressiveness to diseases induced by soil-borne plant-pathogens, m Sorl Bzochemistry, vol 9 (Stotzky, G. and Bollag, J. M , eds.), Marcel Dekker, New York, pp 371-413 43 Vincent, M N , Harrison, L. A., Brackm, J. M., Kovacevlch, P A , MukerJt, P , Weller, D M., and Pierson, E A (1991) Genetic analysts of the antifungal activity of a soil-borne Pseudomonas aereofactens strain Appl Environ Mtcrobtol 57,2928-2934 44. Keel, C., Schmder, U , Maurhofer, M., Votsard, C , Lavtlle, J , Burger, U , et al
(1992) Suppresston of root diseases by Pseudomonasfluorescens CHAO. Importance of the bacterial secondary metabohte 2,4-dtacetylphloroglucinol Mol PlantMtcrobe Interact. 5,413. 45 Harrtson, L , Teplow, D B , Rinaldi, M., and Strobel, G. (1991) Pseumycms, a famtly of novel pectides from Pseudomonas syrzngae possessing broad-spectrum antifungal activity J Gen Microbtol 137, 2857-2865 46. Voisard, C , Keel, C , Haas, D , and Defago, G. (1989) Cyanide productton by Pseudomonasfluorescens helps suppress black-root rot of tobacco under gnotoblottc condmons EMBO J 8, 35 l-358
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47 Keel, C , Wnthner, P H , Oberhansh, T H , Volsard, C , Burger, U , Haas, D , and Defago, G (1990) Pseudomonads as antagonists of plant pathogens m the rhtzosphere role of the anttbtottc 2,4-dtacetylphloroglucmol m the suppression of black-root rot of tobacco Symbrosts 9,327-34 1 48 Kuc, J (1987) Plant tmmumzatton and its applicability for disease control, m Innovatzve Approaches to Plant Dtsease Control (Chet, I , ed ), Wiley, New York, pp 255-274 49 Btles, C L and Martyn, R D (1989) Local and systemtc reststance induced n-r watermelons by formae speciales of Fusarium oxysporum. Phytopathology 79, 856860 50 Olivam, C., Steinberg, C , and Alabouvette, C (1995) Evtdence of induced reststance m tomato inoculated by nonpathogemc strains of Fusarrum oxysporum, m Envtronmental Btottc Factors tn integrated Plant Dtsease Control (Manka, M , ed ), Polish Phytopathologrcal Society, Poznan, pp 427-430 51 Kloepper, J W , Zehnder, G. W., Tuzun, S , Murphy, J F , We], G , Yao, C., and Raupach, G (1996) Toward agrtcultural tmplementatton of PGPR-mediated induced systemic resistance against crop pests, m Advances rn Btologtcal Control ofPlant Dtseases (Tang, W., Cook, R. J., and Rovira, A , eds ), Proceedings of the International Workshop on Biologtcal Control of Plant Diseases, China Agricultural University Press, BeiJmg, May 22-27, pp. 165-174. 52 Van Peer, R , Ntemann, G J., and Schippers, B (1991) Induced resistance and phytoalexme accumulation m btologtcal control of fusarmm wilt of carnation by Pseudomonas sp strain WCS417r Phytopathology 81,728-734 53. Van Loon, L C. (1996) Drsease-suppressive actions of Pseudomonas bacteria induced resistance, in Proceehngs of a Workshop on Btologtcal and Integrated Control ofRoot Dtseases tn Sotlless Cultures (Alabouvette, C , ed ). IOBC/WPRS Bulletm, DlJon, September 18-2 1, 1995, pp 53-6 1 54 Lemanceau, P., Alabouvette, C , and Couteaudter, Y (1988) Recherches sur la resistance des sols aux maladies XIV-Modtficatton du mveau de receptivtte d’un sol reststant et d’un sol sensible aux fusartoses vasculanes en rtponse a des apports de fer ou de glucose Agronomte 8, 155-l 62 55. Lemanceau, P. (1989) Role of competition for carbon and iron m mechamsms of soil suppresstveness to fusarmm wilts, m Vascular Wilt Diseases ofPlants-Baste Studies and Control (TJamos, E C and Beckman, C H , eds ), NATO ASI Series, Springer-Verlag, Berlin, pp. 386-396 56 Lemanceau, P and Alabouvette, C (1991) Btologtcal control of fusarmm dtseases by fluorescent Pseudomonas and non-pathogemc Fusartum Crop Protectton 10,279-286 57 Alabouvette, C , Lemanceau, P , and Steinberg, C (1993) Recent advances m btologtcal control of fusarmm wilts Pestzctde Set 37,365-373 58 Leeman, M , Den Ouden, F M , Van Pelt, J. A., Comehssen, C , Bakker, P A H M , and Schtppers, B (1995) Suppresston of fusarmm welt of radtsh by co-moculatton of fluorescent Pseudomonas spp and of root colonizing fungi Eur J Plant Path01 102,2 l-3 1
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59 Hervas, A , Landa, B , and Jlmenez-Dtaz, R. (1997) Influence of chtckpea geno-
type and Bacillus sp on protection from Fusarmm wilt by seed treatment wtth nonpathogemc Fusarmm oxysporum. Eur J Plant Pathol , 103,63 l-642 60 Garbaye, J (1994) Transley Revtew No. 7&--Helper bacteria a new dimension to the mycorrhizal symblosts. New Phytol 128, 197-2 10 61 Azcon, R , Rubto, R , and Barea, J M. (1991) Selecttve mteracttons between different species of mycorrhtzal fungi and Rhlzobzum melzlotl strains, and their effects on growth, N2-fixation (15N) and nutrrtron of Medlcago satlva L New Phytol 117,399404. 62 Paula, M A , Urqutaga, S , Srquerra, J 0 , and Doeberemer, J (1992) Synergistic
effects of vesrcular-arbuscular mycorrhrzal fungi and dtazotrophtc bacteria on nutrmon and growth of sweet potato (Ipomoea batatas) B~ol Ferttl SOJ~S 14,61-66 63 Dandurand, L M and Knudsen, G. R (1993) Influence of Pseudomonas ji’uorescens on hyphal growth and brocontrol activity of Trlchoderma harzzanum m the spermosphere and rhrzosphere of pea. Phytopathology 83,265-270 64 Hubbard, J P., Harman, G E , and Hadar, Y (1983) Effect of soilborne Pseudomonas spp on the btologtcal control agent, Trlchoderma hamatum, on pea seeds Phytopathology 73, 655-659 6.5 Pauhtz, T C and Lmderman, 66
67
68
69
R G (1989) lnteractlons
between fluorescent
pseudomonads and VA mycorrhizal fungt New Phytol 113,3745 Eparvrer, A., Lemanceau, P., and Alabouvette, C (1991) Populatton dynamtcs of nonpathogemc Fusarlum and fluorescent Pseudomonas strains m rockwool, a substratum for sotlless culture FEMS Mzcoblol Ecol 86, 177-l 84 Lumsden, R D and Lewis, J A (1989) Selection, productton, formulation and commercial use of plant disease btocontrol fungt. problems and progress, m Bzotechnology of Fungi for Improvmg Plant Growth (Whipps, J M and Lumsden, R D , eds ), Umverstty Press, Cambridge, UK, pp 17 l-2 17 Harman, G E. and Taylor, A G (1990) Development of an effectrve btologrcal seed treatment system, in Blologlcal Control of Sod-Borne Plant Pathogens (Hornby, D , ed.), C A B Internattonal, Wallmgford, pp 415426 Hebbar, K P , Lewts, J. A., Poch, S. M , and Lumsden, R D. (1996) Agrtcultural byproducts as substrates for growth, comdratton and chlamydospore formation by a potential mycoherbrctde, Fusarmm oxysporum strain EN4 Bzocontrol Scz
Technol. f&263-275 70 Catroux, G , Revellm, C , and Hartmann, A. ( 1996) Possible strategtes to improve the efficacy of mtcrobtal moculants and inoculatron methods, m Blologzcal and Integrated Control of Root Diseases zn Sodless Cultures (Alabouvette, C., ed ),
Working Group “Btological Control of Fungal and Bactertal Plant Pathogens”, IOBC/WPRS Bulletm 19, DlJon, France, September 18-2 1, 1995, pp 159-l 63 71 Roberts, D P. (1993) Genetically modified bacteria for btocontrol of sotlborne plant pathogens, in Pest Management Blologlcally Based Technologies (Lumsden, R D and Vaughn, J. L , eds.), Amencan Chemical Society, Washmgton, DC, pp 33&346. 72 Lortto, M , DI Ptetro, A , Hayes, C K., Woo, S. L , and Harman, G E (1993) Anttfungal, synergisttc mteractton between chttmolyttc enzymes from Trzchoderma harzlanum and Enterobacter
cloacae Phytopathology
83,72 1-728.
III BIOHERBICIDES
9 Neem and Related Natural Products Murray 6. lsman 1. Introduction Although botamcal msectlcldes once held a positlon of Importance m the grower’s arsenal of plant protectlon products, they were almost completely dlsplaced m most mdustrlahzed countries by synthetic insectrcides m the 1950s and 1960s. However, Increasing documentation of the negative environmental and health Impacts of synthetic neurotoxlc msectlcides and increasingly stringent government regulation of pesticides has resulted in renewed interest in the development and use of botamcal pest management products In spite of this interest, there remam only a handful of botamcal msectlcldes m use m North America and Europe, with few new products on the threshold of commerciahzatlon (Z-3). To this point, the market for botanical msectlcldes has been dominated by two plant preparations whose commercial productlon goes back over 150 years. pyrethrum and rotenone While synthetic pyrethrolds (chemicals loosely modelled after the natural msectlcldal constituents m pyrethrum) are among the most potent and widely used conventional msectlcldes, natural pyrethrum (from Chrysanthemum cinerariaefolium; Asteraceae) has maintained a small but consistent market share among so-called “alternative” pest control products Rotenone (from Derris elliptzca and Lonchocarpus spp; Legummosae) 1s still used to a small extent for insect control, but 1snow primarily used as a commercial plsclclde (fish poison), reflecting its original use over 300 years ago. Neither of these products enjoys wide use m conventional crop production, but they have been embraced by organic food producers. Other botanical msectlcldes have seen use in mdustrlahzed countries, but for various reasons have slipped from the marketplace or are used on a very hmlted scale. These include nicotine (from Nzcotzana tabacum, Solanaceae), From Edited
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quassia (from QUUSSEU amara; Stmaroubaceae), ryama (from Ryan~~speclosa; Flacourtiaceae), and sabadilla (from Schoenocaulon officianale; Lihaceae). Why have so few botanical insecticides been developed? One overwhelmmg reason is that the discovery process, based on screening samples through bioassays with pests,has focused on materials that are acutely toxic to insects. However, acute toxicity 1snot the usual modus operandi m the real world of plant defensive chemistry, m which selection seems to have favored a more moderate approach: herbivore deterrence or dtscouragement. If an mvesttgator uses Insect mortality as the bioassay end point, as one would m the case of synthetic msecttctdes, it is not surprismg that so few plant preparattons have been discovered that have efficacy (in the laboratory) comparable to conventional msecttctdes. However, the demonstrated field efficacy and subsequent commercial development of botanical msecticides derived from the Indian neem tree (Azadzrachta zndlca; Meltaceae) have changed our basic assumptions about how a natural product must affect insects to be useful for plant protection on a commerctal scale. Neem functions primarily as an insect growth regulator, but also as a behavior-modifying substance, deterring feeding and/or oviposition m certain pest species (4). Of equal importance, neem has mmtmal toxtctty to vertebrates, is soft on natural enemies (5) and pollmators (61, and degrades rapidly m the environment. Neem serves as a paradigm for the development of other botanical msectictdes having nonneurotoxic modes of action (I), Environmental nonpersistence is an important trait that neem shares with other botanical insecticides. Although neem and perhaps other botanical preparations will prove to have superb efficacy in certain pest management contexts, for the most part it is unrealistic to expect botamcals to displace conventional msecttcides m agriculture and forestry, except where protection of the envtronment is paramount. The extent to which mainstream agriculture is prepared to accept botanical insecticides as legitimate products for plant protection may well depend on the successof neem m the marketplace m the next decade. 2. Materials 2.1. Choice of Plants There is a long list of properties that would be desirable for an ideal msectttide (for example, see refs. 2 and 7); to some extent, the mmimal presence of existmg botanical msecticides m the marketplace reflects the fact that they fall to meet some of the criteria necessary for commercial success.Neem has many desirable attributes, including efficacy at low concentrations, broad spectrum of action, mmimal nontarget toxicity, and no environmental persistence-but even neem has limitations, and is not a panacea for pest management.
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In reviewing the barriers to the commercialization of new botanical msecticldes (3), the following are listed as major barriers* abundance of the natural resource, standardization and quality control, and registration. In the final analysts, two constderattons are foremost: efficacy against one or more pests, and ongoing availability of the natural resource. Although many plant preparations can be used to mitigate pests, only a select group of these are sufficiently and reliably efftcacious to the point that people will actually purchase and use them repeatedly. However, the products that can deliver suitable performance must also be available to the manufacturer in quanttties sufficient to justify the costs of product development and production. To some extent, users will accept a Iowet absolute level of efficacy, but only if the product is safe to the user and the environment, mexpensive, and easily obtained and applied. Neem seeds, as the starting material for botanical msecticides, benefitted greatly not only from the widespread availabilrty of neem trees in India, but also from the fact that seedswere previously harvested and traded for the manufacture of soap. The foliage of Ginkgo biloba produces both medtcmal and msecticldal compounds (8,9); the latter (dtterpene lactones) can be obtained as a byproduct followmg extracting and removal of the more lucrative flavone glycostdes and proanthocyanidms, the compounds of pharmaceutical interest. If the starting plant material IS used exclusively for productton of insecticides, then it must be naturally plenttful, or, preferably, readily cultivated. In these cases, the cost of producmg the plant material can be a significant factor for development. 2.2. Tissue Harvested If the plant is grown strtctly for the production of natural msecttctdes, the best tissue to harvest must be established. This is especially the case for woody perennial plants, but the reader need only be reminded that pyrethrum is an extract of chrysanthemum flowerheads, and rotenone is obtained specifically from the roots or rhizomes of derrts. If the plant has other uses, then the harvest of biomass for msectictde productton has to be both sustainable and compatible with the other uses. The harvested part of the plant should be relatively abundant, at least seasonally, and easily harvested to mirnmize labor costs. Ideally, one wants to select the plant tissue that provides the optimal concentration of active mgredtent(s), and requires the mmtmal extraction, cleanup, and refinement. Seeds tend to be a good starting material, because they are often well protected m nature by secondary compounds. However, seed productton is often limited in species that are not prolific On the other hand, seeds can be a waste product of, for example, the fruit juice industry. Botanical insecticides can be
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prepared from the seedsof soursop (Annona muncata, Annonaceae) and grapefruit (Cztrus paradzsz; Rutaceae), and m certam regrons the seeds of these species can be sourced m large quantmes at mmtmal (or no) cost. For species that have no other use, tt 1s advisable to screen vartous plant ttssues to determine the ttssue having the best combmatton of btoactivity and biomass avatlabrltty. McLaughlin and coworkers have done such an assessment on various plant parts of the pawpaw tree, Aszmzna trzloba (Annonaceae) (20) Although the seeds and unripe fruit produce the most acttve extracts, they are also the least available forms of btomass. The tissues found to gave the best balance of yield and btoacttvtty are the stem bark and wood, but because separation of the bark from the wood could be costly, the most appropriate ttssue for harvest on a sustainable basrs was deemed to be stems Further broassays establrshed that the smallest-size class of stems, namely, twrgs of C6.5 mm m diameter, were the most btoacttve. 2.3. Collection Sites Just as the quahty of agricultural commodmes varies between seasons and between locattons, so do the msecttctdal constituents of the plants that produce them. Although chemical vartabthty is a natural phenomenon, It 1s one that must be managed if a botanical msecttctde IS to be efficiently produced Chemtcal composttton of plants can vary at all levels among spectes, among and within populations, and between tissues Vartatton m the msecttctdal constttuents of Hawanan Zanthoxyhun (rutaceae) sp (II), and of the shrub Aglaaa odor&a (mehaceae) (12), are but two well-documented examples In the case of neem, numerous studies have been undertaken armed at determmmg the factors regulating variabthty of azadtrachtin content m the seeds, but none to date have been conclustve. For all intents, tt remains necessary to assessthe quality of neem seed, erther by chemical analysts (llqutd chromatography) or vta bioassay prior to commerctal-scale extractton. There ~111always be good and bad batches of starting maternal, but achieving a mmtmum acceptable level or standard can be accomphshed by blending lots of dtffermg qualtty, as 1sdone wtth other commodmes, such as coffee beans or tea Plant secondary compounds can be obtained through other means, though perhaps with decreased variabtlity. For example, pyrethrms can be produced by chrysanthemum tissue culture (13), as can azadtrachtms from Azadzrachta cell-suspenston cultures (14). Plant-ttssue culture offers several advantages for the productton of secondary metabolttes (opttmrzatton of productton, no seasonaltty, fewer co-extractives), but tt remains to be seen whether thts method can be cost effective, compared to harvestmg tissue from growing plants
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3. Methods 3.7. Screening for Bioactivity The wide range of insect species used for screening btoassays, and, stmtlarly, the wide range of bioassay types themselves, usually ensure that comparisons of results between laboratortes are tenuous at best. Assuming that the goal of the research is the discovery and development of an msecticide for the management of phytophagous pests of agriculture and forestry, tt makes sense to use a plant-feeding pest spectes as the primary screening organism. However, if screening 1s limited to one species, tt is easy to miss potentially useful bioacttvity against other types of pests, so a more thorough approach is to use a battery of bioassay species, Examples of this approach are the screening programs at the Rothamsted Experimental Station in the United Kingdom (15), the National Chemical Laboratory in India (16), and the Research and Development Corporation in Japan (17). In industry, tt IS not uncommon for as many as 10 pest species to be tested with candidate compounds. Although desirable, few laboratories can afford to mamtam contmuous cultures of more than three insect species, because of the human resources and direct costs required. Some mvestigators who have screened extracts from many plant species have relied on a single organism, e.g., brine shrimp (18) or mosquito larvae (17,19), largely because of the convemence m using these species. Though these bioassays are sensitive and reproducible mdicators of cytotoxtctty, they are not necessarily good predictors of btoactivity against agricultural pests (17). In the author’s research program, the primary screening species is the tobacco cutworm (Spodoptera Iztura), an noctuid pest of tobacco and vegetable crops m tropical and subtropical Asia. Active plant extracts are subsequently evaluated against a range of insects, rncludmg the migratory grasshopper (Melanoplus sanguinipes), the green peach aphid (Myzuspersrcae), the yellow mealworm (Tenebrzo molitor), and the large milkweed bug (Oncopeltus fasciatus). The primary bioassay, utilizing the cutworm, measures larval growth and survival of neonate larvae reared at 26°C for 10 d on arttfictal media, to which plant extracts (or fractions thereof, or pure compounds) are admixed Crude extracts are screened at 1000 ppm fresh wt (= 0 l%), pure compounds at 50 ppm. For compounds active at these concentrations, ECsO values (effective concentration reducing larval growth by 50% compared to controls) are established based on dose-response relattonships obtained usmg four or five lower concentrations An advantage of the larval growth bioassay is that tt can detect effects on the insect that have either behavioral or phystological bases,and effects resultmg from a wide range of modes of action. Many investigators have used antifeedant bioassays (either choice or no-choice feeding tests) for screenmg plant extracts. These strictly behavioral
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bioassaysare no longer conducted on a routine basis for three reasons: A strong antifeedant wrll result m suppressedgrowth m the aforementioned diet bioassay, so a separate bioassay measuring feeding behavior alone IS not needed, differences between insect speciesare far greater for behavioral effects (feeding deterrence) than for physiological effects (toxrcity), and feeding behavior can be a function of bioassay duration, because insects can quickly habituate to feeding deterrents, as has been demonstrated in the case of azaduachtm, the prmcipal antifeedant from neem (20). The utility of antifeedantsper se as crop protectants is therefore questionable, given the plasticity of insect feeding behavior This variation in behavior response IS well exemplified by azadnachtm, the most potent insect antifeedant yet discovered Even closely related species of noctuid caterpillars differ srgmficantly m then behavioral responses to this substance, but their physiological responses are far more consistent (21). And, although azadirachtm is a profound antifeedant for the desert locust, it has no antifeedant effect agamst the migratory grasshopper (22) or the strawberry aphid (23), although both of the latter species are susceptible to the phystological actions of the compound Acute toxicity can be determmed through different modes of admmistranon, i.e., via direct topical application, or via exposure of insects to residues of test materials applied to glass plates or vials (24). A less precise but perhaps more realistic approach is to spray-test materials (m dilute alcoholic solutions) onto plants, either naturally or artificially infested with insects. Placmg insects onto freshly treated plants can indicate contact action of residues of the test material, rather than assessing the impact of the material hitting the pests directly. In these types of bioassays, mortality is normally assessedafter 24 or 48 h An important shortcommg of such experiments is that not all useful crop protectants result m pest mortality within 48 h; significant chronm effects can therefore be missed if acute mortality is the only bioassay endpoint considered. For example, neem msecticides often take 4-7 d to kill lepidopteran larvae (basically, at the time of the next molt), but these insects, though ahve m the mterim, often cease feeding almost immediately, so no further damage to the crop is inflicted. If we are to seriously consider the dtscovery and development of botanical msecticides, we must be prepared to consider many modes of action that do not result in acute mortality. 3.2. Extraction
Active prmciples from most existmg botanical msecticides are of moderate polarity and can be readtly extracted usmg alcohols of various origm. Important considerations m the choice of solvents include cost,safety (low flashpoint), and the potential for recycling Effluent disposal and flammability may preclude the use of organic solvents m some cases,but, for example, petroleum disttl-
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lates are used for the extraction of pyrethrum. There have been very few attempts to use exotic solvents and/or extraction technologies to obtain botamcal insecticides, though a supercritical fluid-extraction process (utilizmg liquid C02) for yielding concentrated pyrethrins from Chrysanthemum flowers has been patented (25). In the case of neem, the seedscan contam up to 40% by weight of oil, and tt is preferable to remove the oil, either through cold pressing or hexane extraction, prior to initial extraction for the azadirachtms. Note that neem oil itself, refined or clarified, can be used as a separate crop protectant targeted at certain soft-bodied pests. For some materials, it may be possible to use a crude extract, followmg removal of the extracting solvent, if the active constituents are present m sufficient concentration However, m most cases, some additional cleanup or refinement is necessary. This can normally be accomplished by some form of hquid-liquid partition, including the use of countercurrent extraction, on a commercial scale. The goal, though, should be to mmimize the number of steps needed to obtain a technical grade extract with an acceptable concentration of active ingredients. Extraction of insecticidal acetogenins from the bark of A. triloba provides an excellent example (28). Bioactivity (measured as brine shrimp toxicity) of the crude ethanohc extract is increased 4.5x by solvent partttion, but an additional partition of the organic phase leads to a further 42-fold increase m acttvity-almost to the same level as that of the mam constituent m purity. Both cost and yield of each step must be factored into the equation before the manufacturer can decide what level of refinement is justified. 3.3. Standardization For a botanical to be approved for use (i.e., registered) m industrialized countries, the putative active ingredient(s) must be specified and Its concentration guaranteed on the product label. It is therefore necessaryto standardize the technical grade material (refined plant extract). There are various chromatographic means of quantifying mdivtdual constituents of complex mixtures such as plant extracts, but high-performance liquid chromatography appears to be the most widely applicable for most types of insecticidal compounds found m plants. The active prmctples m plants almost always occur as suites of closely related structures, often comparable to one another in bioactivity when isolated. Thus, they are collecttvely considered to be the active ingredient, viz., pyrethrins in pyrethrum and azadirachtms m neem. Quantification of active ingredients is not only important for regulatory purposes, but also for trade; m the case of neem, the (total) azadirachtin content determines the price of the refined seed extract.
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Neem kernels contam at least a dozen analogs of azadn-achtm.The chemlstry and biological activity of these are extensively revlewed by Kraus and Rembold (4). There are some significant differences m the behavioral (antlfeedant) and physlologlcal (growth-disrupting) effects of these compounds, but mvestlgatlons of structure-activity relations have revealed that the entlre carbon skeleton 1sessential for insect-growth-regulatmg activity. This reahzatlon, combined with the structural complexity of the azadirachtm molecule (containing 13 chu-al centers and 4 oxygenated rings), diminishes the prospect of syntheslzmg a simpler compound retaining the outstanding bloactivlty of the natural product. From a practical standpoint, the issue of structure-activity relations of the naturally occurring azadirachtms is largely a moot point, because, of the dozen or so compounds m neem kernels, two account for about 99% of the total. These are azadlrachtm proper (sometimes referred to as “aza A”), and 3-tlgloylazadlrachtol (frequently referred to as “aza B”). In analyzing 20 partially- to highly-refined neem kernel extracts via HPLC for hmonoid constltuents, we found that these two compounds occur m ratios of 2-6 to 1 (average 2 5.1), with azadlrachtin dominating (Isman et al., unpubhshed data). As an Insect growth regulator, 3-tigloylazadlrachtol ls substantially more active than azadlrachtm agamst some pest species (e.g., S. litura and Epzlachna vanvestu), but less active against others (e.g., Schzstocerca gregarza and Helzothis vzrescens). As an antlfeedant against noctuld larvae, 3-tlgloylazadlrachtol appears to be somewhat less active than azadlrachtm Given the above observations, considering the azadlrachtms collectively in quantitatmg the active ingredients m neem preparations seems to be a reasonable approach. 3.4. Formulation Some of the existing botamcals have been sold primarily m the form of dusts or powders, but these tend to be relatively inefficient with respect to delivery of toxlcant to the target pest and residual action on plant foliage More desirable, and more widely used, are emulsifiable concentrate (EC) formulations of botanicals. Most botamcals lend themselves well to the preparation of EC formulations. Because of then- moderate polarity, the technical grade extracts often dissolve readily m conventional alcohol-based carriers. There are also numerous conventional food-grade emulsifiers (e.g., ethoxylated glycerides or esters) that will produce stable aqueous emulsions of the dissolved extract. Compared to many synthetic msectlcides, the active principles m many botanical msectlcldes, mcludmg neem, tend to be very susceptible to photodegradation, and labile to oxldatlon m storage. To counter these deleterious actions, UV-absorbing adjuvants (i.e., sunscreens) and food-grade antloxldants
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can be added to the formulation, although then ability to protect the active ingredients should be determined empirically. Some actives may be sufficiently stable to allow the preparation of ready-to-use formulations, with or without a propellant, for use m the home and garden.
3.5. Applications The predominant botamcals m current use, namely pyrethrum and rotenone, enjoy widespread use, at least in part, because they are broad-spectrum msectictdes. Newer botanicals, including several under development, have more subtle and varied modes of action, functionmg as moltmg disruptants, proteinsynthesis mhtbitors, or inhibitors of other specific enzyme systems. In some cases, it 1slikely that several modes of action are possible for a single compound. In the field, neem acts as a crop protectant largely through tts action as an insect growth regulator, but suppression of feeding through the insect’s central nervous system and behavioral effects (deterrence of feedmg and oviposition), and reduced mobility or vigor, cannot be discounted in some applications. Neem is active against a wide array of pest spectes, including members of most of the economtcally important insect orders, but, like some other botamcals, has poor contact action and IS efficacious only when ingested by the target pest Another consequence of the anti-hormonal actton of azadirachtm can be reduced fecundity following ingestion of sublethal doses by either larvae (Leptdoptera) or adult insects (Coleoptera). Whtle the Impact of this effect may not be nnmediately apparent (I.e., within a growing season), It can contribute to long term populatton reduction of pests. Such an effect could be particularly important for multtvoltme species where latter generations are the most potentially damaging to the crop. Against certain pests such as aphids, efficacy IS influenced to a large degree by the host plant, presumably reflecting the relative systemic movement of azadnachtm m different crop species (26). Though the systemic action of neem has been demonstrated in some important crop species and even m certain tree species, it 1sdangerous to assume this applies to all plants. Empirical studies with specific crops are clearly warranted. Other botamcals under development are more selective in their efficacy; if commercrahzed they will have to be aimed at mche markets where they can compete with conventional products. For example, the thiophene a-terthienyl is extremely effective against mosquito larvae, but variable against plant-feedmg pests (27), gmkgohdes, msectictdal diterpenes from Ginkgo bzloba foliage are effective against planthoppers, but only weakly active against lepidopteran pests (9); and hmonm, an abundant triterpene from grapefruit seed is a potent antifeedant for the Colorado potato beetle Leptinotarsa decemlineata, but relatively ineffective against leptdopteran pests (28).
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Most botanical msecticides are relatively soft on nontarget arthropods, probably because they have to be Ingested to be effective (1.e , they lack contact toxtctty) and owing to their limited persistence on foliage. In particular, neem has been shown to have mmtmal impact on natural enemies of aphids (5) and predatory mites commerctally reared as biocontrol agents (29). Equally important, neem does not disrupt foraging by honeybees and other pollmators, nor does tt appear to pose a risk to bees (6,30). These properties suggest that neem insecticides will be quite compatible with integrated pest management in many crop ecosystems.Less is known regarding the effects of other botamcals under development on natural enemies and pollinators. If these products can be demonstrated to have reduced impact on nontargets, their attractiveness to growers will be enhanced. 4. Results 4.7. Recent Products Renewed interest m botanical msecticides is ostensibly a consequence of the recent mtroduction of neem into the market. The ortgrnal neem product, Margosan-OTM was introduced into the United Statesby W R. Grace (Columbra, MD) m 1990. Developed by Robert Larson of Vtkwood Botamcals (Sheboygan, WI) with the assrstanceof the U.S. Department of Agrtculture, tt consisted of an ethanol extract of ground neem seeds mixed with an emulsifier to a final concentratton of 0.3% azadtrachtm and approx 20% neem oil. This product contmues to be sold by Ringer (Mmneapolts, MN) under several trade names, including Safer Bto-Neem TM Margosan-0 was followed mto the marketplace by a range of products based on oil-free neem seed extracts, developed by AgrtDyne Technologies (Salt Lake City, UT) These products, contammg 3% azadnachtm as the active ingredient, mcluded AzatmTMfor nonfood crops and AhgnTM for food crops. Since 1992, several companies in India, as well as firms m Germany and Australia, have independently developed processes to obtain oil-free concentrated neem seed extracts m a dry form, typically contammg between 10 and 30% azadirachtm(s). From these technical grade extracts, EC formulations containing between 2 and 5% azadrrachtin can be readily prepared. ThermoTrrlogy (Columbia, MD) (having acquired both the Biopestictdes Division of W. R. Grace and AgriDyne Technologres) is currently marketing an oil-free neem msecticide contammg 4.5% azadtrachtm(s) under the name Neemtx 4.5TM Among other companies, Trifolio-M GmbH in Lahnau, Germany has developed products under the tradename of NeemAzalTM that are currently being sold m India, and for which regulatory approval in Germany is imminent. For-
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tune Btotech (Secunderabad, India) is pursuing registration of neem msectitides in the United States. Closely related to the Indian neem tree IS the chinaberry tree, Melza azedaruch (meliaceae). The seeds of this tree contam msectictdal constttuents from which a pest-control product can be prepared, but the seeds also contam meliatoxms, substancesthat are toxic to vertebrates (31). However, the bark of this tree and that of Melza toosendan (considered a race of A4. azedarach by some authors, a distinct species by others) contam hmonoid triterpenes that can be used to produce a botanical msecttcide (32). Such a product 1scurrently manufactured m the Peoples’ Repubhc of China, for use against frutt, nut, and vegetable pests. The active ingredient listed on the label is 0.5% toosendanm, but the commercial product is known to contain 0.1% of a synthetic pyrethroid or other conventional msecticide. Trials m North America using the Chinese product, and formulated bark extract alone, indicate that the latter has only limited efficacy as a stand-alone product, suggesting that the limonoids function primarily as a synergist to the small amount of synthetic insecticide m the commercial formulatton. 4.2. Botanicals Under Development Several other botanical materials have been the subject of considerable SCIentrfic investigation and could proceed to commerctal production if suitable parties m the private sector are prepared to shepherd them through the regulatory process. A number of these botamcals are reviewed elsewhere (2). Insecticides prepared from the seeds of soursop fruit (A muricata) and the twigs of the pawpaw tree (A tnloba) have been the subjects of U.S. patents (33,3#). In both cases, the active ingredients are annonaceous acetogenins. Field trrals demonstrate that plant extracts containing these compounds are effective against a wide range of insect and mite pests, and they act synergistttally when combined with pyrethrum or neem (35). In purity, the acetogenins show stgmficant mammalian toxicity, although some are particularly effective as antitumor agents. It can be argued that, as crude, complex mixtures in relatively low concentrations, annonaceous acetogenms could be effective for pest management without posmg appreciable risks to humans and wtldhfe, a situation not unlike that for pyrethrum and rotenone. Crude foliar extracts of iVicotiaaa gossez and related species, prepared by rinsing foliage with dichloromethane, are very effective for the control of soft-bodied arthropod pests (36). The active compounds m the extracts are sucrose esters having acyl substituents (Ct-ClO) on both the fructose and glucose moietres. However, commercial synthesis of these compounds is not economically feasible, and their recovery from Nicotmna foliage may not be, either.
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A standardized extract from seeds of Meha volkenm, a species native to East Africa and related to the neem tree, shows good potential for management of a number of pest insects, especially the yellow fever mosquito, Aedes aegyptz, and the desert locust, S. gregarza (37) Prehmmary results of laboratory and field trials m the United States suggest that this material could be efficacious againstagricultural pestsm temperatecountrtes,aswell (H. Fescemyer, personal communication) Other botanical preparations that have been touted for pest management include root extracts of marigolds (Tagetes spp), rich m throphenes, as a mosquito larvrcide (27), fohar extracts of G biloba for control of the brown planthopper on rice (9), limonin from grapefruit seeds for control of the Colorado potato beetle (38), and seed extracts of lupms (Lupznus spp), rich in qumohzidme alkaloids, which function as feeding deterrents and msecticides to a wade range of pests (39) 4.3. Future Trends With consumer and polmcal pressure for reductions m pesticide usage m agriculture and forestry, and increased awareness of the nontarget impacts of garden pesticides among homeowners, the prospectus for botanical msecticides 1sthe most favorable it has been for 50 yr. As we reach the mtllenmum, with proper marketing and continued refinement, we should see neem msecticides approach the current use levels of pyrethrum. Neem 1scurrently being evaluated as an alternative to synthetic pyrethroids for protection of cotton in China and Australia Cotton represents the largest single market sector for insecticides, so even modest successesm these trials could lead to an explosive Increase m the global demand for neem products. Increasing use of any new msecticide raises the specter of pest resistance In this regard, botanical materials consistmg of mixtures of active prmciples may have an advantage over conventional synthetic insecticides. Artificial selection experiments with diamondback moth larvae (Plutella xylostella) (40) and green peach aphid nymphs (A4 permae) (41) suggest that pest species cannot readily evolve resistance to neem-based msecticides, even though, m the same experiment, selection with pure azadirachtm led to the development of nmefold resistance to this natural product m the aphid. Other botamcal products, mcludmg some of those mentioned m this chapter, should reach the market for specialty uses; few of the products under development ~111have the widespread apphcabtlrty m agriculture and forestry that neem appears poised to attam. Also, botamcals should Increase their share m the home and garden (domestic) msecticide market, perhaps reaching 50% by volume in 1&15 yr. Up to the present, regulatory approval, designed around synthetic pestictdes, has constituted a barrier to the introduction of new botamcals, primarily because
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botamcals usually consists of complex mixtures of active ingredients, and can have more than one mode of action in pests. However, there IS evidence that regulatory authorities, having gamed experience with botanicals through evaluatton of neem insecticides, are likely to look more favorably on these alternative products, with procedures aimed at moving new products into the marketplace with fewer impediments.
References 1 Isman, M B (1994) Botanical msecticides Pestzczde Outlook 5, 26-3 1 2 Isman, M B (1995) Leads and prospects for the development of new botanical msecticides Rev Pestle Toxzcol 3, l-20 3 Isman, M B (1997) Neem and other botamcal msecticides barriers to commercialization Phytoparasltzca 25, 339-344. 4 Schmutterer, H , ed (1995) The Neem Tree VCH, Wemheim, Germany 5 Lowery, D. T and Isman, M. B (1995) Toxictty of neem to natmal enemies of aphtds Phytoparasltzca 23,297-306 6. Naumann, K and Isman, M B. (1996) Toxicity of neem (Azadwachta wzdrca A Juss) seed extracts to larval honeybees and estimation of dangeis from field appllcations Am Bee J 136,5 18-520 7 van Beek, T A and de Groot, A (1986) Terpenoid antifeedants Part I An overview of terpenoid antifeedants of natural origm Recued des Travaux ChzmlqueF des Pays-Bas 105,5 13-527 8 O’Reilly, J (1993) Gznkgo bzloba-cultivation, extraction and therapeutic use of the extract, m Phytochemlstry and Agrzculture (van Beek, T. A and Bretelei, H , eds ), Clarendon, Oxford, pp 253-270 9 Ahn, Y J , Kwon, M , Park, H. M , and Han, C G (1997) Potent msectictdal activity of Ginkgo bzloba derived trilactone terpenes against Ndaparvata lugens, m Phytochemzcalsfor Pest Control (Hedin, P A , Hollmgworth, R M , Masler, E P , Miyamoto, J., and Thompson, D G , eds.), American Chemical Society, Washmgton, DC, pp 90-105. 10 Ratnayake, S , Rupprecht, J K , Potter, W. M , and McLaughlm, J L (1991) Evaluation of the pawpaw tree, Aszmznu trlloba (Annonaceae), as a commercial source of the pesticidal annonaceous acetogenms, m New Crops (Jamck, J and Simon, J E , eds.), Wiley, New York, pp. 644-648 11 Marr, K L and Tang, C. S. (1992) Volatile insecttcidal compounds and chemical variabihty of Hawaiian Zanthoxylum (Rutaceae) species Bzochem Syst Ecol 20, 209-217 12 Satasook, C , Isman, M B , Ishibashi, F , Medbury, S , Wniyachitra, P., and Towers, G H N (1994) Insecticidal bioactivity of crude extracts of Aglaza species (Mehaceae) Bzochem Syst Ecol 22, 121-127 13. RaJasekaran, T , Perena, J , Ravishankar, G A., and Venkataraman, L V (1996) Repellency of callus derived pyrethrins to mosquito Culex qurnquefasclatus Say and red flour beetle Trlbollum castaneum Herbst Int Pest Control 38, 155-159
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14 Morgan, E. D., van der Esch, S A., Jarvts, A P , Macctom, O., Gtagnacovo, G , and Vttale, F (1996) Productton of natural msecttctdes from Azadzrachta spectes by tissue culture. Abstract, International Neem Conference, Lawes, Australia. 15. Khambay, B P. S. and O’Connor, N (1993) Progress m developmg msecttcides from natural compounds, in Phytochemzstry and Agrzculture (van Beek, T A and Breteler, H , eds ), Clarendon, Oxford, pp 40-61 16 Sharma, R N (1984) Development of pest control agents from plants a comprehenstve workmg strategy, m Natural Pesticides from the Neem Tree and Other Tropical Plants (Schmutterer, H and Ascher, K R S , eds ), GTZ, Eschbom, pp 55 l-563 17 Escoubas, P., LaJide, L , and Mizutam, J (1994) Insecttctdal and anttfeedant activtttes of plant compounds. potenttal leads for novel pesttctdes, m Natural and Engineered Pest Management Agents (Hedm, P. A., Menn, J. J., and Hollmgworth, R M , eds ), American Chemical Society, Washmgton, DC, pp 162-l 7 1 18 Alkofahl, A., Rupprecht, J. K., Anderson, J E., McLaughlin, J L , MikolaJczak, K L , and Scott, B. A (1989) Search for new pesttctdes from higher plants, m Insectwdes of Plant Orrgrn (Amason, J T , Phllogene, B J R , and Morand, P , eds.), American Chemical Society, Washmgton, DC, pp 2543 19. Cepleanu, F , Hamburger, M 0 , Sordat, B , Msontht, J D , Gupta, M P , Saadou, M , and Hostettman, K (1994) Screening of troptcal medtcmal plants for mollusctctdal, larvtctdal, fungtcidal and cytotoxic activities and brme shrtmp toxtctty Int J Pharmacog 32,294-307. 20. Bomford, M. K and Isman, M. B. (1996) Desensmzatton of fifth mstar Spodoptera lztura (Lepidoptera. Noctutdae) to azadtrachtm and neem Entomol Exp Appl 81,307-313 21 Isman, M. B. (1993) Growth mhtbttory and anttfeedant effects of azadtrachtm on SIX noctutds of regtonal economic tmportance Pestlclde Scl 38,57--63 22. Champagne, D. E., Isman, M B , and Towers, G. H. N (1989) Insectictdal acttvtty of phytochemicals and extracts of the Mehaceae, m Insectzczdes of Plant Ongzn (Arnason, J. T., Phtlogene, B. J. R., and Morand, P., eds.), Amertcan Chemical Society, Washington, DC, pp 95-109 23 Lowery, D. T and Isman, M B. (1993) Antifeedant acttvity of extracts from neem, Azadwachta mdlca, to strawberry aphtd, Chaetoslphon fragaefolu J Chem Ecol 19, 1761-1773. 24. Isman, M B , Proksch, P , and Yan, J -W. (1987) Insecttctdal chromenes from the Asteraceae: structure-activity relattons. Entomol Exp Appl 43,87-93 25. Sims, M. (1981) Ltqutd carbon dioxide extraction of pyrethrins US Patent No 4,281,171 26 Lowery, D. T and Isman, M B (1994) Insect growth regulatmg effects of neem extract and azadtrachtm on aphids Entomol Exp Appl 72, 77-84 27. Amason, J. T., Phtlogene, B. J. R , Morand, P., Imne, K., Iyengar, S., Duval, F., et al (1989) Naturally occurrmg and synthetic thiophenes as photoactivated msecttctdes, m Znsectzcides of Plant Orzgzn (Amason, J T , Phtlogene, B J R , and Morand, P , eds ), American Chemical Soctety, Washmgton, DC, pp, 164-l 72
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28. Mendel, M J., Alford, A. R., and Bentley, M. D. (1991) A comparison of the effects of hmonm on Colorado potato beetle, Leptrnotarsa decemltneata, and fall armyworm, Spodoptera frugtperda, larval feeding. Entomol Exp. Appl 58, 191-194. 29. Spollen, K. M. and Isman, M. B. (1996) Acute and sublethal effects of a neem msecticide on the commercial biocontrol agents Phytosetulus perstmtlts and Amblysetus cucumerts (Acari Phytoseiidae), and Aphzdoletes aphtdtmyza (Rondam) (Diptera. Cecidomyiidae) J. Econ. Entomol 89, 1379-1386 30 Naumann, K , Currie, R. W , and Isman, M. B. (1994) Evaluation of the repellent effects of a neem msecticide on foraging honey bees and other pollinators Can Entomol 126,225-230. 3 1 Ascher, K R S , Schmutterer, H., Zebitz, C. P. W., and Naqvi, S. N H (1995) The Persian lilac or chmaberry tree: Melta azedarach L , m The Neem Tree (Schmutterer, H , ed ), VCH, Wemheim, pp. 605-642 32 Chiu, S -F. (1995) Melra toosendan Sieb. & Zucc., m The Neem Tree (Schmutterer, H , ed), VCH, Weinheim, pp. 642-646. 33. Moeschler, H. F., Pfuger, W., and Wendlisch, D. (1987) Pure annonm and a process for the preparation thereof. US Patent No. 4,689,323 34 MikolaJczak, K L , McLaughlin, J. L., and Rupprecht, J. K. (1988) Control of pests with annonaceous acetogenins. US Patent No. 4,721,727. 35. McLaughlin, J. L., Zeng, L , Oberlies, N H , Alfonso, D , Johnson, H A , and Cummings, B. A. (1997) Annonaceous acetogenms as new natural pesticides. recent progress, m Phytochemicals For Pest Control (Hedm, P. A., Hollingworth, R. M , Masler, E. P , Miyamoto, J , and Thompson, D G , eds ), American Chemical Society, Washmgton, DC, pp. 117-133. 36. Pittarelh, G W , Buta, J. G., Neal, J W , Jr., Lusby, W. R., and Waters, R M (1993) Biological pesticide derived from Nicottana plants US Patent No. 5,260,28 1 37 Rembold, H and Mwangi, R W. (1995) Melta volkensu Gurke, m The Neem Tree (Schmutterer, H., ed ), VCH, Wemheim, Germany, pp. 647-652. 38. Murray, K. D., Alford, A. R., Groden, E., Drummond, F. A., Starch, R H., Bentley, M. D., and Sugathapala, P. M. (1993) Interactive effects of an antifeedant used with Bacrllus thurmgtensu var. san dtego delta endotoxm on Colorado potato beetle (Coleoptera: Chrysomehdae). J Econ Entomol 86, 1793-l 801 39. Wink, M. (1993) Production and application of phytochemicals from an agricultural perspective, m Phytochemtcals and Agrtculture (van Beek, T A. and Breteler, H , eds ), Clarendon, Oxford, pp 171-213. 40 Vollinger, M. (1995) Studies of the probability of development of resistance of Plutella xylostella to neem products, m The Neem Tree (Schmutterer, H., ed ), VCH, Wemhelm, Germany, pp. 477483 41. Feng, R. and Isman, M. B. (1995) Selection for resistance to azadnachtm m the green peach aphid, Myzus perstcae Expertentta 51,83 l-833
10 Commercial
Experience
with Neem Products
James F. Walter 1. Introduction The agricultural mdustry of the 1990s IS challenged to find new methods and materials for controllmg pests and diseases. New legtslatton, mcludmg the 1996 Food Quality Protection Act, Worker Protection Standard, and Pesttctde Reregtstratton, are limiting the avatlabtltty of traditional chemical pesticides. Governmental policies committed to the institution of integrated pest management (IPM) programs, the mcreasmg resistance developed by msects and pathogens to chemical pesticides, and the public concern about chemicals m general has u-utiated a re-evaluation of pesticide use. increasingly, farmers m developed and developing nations are looking toward the use of natural materials as pest-control agents (I). Neem-based msectlcldes containing azadtrachtm address these concerns. The insect-growth regulator (IGR), azadtrachtm, affects over 300 species of Insects, including such important pests as armyworms, leafmmers, aphids, whiteflies, psyllids, and numerous other insect pests (2). In addition to controllmg these pests, many azadirachtm-based msecttcides have negligible effect on natural beneficial insects, and low environmental impact (3). These properties make azadlrachtm a sensible material to use m most pest-management programs. However, significant manufacturing, regulatory, and application problems had to be solved before azadxachtin could be brought to the market. Since then mtroduction mto the agricultural market m the United States m 1993, azadirachtmbased pesticides are fast becoming an important tool in crop protection, although the total amount of azadirachtm sold 1smuch less than 1% of all Insecticides sold.
From Methods in Blofechnology, vol 5 B/opestmdes Use and Delwery Edlted by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
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156
Walter
2. Where Does Azadirachtin Come From? Extracts and parts from the neem tree have been used for centuries to control numerous insect pests and diseases,and as a therapeutic substance The neem tree, or Azadzrachta zndzca (A. Juss), 1sa member of the mahogany family (4). The trees are a hardy, broad-leaved evergreen that can reach heights of 100 ft It grows prlmarlly m tropical regions where the rainfall 1slOOO mL/kg for red-winged blackbirds. But Sharma et al. (9) report that the acute oral LD,, for neem seed 0111s 39.9 mL/kg for chickens. Larson (6) reports the LDsO for the commercial product Margosan-0 (Vlkwood Botamcals, Sheboygan, WI) 1s>I 6 mL/kg for mallard ducks. &mllarly, Chopra (10) reports that neem-seed 011produced occasional diarrhea,
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nausea, and general discomfort when given orally to human adults. A 4-mo-old infant died after being administered 12 mL of neem oil for a cough (II). Yet neem oil is commonly used as an oral medication in India, and oral doses of neem as high as 6 mL/kg caused no mortality in female albino rabbits (22), Margosan-0 produced no mortality for rats when fed at a rate of 5 g/kg (10) These reports mdicate that the toxicity and chemical composition of neem extracts can vary significantly. This makes the comparison of different extracts difficult. Although azadirachtin has been identified as a key mgredient, neem extracts can contain dozens of other extractable materials that can influence the toxicity and efficacy of the extract. In particular, aflatoxms have been identified as a potentially toxic contaminant of neem extracts. Other limenotds include such compounds as salannm, mmbandiol, nimbm, and deacetyl mmbinbandiol, all of which have insecticidal activity. This has created confusion in the literature and led to unsubstantiated claims regarding azaduachtin. In order for a product to be registered and suitable for use m developed countries, a consistent,reliable, efficacious product had to be developed. The development of neem msecticides was expensive and drawn out, and took many years of development. 3. The History of the Commercialization of Azadirachtin-Based Pesticides in the United States The development and commercialization of refined azadirachtm-based msecticides has been spearheadedby two companies m the United States.This is somewhat ironic, since there is very little neem grown in the United States,and the regulatory environment in the United States is very strict. However, these two factors probably stimulated the development of efficient, consistent, azaduachtm extraction techniques. The history of azadnachtm-basedmsecticides m the United Statesis very convoluted, with several parties changing hands and products changing names, and constant improvements m technology. The first commercial use of an azadnachtm-basedpesticide for nonfood use was approved by the U.S. Environmental Protection Agency (EPA) in 1985. Vikwood Botamcals, owned by Robert Larsen, introduced Margosan-0 for use on trees and shrubs to control leafmmers and gypsy moths. This product was developed m part with the assistance of the United States Department of Agriculture (USDA) m Beltsville, MD, and was tested throughout the world Margosan-0 contamed an ethanohc extract of neem seedswith 0.3% azadirachtin (6). However, because of manufacturing and formulation problems, Margosan-0 production was limited to sample quantities, and, although it became an academic international standard, it had little commercial impact. In 1988, W R. Grace (New York, NY) purchased the patent, registration, and technology for Margosan-0 from Larson. Over the next several years, Grace improved the manufacturing and formulation technology for azadnachtin, which resulted in a much more consistent product.
158
Walter
In 1990, Grace changed the formulatton of Margosan-0, reducmg the active content to 0.25%, expanded the registration to include several important insect pests, mcludmg whiteflies, aphids, and armyworms, and expanded its use to include the greenhouse and mteriorscape environments Working through its partially owned subsidiary, Grace/Sierra Horticultural Products, Grace mtroduced Margosan-0 m the greenhouse/nursery mdustry (14). Margosan-0 had a caution label and no specific handling requirements Sales of Margosan-0 were primarily targeted to the control of whiteflies on pomsetttas and other ornamental crops, and the product successfully established the commercial viability of azadtrachtm-based insecticides. In 1992, Agrtdyne Technologies (Salt Lake City, UT) received registration for, and introduced, Azatm to the greenhouse market and Turfplex to the lawn care Industry Both Azatm and Turfplex contamed 3% azadn-achtm m a naphalene solvent, and carried a warning label. Azatm made inroads mto the greenhouse market because of its higher concentration and price position, but sales of Turfplex were weak and the product was dropped after a few seasons. Grace introduced the product Bioneem (0 09% azad), through Ringer, for the consumer pesticides market. Because of their nontoxic mode of action on insects and then inherent low toxictty, the EPA has created rational guidelmes for the registration of neembased msecttcides In 1993, the EPA granted an exemption of tolerance for using azadn-achtm on all food crops at ~20 g azadirachtm/acre. Grace received approval for, and Introduced, Neemix (0 25% azadirachtin) for use on food crops. Inmal sales efforts were targeted on vegetables m Florida. Simultaneously, Grace, m collaboration with an Indian partner, started up the world’s largest azadirachtm plant m Tumkur, India (15, Neemtx found good acceptance m the citrus and vegetable markets for control of such pests as armyworms, leafmmers, and aphids. In 1994, Grace received registration for a 4.5% azadirachtm formulation, and introduced Neemix 4.5 to the agricultural market The 4.5% formulatton, being 18 times more concentrated than the 0.25%, reduced the difficulty of handling large volumes of material and simplified package dtsposal. Also m 1994, Grace sold Grace/Sierra Horticultural Products to the Scotts Company (Marysville, OH). Grace retained ownership of the biopesticide business, but Margosan-0 was renamed Neemazad. In March 1996, AgrtDyne Technologies was sold to Biosys of Columbia, MD. Biosys is a nematode and pheromone producer, and this acquismon was seen as a strategic fit In May 1996, while divesting itself of noncore businesses, Grace sold its biopesticide busmess to Therm0 Ecotek, which formed a new company, ThermoTrdogy (Columbia, MD), to market and develop these biopesticides (16). In September 1996, Biosys filed for bankruptcy (17) In
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January 1997, ThermoTrilogy bought the assetsof Biosys out of bankruptcy, and thus became the sole producer and supplier of azadrrachtm m the United States.With the acquisition of the Biosys assets,ThermoTrilogy has become a much more dtversrfied bropesticide company. It is drffrcult to predict rf azadirachtm will remam a focus of the company. 4. Development of Azadirachtin-Based Insecticides Outside of the United States Outside of the United States, India is the largest user of azadn-achtm-based msecticrdes. Because of familiarity and a captive supply, companies in India have produced and distributed for many years neem-based pesticides that claimed to contain azadirachtin. Various manufacturers, including West Coast Herbochem (Neemark) and Godrej Soaps (Neemacure), produced neem-oilbased pesticides that were unregistered and did not specify an azadirachtm content, because no formal registration system had been established. In 1993, the government of India formalized the registration process for neem-based msecticides. They created a registration system, unique to India, based on the azadirachtm content of the product. Crude neem-oil-based formulations are required to contam 0.0 15% azadirachtm More refined extracts were allowed to contam 0.15,0.3, 1,2, or 5% azadirachtin. Acute toxicity and chemical testmg is required for all formulations. Many small companies entered the market with oil-based azadirachtm formulations. The overall quality and effectiveness of these products has been rather mconsistent, because of variabilmes m oil quality. Several large Indian companies have entered the azadirachtm pesticide market with higher-concentration, and higher-quality, products, mcludmg Spit (Neem Gold), E.I.D. Parries (Neemazal) and MargoBrocontrols (Econeem). Most of the azadirachtm-based pesticides produced m India are used on three mam crops: tea, cotton, and vegetables (28). Other than m the United States and India, the use of azadu-achtm-based msecticides is sparse, but the approval of new registrations in many countries may change this situation. Registration for neem-based pesticides manufactured by ThermoTrilogy or Biosys have been approved m Saudi Arabia, Taiwan, Israel, Spain, Chile, Mexico, Nicaragua, Costa Rtca, and Ecuador A German company, Trrfoho, has received registration of an azadirachtm-based msecticide (Neemazal) in Switzerland, and has applied for registration m Germany. Despite the great amount of fundamental research conducted on azadirachtm m Europe, only recently has azadirachtm been registered m a few countries there. These new registrations should allow for the expanded use of azadn-achtm (19). Along with the registered uses for azadirachtm, there are several countries where azadirachtin is used without formal registrations Australia and Indone-
760
Walter
sta have several plantings of neem, and mdrviduals have been sellmg unregistered azadu-achtm-based msecticides for a number of years. Although most of the products are used as mosqmto repellents or cures for head lice, some have been used on food crops. Development projects in Kenya, Senegal, Thailand, Nicaragua, Phihppmes, Ham, and other countries, supported by European or American governments, have started up rudimentary neem extraction plants or tramed local farmers to produce neem-based msecticides (18). The exact amount of azadnachtm used at this level is unmonitored, and, thus, it IS difficult to estimate the true extent to which neem is used. 5. How Does Azadirachtin Work? The primary active ingredient m most neem pesticides ISa compound called azadnachtm. Although neem extracts can, and usually do, contain other compounds that can control insects or influence the activity of azadnachtm, neem pesticides generally only specify their azadtrachtm content. Azadtrachtm is a hmmotd or, more spectfically, a tretranor triterpenoid with great msecttctdal activity. Azadnachtm 1schemically very complicated and has not been chemically synthesized. Azadirachtm has numerous effects on msects; however, Its major modes of actton are that of a powerful IGR, a feedmg deterrent, and an oviposttion deterrent. These three modes of action give azadu-achtm unique properties that make it very useful m today’s agricultural mdustry. Most farmers are not familiar with these modes of action, and need to understand them, so that they will know what to expect when they use the product. The most pronounced mode of action of azadirachtm is as an IGR. IGRs effect the hormonal system of insects, preventmg them from developmg normally mto mature insects. However, thts IGR property will not cause the immediate death of the insect pests Azadnachtin is structurally similar to the natural insect hormone ecdysone. Ecdysone regulates the development of insects, and any disruptton m its balance will cause improper development, Azadnachtm interferes with the production and reception of this msect hormone durmg an insect’s growth and molting. Thus, m thts manner, azadirachtm blocks the molting cycle, causing the msect to die (20). Because of its IGR effect, azadirachtin does not immediately kill msects and does not ktll adult insects. Immature insects die durmg their development, thereby reducmg the overall populatton over a period of time. The length of time depends mostly on the species of insect, age of insect, and the size of the population. Mortality can be seen m as little as l-2 d, to as long as a few weeks. Azadirachtm has its greatest effect on the early mstars. However, azadnachtin has effects on the emergence of pupae of some insects. It has been observed that the pupae of the leafmmer Liromyria trzfolia (21) and the frutt fly Ceratztls capztata (22), treated with azadnachtm, die before they emerge as
Commercial Experience with Neem Products
167
Table 1 Control of Beetarmy Worm (BAW), Cabbage Looper (LOOPER), and Diamond Back Moth (DBM) on Broccoflower in Oxnard, CA Treatment
Rate (per acre)
BAW
Average number Loopers
Untreated Xentari Neernlx Asana
1 lb 0.5 gal 9 6 oz
0 67 A 0.47 AB 0.83 A 023 B
09A 0.73 A 0.90 A 03B
DBM 0.47 0 23 0 37 0 07
A B A c
Plant damage P-3 45A 31A 1.2 B 08B
Three treatments made weekly at 100 gal/acre and evaluated after the third treatment Treatments followed by the same letter do not slgmficantly differ (P = 0 05 Duncan’sMRT)
adults. This variability in the expression of the activity of azadrrachtm can confuse farmers. Many IGRs have the drawback that they do not immediately kill the pest insect, thus leaving the insect to further damage the plant until it succumbs to the IGR. However, m the case of azadirachtm, the additional modes of actlon help protect the plants from damage while the IGR works on the insect Many insects exposed to azadlrachtm will stop feeding shortly after exposure. This, m effect, ends the damage to the plant, even though the insect larvae are still present This effect 1sexperienced m the field, where insect counts may not be significantly reduced, but plant damage is not occurring. In field trials conducted in California, the author has noted that broccoflower treated with Neemlx had amounts of worms present equivalent to the untreated control. But the damage caused to the plant was significantly reduced in the Neemlx-treated plots, and similar to that observed in plots treated with conventional msecticldes (Table 1). This mode of action complicates scouting, because insect counts are not totally representative of potential damage. 6. Formulation Effects Currently, m the United States, at least four different formulations contaming azadirachtin are registered for commercial use. They vary in active ingredient content, manufacturing process, as well as formulation components. ThermoTrilogy produces three azadirachtin forrnulatlons, including BloNeemT”, containing 0.09% azadirachtm m an alcohol base and supplied to the homeowner market. NeemixBTM and NeemazadBTM,contammg 0.25% azadlrachtm m an alcoholic base with 5% neem 011,are supplied to the agricultural and greenhouse markets, respectively. Neemlx and Neemazad were previously called Margosan-0. Neemix 4.5 and Neemazad 4.5, contaming 4.5% azadn-achtm m an acetate base, are marketed m the agricultural and greenhouse markets, respectively. Biosys produces Azatm and Align, which contam 3% azadlrachtm
Walter
162 Table 2 Final Population Density of A. pisum Exposed to Broad Beans Treated with Several Neem Insecticides at Equivalent Rate of 100 mg of Azadirachtin/L No. aphids Control
Azatm
Neemix
RH-9999
1392.25 A
654 B
232 C
1378 5 A
Table 3 Toxicity of Neem Insecticides to Immature A. pisum Exposed as First lnstars to Neem Insecticides at 100 mg of AzadirachtML Control
Azatm
Neemlx
RH-9999
2oc
68 0 B
90.0 A
80C
Means followed by same letter are not stgnlficantly different Based on five rephcates m a naphthalene base. Azatm is supplied to the greenhouse trade, and Align 1s supplied to the agricultural trade. Despite the fact that all these products contain azadlrachtin, which has little mammalian toxicity, the different mert Ingredients create products that have different levels of toxicity and may not perform similarly. Wan et al. (23) has recently shown that the naphthalene carrier m Azatm makes It 10 times more toxic to Juvenile salmon than is Neemix (Margosan-0). Formulation differences also impact the ability of these materials to control insects. Stark and Walter (24) demonstrated that three different azadlrachtm contaming formulations, when applied at the same rate of azadlrachtm, showed very different ablhtles to control the pea aphid, Acyrthoszphonpzssum (Harris). In these tests, they examined the effects of Neemlx (Margosan-0), Azatm, and an experimental formulation RH-9999 (Rohm and Hass, Phlladelphla, PA) on the pea aphid on broad beans. Trials conducted on mixed-age populations, as well as first mstar nymphs, showed that, when applied at equal rates of azadlrachtm, Neemlx was statistically more effective than the other materials, and RH-9999 had little effect (Tables 2 and 3). Slmllar results were reported by Eckberg et al (25), who noted that Neemlx (Margosan-0), used at a low rate, killed forest tent caterpillars, Mulacosoma disstria, more quickly than Azatzn at a much higher rate (Table 4). Further analysis conducted by Stark and Walter (26) suggests that the presence of llmmlods other than azadlrachtin, present m Neemlx, including
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Table 4 Effect of Azatin EC and Neemix (Margosan-0) on Mortality of Forest Tent Caterpillars % Mortahtv Treatment Untreated Azatin Neemlx
Rate 50 PPM 125PPM
7 DAT
11 DAT
15 DAT
19 DAT
24 DAT
OOA OOA 160A
OOB 10.5 B 61 3A
40B 30.0 B 68.0 A
80B 70 0 A 82.0 A
380B 86 0 A 90 0 A
Fourth mstar larvae were placed m a Petri dish with ash leaves treated with the products for 6 d Then the treated leaves were replaced with untreated leaves Numbers within a column followed by the same letter are not slgmficantly different (P = 0.05) by SNK
Table 5 Effect of Removing Neem Oil Components from Neemix and Adding to Aratin and RH-9999 No aphids Control 1437.75 A
Azatm
Azatm + 011
RH-999
RH-9999 + 011
625.25 C
281.75 D
1416.0 A
810.0 B
Means followed by same letter are not slgmficantly different Population density of,4 p~sumexposed to several neem msectlcldes at 100 mg of azadlrachtmil
mmbandlol, deacetylsalanmn, deacetylnimbin, mmbm, 6-acetylnimbandtol, and salanmn, and the or1component, are responsible for the enhanced acttvity of Neemtx. These hmmotds have little or no msecttcldal of then own at the levels present, but appear to strmulate the activity of azadnachtin Removal of these components from Neemrx reduces its activity, but then addition to the other azadnachtm formulattons Increased the activity of azatm and RH-9999 (Table 5). This 1sfurther amplified by the fact that recommended apphcation rates for azatm (S-21 oz/lOO gal, equivalent to 8-18 g azadtrachtm/lOO gal) are roughly 3 ttmes higher than those recommended for Neemtx (2.5-5 pt/ 100 gal equivalent to 2.8-5.6 g azadirachtin/lOO gal). Thus, azadtrachtm-based msecttctdes cannot be compared solely on this azadirachtin content. Other factors Influence the acttvlty of azadirachtin. 7. Adjuvant
Effects
An adjuvant is used to aid the operatton or improve the effectiveness of a pesticide. The term mcludes such matertals as wetting agents, spreaders, emulsifiers, dispersing agents, and penetrants. These materials are commonly used
Walter
164 Table 6 Effect of Adjuvants on Control of Greenhouse Whitefly on Tomato Treatment Untreated Neemlx Neemlx + Bond Neemlx + Plyac Neemlx + Intact Neemlx + Kmetlc Neemlx + Sllwet Neemlx + Soydex Neemlx + Dynamic Neemix + Joint venture
by Neemix
Adluvant rate
% Mortahty 19 35 A
002% 002% 025% 0.02% 0.03% 025% 025%
05%
3288 B 4078 B 37 1B 5007c 5321C 7452 CD
92.11 D 83 02 D
91 27D
Mortahty of first mstarnymphsexposedto Neemtxat a rateof 0 5 gal/100gals (5 ppmazadlrachtm) Meansm the samecolumnfollowedby the sameletterare statlstlcallyequal, P=OO5
to enhance the performance of conventional pestlcldes. Although azadirachtm works differently from conventional pesticides, because of its broad spectrum of activity, many applications of azadirachtin can benefit from the addition of adJuvants. As with most pesticides, getting the material to the pest 1s of utmost importance Although azadirachtm has some systemic propertles and will translocate across the leaf cuticle (26), it does not effectively move from leaf to leaf The use of spreading agents has been shown to improve coverage and enhance the activity of azadlrachtin m the laboratory and m the field. Laboratory trials conducted on greenhouse whitefly (Trraleurodes vaporariorum) indicate that not all adjuvants mfluence azadlrachtin similarly. In these trials, tomato plants were introduced into a greenhouse whitefly colony and the adults were allowed to lay eggs. The plants were then removed and sprayed with solutions of Neemlx (0.5 gal/l00 gal) containing various adJuvants. Seven d later, the mortality of the immature nymphs was evaluated. The results presented m Table 6 indicate that most of the adJuvants Improved the performance of Neemlx, but the adJuvants contammg vegetable or mineral 011 (Joint Venture and Soydex) gave the most significant improvement. Field tnals conducted m Florida show that the addition of Joint Venture to Neemlx 4.5 improved whitefly control (Table 7). Other effects have been noted with other adjuvants. For instance, the addltlon of Cell-u-wet dramatically improved the efficacy of Neemix to control pepper weevil damage, but did not Improve the control of armyworm m field
Commercial
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Products
Table 7 Control of Silver Leaf White Fly on Tomatoes with Neemix and Joint Venture No dead nymphs/leaf Treatment Neemlx Neemlx + Joint venture
Thiodan + Ambush + Soydex
Rate/acre
ODAT
4DAT
0.5 gal
0 05 0 05 0.12
0.14 0.37 0 10
0 5 gal + 0.25 gal
1 qt + 8 02 +1 qt
lIDAT 0 02 0 50 0 06
18DAT 0 25 1 10 0 32
Treatments applied on d 0,8, and 15 at 100 gal/acre. Evaluations made on d 0,4, 11, and 18.
Table 8 Effect of Additives on Control of Rosy Apple and Green Peach Aphids at Two Locations (Sebastopol, CA and Graton, CA) Treatment
Untreated M-Pede Stylet 011 Neemix Neemlx + Stylet oil Neemlx + M-Pede
Sebastopol
Graton
Rate/acre
Damaged shoots
Infested shoots
2 gal 2 gal 0 5 gal 0.5 gal + 2 gal 0.5 gal + 2 gal
1005 7 65 8 65 65 3 30
6.25 A 3.17 AB 2.75 B 358AB 0.5 B 3 17AB
Apphcatlons apphed 3 times, 10-14 d apart, at 100 gal/acre The Sebastopol trial was evalu-
ated for damaged shoots and the Graton trial for infested shoots trials m Florida.
This result 1s sigmficant,
because Neemrx
does not ktll the
adult pepper weevil, but in some way deters their ovipositton on the fruit. The addmon of spreading agents that slow the rate of drying, such as Cell-u-wet, enhances this activity. In field trials in California, the addition of materials like Stylet 011 and M-Pede
improved
the control
of aphids by Neemlx.
In these
trials, apple trees infested wtth aphids were sprayed 3 times over a 1mo period, and then evaluated for aphid damage. Four replications were included per treatment. In one trial, the addition of Stylet oil at 2% dramatically improved the performance of Neemtx, and, m another case, M-Pede provided a stmilar response (Table 8). Both M-pede and Stylet 011have some insecticidal activtty on their own, but the combinatton with Neemix IS much more effective. All of these trials indicate that, for some pests, the addmon of adjuvants that increase coverage and delay drying of the application, enhance the activtty of Neemix.
Mixtures of azadn-achtmwith other pesticides often show an apparent synergy.
Walter
166
Table 9 Neemix Has Been Found to Have Little or No impact on the Following Beneficial Organisms When Used According to Label Directions General beneficial organisms
General insect predators and parasites Delphastus pusdlus Scymnus sp
Honeybee worker adults (Apes melllfera) Spiders (Lycosa pseudoannolata, Chwoanthlum
mzldzz)
Nematodes (Steznernema, Heterobdztus) Lady beetles (Cocclnellldae, Hlppodamla
Phytosendus persrmllus Lyslphlebus tesacelpes
convergens)
Earthworms (Elsema foetlda) Nonorlbated mites Sprmgtalls (Collembola) Ground beetles (Carabtdae) Rove beetles (Staphylrnldae)
Aphelznus asychzs Eretmocerus callfornlus Encarsla formosa Pysttalla lnclsls Encarsla translena
Clearly, the influence of extractton processes,formulation solvents, and even formulation adjuvants can make the comparison of neem-based msecttctdes difficult, tf not imposstble. Although researchers and manufacturers have tried to use azadtrachtm as a marker mdtcattve of a product pesticide acttvtty, practical experience indicates that this has been unsuccessful. Farmers and other applicators must rely on the manufacturer’s recommendatton and data developed by local extension agents when selecting application rates and adjuvants for controllmg specific pests. The lack of a true standard of acttvtty for neem extracts is a clear difficulty m the commerctahzatton of neem Substandard or degraded products have too often left farmers with the impression that neem products are not effective. However, with high-quality products and the proper use of adjuvants, these impressions can be overcome In the United States market, because of the presence of only two neem suppliers, confuston is somewhat limited But m the world market, the differences m neem pesticides are not well understood and are a major obstacle to the acceptance of neem msecttcides 9. Use of Neemix
with Beneficial
Insects
Neem pesticides, and, m particular, Neemtx, are an excellent choice of materials to use when the preservation of beneficial msects 1s important In both laboratory and field tests,Neemtx was found to have little or no effect on benefictals, such as spiders, lady beetles, parasitic wasps, and predatory mites (27,28). Table 9 presents a list of beneficial
insects compatible
with Neemlx.
Azadnachtin has also been demonstrated not to reduce honeybee pollmatton m the field, nor to effect worker bees through direct contact sprays In fact, recent
Commercial Experience with Neem Products
167
work suggests that the consumption of Neemix can actually be beneficial to bees through the control of Chaulk brood and Varoa mites (29). In laboratory testsperformed on aphid parasites,it was found that, even after four applications of azadirachtin, the wasps inside the parasitized aphids exposed to the azadirachtm emerged m equal numbers to the untreated aphids (30). In other studies, Neemix did not significantly affect lady beetles or parasitism by P jlavzpes. The compatibility of neem with beneficial insects IS especially important because of today’s expanding IPM programs. Neemtx’s low impact on beneficials allows it to be used m conjunction with these predators and parasitoids with little worry about the effect rt ~111have on them. This strategy of combmmg Neemix with beneficial insects has been used successfully m the field to control insect pests. Pepper growers in Florrda have learned thts by using Neemix early in the seasonto control armyworms and aphids and protect beneficial insects. The loss of beneficial msectscaused by the use of mcompatible msecticides causes secondary pests to multiply unchecked, and typically result in late seasoncontrol problems. The use of Neemrx preserves the natural balance of beneficial insects, and thus ehmmates the need for additional pesticrde apphcattons, whrch ultrmately saves the grower money (31). It has been speculated that the msensmvity of beneficial insects to Neem extracts, m general, 1sbecause neem products must be ingested to be effective Thus, insects that feed on plant tissues will be effected by the extracts, but those that feed on nectar or other insectsrarely contact lethal concentrates (32). This is clearly not the case, because bees can be fed concentrations of Neemix m a sugar solution that would kill whiteflies or other insect pests (29). Beneficial insects m some way have a defense mechanism agamst azadnachtm, probably because of a different evolutionary history of carnivores and herbivores. 10. Summary Researchers have for years extolled the potential of using azadirachtm-based pestictdes on ornamental and food crops. After several years of regulatory review, azadirachtm was approved for use on food crops m the United States, m 1993, and was mtroduced for sale in Florida, and later California and Texas, for use on vegetables under the trade name of Neemix. In 1995, sales expanded to the Northwest and Northeast, and a new, more concentrated formulation, Neemix 4.5 (4.5% azadnachtm), was introduced. Because of its inherent safety, Neemix has been granted an exemption from tolerance for use at ~20 g a.1.per acre, and has the shortest re-entry time allowed by the EPA. Similarly, azadirachtin-based msecticides have been registered in several other countries, mcludmg Mexico, Saudi Arabia, Taiwan, Chile, and India. These products would never have been developed without the contributions of several mtemational researchers, mcludmg H. Schmutterer, W. Kraus, M. Jacobson, H. Rembold, R. C. Saxena, E. D. M Saxena, and K. R. S. Asher.
168
Walter
As a pesticide, azadnachtm kills Insects slowly and does not krll adult insects. Thus, neem-based msectrctdesare often used m combmatron with adulticrdes or beneficial insects, which expand the efficacy of the product. Education of farmers, and the development of practical strategies are essential to the effective use of azadirachtm-based pesttctdes.Manufacturers and extension agents must work m cooperation for azadirachtm-based pesttcrdesto succeed. Commercralization of azadirachtm 1splagued by the problem that the brological actrvrty of neem-based pesticides cannot be Judged solely by their azadnachtin content. Differences in extraction process, formulatton solvents, and adjuvants can dramatrcally influence the toxrcrty and pestrcidal activity of neem-based pestrcrdes. Detailed field experience with specific azadirachtmbased msecticides IS critical for both manufacturers and extension agents, to effectively recommend applicatron rates sufficient for adequate pest control. Despite these limitations, azadirachtin based msectrcides have established niche uses for controlling pests on peppers, melons, lettuce, tomatoes, pears, cm-us, celery, and other crops. The future demands for safe, environmentally sound pesticides will undoubtedly offer additional uses for azadirachtin. References 1 Mau, R F. L , Gusukuma-Minuto, L R , and Shimabuku, R. S (1994) Laboratory evaluations of biomsecticides against DBM larvae Arthropod Manage Tests 20, 327 2 Schmutterer, H and Smgh, R. P (1995) Uses of Neem, m The Neem Tree (Schmutterer, H , ed ), Verlagsgesellschaft, Wrenham, GDR 3 Schmutterer, H (1995) List of Insect pests susceptible to neem products, in The Neem Tree (Schmutterer, H , ed ), Verlagsgesellschaft, Wrenham, GDR, pp l-29 4 Benge, M D (1989) The tree and its characteristics, cultivation and propagation of the neem tree, m Focus on Phyotochemrcal Pestlcldes (Jacobson, M , ed.), CRC, Boca Raton, FL, pp. l-l 6 5 Schmutterer, H (1995) Introductory remarks, m The Neem Tree (Schmutterer, H , ed.), Verlagsgesellschaft, Wienheim, GDR, pp. IX-XII 6 Larson, R 0. (1989) Commercialization of neem, m Focus on Phytochemlcal Pestzcrdes (Jacobson, M , ed.), CRC, Boca Raton, FL, pp. 155-160 7 Isman, M. B , Koul, 0, Lowery, J. J., Arnason, D , Gagnon, J G., Stewart, J , and Salbum, G S (1990) Development of a neem-based msecticrde m Canada m neem’s potential m pest management programs, Proceedmgs of the USDA Neem Workshop (Locke, J C , ed.), USA ARS, pp. 32-39 8 Schafer, E W and Jacobson, M (1993) Repellency and toxrcity of 55 Insect repellents to red winged blackbirds (Angelausphoenzceus) J Envwon SCI Health l&493-497 9 NCR (1992) Neem, m A Tree for Solving Global Problems (Ruskm, F R , ed ), National Academy, Washmgton, DC, pp l-l 37
Commercial
Experience
with Neem
Products
169
10. Chopra, R N., Badhwar, R L , and Ghosh, S. (1968) in Pozsonous Plants oflndza, vol 1. (Pravad, J , ed ), Indian Council of Agricultural Research, New Delhi, pp. 248-270.
11, Sinmah, D , Baskaran, B. G , Looi, L. M., and Leong, K. L (1983) Reye-like syndrome due to Margasa oil poisonmg: report of a case with post mortem lindings Am J. Gastroenterol. 77, 158-164. 12. Jacobson, M. (1989) Pharmacology and toxrcology of neem, in Focus on Phytochemtcal Pestrctdes (Jacobson, M , ed ), CRC, Boca Raton, FL, pp 133-l 83 13 Smniah, D., Baskaran, G., Looi, L. M., and Leong, K. L. (1983) Fungal flora of neem seeds and neem oils toxicity, Malaysia, Appl Btol 12, l-l 2 14 Walter, J. F. and Knauss, J. F. (1990) Developing a neem-based pest management product, m Proc. Neem ‘s Potenttal tn Pest Management Programs (Locke, J. C., ed.), USDA ARS, USA, pp 29-3 1. 15. Anon. (1993) “New York Times News Service,” June 6. 16. Anon (1996) “Company News on Call,” May 14. 17 Anon. (1996) “Busmess Wire,” September 30 18. Walter, J. F (1996) Proceedings International Neem Conference, Austraha (Smgh, R P , ed.), m press. 19. Walter, J. F (1996) International Conference on Standardization of Neem Pesticides, Stuttgart, Germany 20. Mordue (Luntz), A. J. and Blackwell, A. (1993) Review of the activity of azadnachtm. J. Insect Phystol 39,903-924. 21. Smith, R. and Chaney, W. (1995) Update on leafmmer pest control U C Crop Reporter February 3, l-3. 22 Stark, J. D , Vargas, R. J., and Wong, T. Y (1990) Effects of Neem Extracts on Trephiretha Fr. #Fhes and then Parasitoids m Hawaii, Nemo Potential in Pest Management Program USDA ARA, pp 36-42 (Locke, J C , ed ) 23. Wan, M. T., Watts, R G., Isman, M. B , and Strub, R. (1996) Evaluation of the acute toxicity to juvenile Pacific Northwest salmon of azadnchtm, neem extract, and neem-based products. Bull Environ Contam Toxtcol 56,432-439 24. Stark, J D. and Walter, J. F. (1995) Neem oil and neem 011 components affect the efficacy of commercial neem insecticides J Agrtcult Food Chem. 43,507-512. 25. Eckberg, T. B., Cranshaw, W., and Sclar, D. C. (1994) Evaluation of neem msec-
ticides and persistence for control of forest tent caterpillar, Ft Collins, CO Arthropod Manage Tests: 1995,20, 327. 26. Larew, H. G., Knodel, J. J., and Marion, D. F. (1987) Use of fohar-applied neem (azadirachta zndica A. Juss) seed extract for the control of the birch leafmmer, Fenusa pustlla (Lepeletier). J Envtron Hort 5, 17-19. 27 Stark, J. D., Vargas, R. I., and Wong, T. Y. (1990) Proc. Neem ‘s Potenttal tn Pest Management Programs (Locke, J C , ed ), USDA ARS, USA, pp 106-l 13. 28 Hoelmer, K. A., Osborne, L. S , and Yokomu, R. K (1990) Effects of neem extracts on beneficial insects m greenhouse culture, Proc Neem s Potenttal zn Pest Management Programs (Locke, J. C., ed ), USDA ARS, USA, pp 100-106
170
Walter
29 Lru, T P (1995) Possible control of chalkbrood and noseme drsease of the honey bee wrth neem. Am. Bee J 134, 195-198 30 Schauer, M (1985) Die Wrrkung von Ntemmhaltsstoffen auf Blattlause und dte Rubenblattwanze. Doctor thesis, Umversrty of Gressen, Germany 3 1 Walter, J F (1996) Use of botanical pestrcides for the control of pepper pests, Internatronai Pepper Conference Proceedmgs (Maynard, D , ed ), pp 17-19 32 Wrlhams, L. A D and Manstgh, A (1996) Insecttctdal and acamedal actron of compounds from Azahrachta zndzca (A Jus) and thetr use m troprcal pest management Integrated Pest Manage Rev 27, 133-145
11 Fermentation-Derived
Insect Control Agents
The Spinosyns Thomas C. Sparks, Gary D. Thompson, Herbert A. Kirst, Mark B. Hertlein, Jon S. Mynderse, Jan R. Turner, and Thomas V. Worden 1. Introduction Many insect pests present an ongoing battle between the grower’s ability to control the pest and the pest’s ability to resist the available control methods Several well-known examples include the Colorado potato beetle on potatoes, the diamondback moth on vegetable crops, and the Helzothzs complex on cotton. The discovery of new, novel insect control agents for use against these and other Insect pests has served as a focal pomt for insecticide research for more than four decades There are a number of approaches that can be taken m the discovery of Insect control agents, and these have been discussed from a variety of vlewpoints (Z-4). A key component m all of these various vlslons for the discovery of new potential Insect control agents IS natural products A variety of natural products have been or are used as insect control agents (5), mcludmg pyrethrum, abamectm, milbemycin, azadirachtm, mcotme, rotenone, and ryania (6-10). LikewIse, natural products have served as leads for a variety of insect control agents, mcludmg the pyrethrolds, Juvenoids, chlorfenapyr, and, arguably, the phenyl carbamates (9,11-23). Thus, it IS reasonable to expect that natural sources will continue to provide other new insect control agents. It is the purpose of this chapter to outline the discovery, chemistry, and biology of a new class of novel, fermentation-derived Insect control agents the spmosyns. From Methods in Biotechnology, vol 5 Bopeshodes Use and Delwery Edlted by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
171
172
Sparks et al.
2. Discovery of the Spinosyns A key aspect of searching natural sources for new products 1s to mnnmaze the ltkelthood of redtscovermg known, unmterestmg compounds. This IS critical because of the time and difficulty of lsolatmg and identtfymg the compound or compounds that are associated with a given blological activity. Just as deconvolutron can be a key pinch point m the utilization of combinatortal chemistry, the isolation and tdenttficatlon of components m a naturally occurring source represents a deconvolutlon of nature’s combinatortal chemistry. Thus, it is prudent to take measures that increase the probablllty of the isolated component being a new, novel compound when finally identified. Two aspects that directly influence fmdmg new, novel compounds are screening new or unusual sources of natural products, such as marine algae or invertebrates, uncommon fungal or bacterial sources, and so on, and employmg a screening tool that imparts some measure of selectivity or novelty. By using one, or, better yet, both aspects, the chances that the isolated compounds will be new and interesting are greatly improved. During the 1980s Lilly Research Laboratories (LRL, Indtanapolts, IN) operated a program directed at finding new natural products that possessed utility m the pharmaceutical and agricultural mdustrtes. Soil samples from all over the world were collected, fermented, extracted, and screened m a variety of assaysystems.Where possible, the sot1samples were collected from unusual habitats, to improve the chances of findmg new mlcroorgamsms. Among the assaysemployed m the LRL screening program was a mosquito larvlclde assay that was used to detect msecticrdal activity (24). A multtspecles, on-plant assay was used as a follow-up to any actrves detected m the mosquito larvtcide assay. This multispectes assay provided a measure of spectrum for any mosquitoactive broth extracts. During the course of this fermentation screening program, extracts from the fermentation broth of a sol1 sample (designated A83543) collected m 1982 on a Caribbean island were found to be active on mosqurto larvae (14). More importantly, these extracts were active on southern armyworm (Spodoptera endanza) when tested m the multrspecles follow-up assay. Subsequent testing suggested that the insect activity was caused by a low-abundance, htgh-acttvtty substance that appeared to have activity at the level of some commerctal msectrcrdes. The mtcroorgamsm Involved was identified as an actmomycete belonging to a less common genus, Saccharopolyspora. The mtcroorgamsm, Saccharopolyspora spmosa, was identified as a new species (15), and rt produced a family of new, unique macrohdes (molecules contammg a macrocyclic lactone) (14), ortgmally referred to as A83543 factors, but now called spmosyns (16)
Spinosyns
173 2’,3’,4’-tw0-IMethyl Rhamnose R2 ’
Tetracycllc Rmg
Fig
1.
Generalstructureof the spmosyns
3. Chemistry of Spinosyns A variety of techniques were used to establish the structure and stereochemistry of spmosyn A, mcludmg mass spectrometry, extensive NMR spectroscopy, X-ray crystallographic analysis, and hydrolysis of the forosamine sugar, to establish absolute configuration (1417). The spmosyns are composed of a 12-membered macrocyclic rmg as part of an unusual tetracychc ring system, to which two different sugars are attached (Fig. 1); an ammo sugar, forosamme, and a neutral sugar, 2’,3’,4’-tri-O-methylrhamnose. These attributes set the spmosyns apart from other macrocyclic compounds, such as erythromycin A (14-membered monocyclic macrocyclic ring), tylosm, and spiramycin (all 16-membered monocyclic macrocyclic rmgs), the avermectm-mllbemycm family, and lkarugamycin (a tetracyclic macrolactam lacking any sugars) (I4,16, Fig. 1). Spmosyn A (A83543A) was the first spmosyn isolated and identified from the fermentation broth of S. spznosa. Subsequent exammation revealed that the original parent strain of 5’. spznosa (wild-type, WT) produced a number of spinosyns (A-J) (Table 1). Compared to spmosyn A, these other spmosyns (B-J) are characterized by differences m the substitution patterns on the amino group of the forosamme, at selected sites on the tetracychc ring system, and on 2’,3’,4’-tri-O-methylrhamnose (Fig. 2). The WT stram of S spinosa produces a mixture of spmosyns (Table l), of which the primary components are spmosyn A and spinosyn D. An extract of the fermentation broth that contains this naturally occurrmg mixture of spinosyns A and D IS called spmosad (Tracer@), the first product in Dow Agrosciences Naturalyte@ lme of insect control products. Spmosad received U. S. Environmental Protectlon Agency (EPA) registration for use in cotton insect control m February 1997. Spmosyn A is the most active of the naturally occurring spmosyns (listed In Table 1) agamst larvae of the tobacco budworm, Helzothis vwescens, followed closely by spmosyn D. Thus, the most insecticldally active spmosyns are also those that the mlcroorgamsm naturally produces m largest quantrty
Rl
Sources,
R21
R16
Activity
R6
R2’
of Spinosyns
Me Et Me H OMe Me Et Me H OMe H Et Me H OMe Me Et Me Me OMe Me Me Me H OMe Me Et H H OMe Me Et Me H OMe Me Et Me H OH Me Et Me H OMe nonfunctional 2’-O-methyltransferase Me Et Me H OH Me Et Me ine OH Me Et Me H OH Me Me Me H OH Me Et Me H OH nonfuncttonal 3’Gmethyltransferase Me Et Me H OMe Me Et Me Me OMe Me Et Me H OMe Me Et Me Me OMe
R2
and Biological
Spmosyns from wild-type A Me B H C H D Me E Me F Me G” Me H Me J Me Spmosyns from H mutant H Me Me Q R H S Me T Me Spmosyns from J mutant. J Me L Me M H N H
Table 1 Structures,
OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe OMe
OMe OMe OMe OMe OH OH OH OH OH
R4’
~80 26 22 6 40
5.7 05 14 5 53 >64
0.3 04 08 08 4.6 45 71 57 >80
TBWa Neonate drench LC$
to Spinosyn
OMe OMe OMe OMe OMe OMe OMe OMe OH
R3’
Compared
>25 -25 >25
>25 31 -
1.1 60 18 31 66 18 >25 >25
TBW Cotton leaf-drp LCSClb
-63 67 >50
114 -
95 14
0.9 04 84 29 >50 16 95 -63
>lOO >lOO 61
12 >lOO
-
6.9 51 15
ALH Vial contact LC50b
Standards
TSSM Acute LC50b
A and Selected
“TBW, tobacco budworm, TSSM, two-spotted spider mite, ALH, aster leafhopper ‘wm ‘The ammo sugar IS ossamme Instead of forosamme dForosamrne is missmg ‘2’,3’,4’-tn-O-methylrhamnosyl moiety IS mlssmg
Spinosyns from K mutant: nonfuncttonal4’-0-methyltransferase K Me Me Et Me H OMe OMe 0 Me Me Et Me 1Me OMe OMe Y Me Me Me Me H OMe OMe Spinosyns from H and J mutants. nonfunctional 2’ or 3’-0-methyltransferase Me H OH OMe U Me Me Et Me Me OH OMe V Me Me Et Me H OMe OH P Me Me Et Me Me OMe OH W Me Me Et Spinosyns lacking one or more sugars Me H OMe OMe Psa-17 d d Et Me H e e Psa-9 Me Me Et d d Et Me H e Aglycone Psa-17 D d d Et Me Me OMe OLe Psa-9 D Me Me Et Me 1Me e e Aglycone D d d Et Me Me e e Cypermethrm Propargite Ethofenprox OMe e e OMe e e
>64 >64 >64 >64 >64 >64 061 -
-
100 -
19
13 -
03
82 28 -
x50 -
32 69 -
10 04
-
>25 OH 3.5 14 13 OH OH 20 in combmatton wtth smefungm OH 22 OH 17 OH >64 OH >64
Sparks et al
776
Spmosyn A
Avermectm
B 1a
Erythromycm
.4
Spxamycm I
Ikarugamycm
Fig 2 Structures of spmosyn A and other macrocychc compounds
In addition to the spmosyns produced by the WT stram, other spmosyns were identified from several mutant strains. Because the parent strain produced the spmosyns only m very minute quantities, LRL began a program of strain improvement to increase the yield. One offshoot of the strain selection program was the tdentifkation of several mutant strams, possessmgnonfunctional 2’- and/or 3’- and/or 4’-O-methyltransferases. Because these mutants were unable to methylate particular hydroxyl groups on the 2’,3’,4’-tri0methylrhamnose, a variety of spmosyns were produced, most of which were not pro-
Spinosyns
177
duced by the WT stram (18). The spinosyns isolated from these mutant strains include spmosyns H, Q, R, S, and T; spmosyns J, L, M, and N; and spinosyns K, 0, and Y from mutants with nonfunctronal2’-, 3’-, or 4’0methyltransferaseq respectrvely (18,19). Further varratrons m the methylatron of the rhamnose sugar were observed with the addition of smefungm (ZO), whrch was found to specifically block the 4’0methyltransferase during the fermentatron process of the WT strain. When coupled (sinefungin) with the H and J mutant strams, several other new spmosyns, P, U, V, and W, were produced (18). Again, the variations in all of these spmosyns center around methylation of the forosamme ammo group, presence or absence of O-methyl groups on the rhamnose sugar, and presence or absence of methyl group(s) in the C6, C 16, and C2 1 positions of the tetracychc rmg system. To date, more than 20 spmosyns have been identified from the WT and mutant strains (Table 1). Physical characterrsttcs of the spmosyns have been published elsewhere (14,22,22). Because of their chemically complex nature, the spmosyns are efficrently obtained only through the process of fermentation Although not a useful process for commerctal productron, the first total synthesis of spinosyn A as its unnatural levorotatory enantiomer was accomplished by Evans and Black (23,24; the term “spinosyns” 1snow the preferred name for this chemical class) The naturally occurring spmosyn A is dextrorotatory and 1sbrologrcally active against insects such as H. vlrescens, but the unnatural levorotatory enantromer IS brologically inactive against H vzrescenslarvae. 4. Insect Spectrum of Spinosyns Spinosyn A is active on a variety of insect species, but especrally on leprdopterous pests such as the tobacco budworm (H. vzrescens), the cotton bollworm (Helicoverpa zea), American bollworm (Helzothu armigera), armyworms (Spodoptera exigua, Spodoptera littoralis, Spodoptera frugzperda), loopers (Trzchoplusza nz), diamondback moth (Plutella xylostella), and rice stemborer (CItllo suppressah) (Tables 1 and 2; refs. 16,21,22,25). Good activity IS also observed against a variety of dipteran pests, thrips, fleas, and hymenopteran pests; activity IS variable against coleopterans (21). At a screenmg rate of 400 ppm, spinosyn A 1s active against leprdopteran pests, spider mites, planthoppers, and cockroaches, but no actrvrty is observed on aphids or nematodes (Table 2; ref. 22). Although the relatively broad activity spectrum of the spmosyns is interesting, the truly exciting aspect of this novel chemistry is the level of activity observed against leptdopteran pests such as H. virescens. Bioassays using a standard topical bioassay show spinosyn A to be far more active than a variety of organophosphorus, carbamate, cyclodiene, or other insect control agents commonly used m crops such as cotton (Table 3). In these and other assays,
178 Table 2 Screening
Sptnosyn A B C D E F H J K L M N 0 : R S
Sparks et al. Activity
TBW + + + + + + + + + + + + + + + -
of Spinosyns
BAW + + + + + + + + + + + + + + +
T
+ +
U
+
+
v
+
nt
W Y
+ +
+
Against
CPH + + + + + + + + + + + + + nt +
Selected
-
GECR -t -t + + + + -
+
-
-
nt nt
-
-
-
nt nt
-
-
-
nt
nt
+
-
nt nt
nt
nt -
nt
+
-
nt
nt
nt
TSSM + + + +
Pest Species
+ +
CA -
RKN nt nt
nt
+ = >80% mortality at 400 ppm, - = ~80% mortality at 400 ppm; nt = not tested TBW = tobacco budworm, H wrescenr, BAW = Beet armyworm, Spodopteta exlgua, CPH = Corn plant hopper, Peregrrnus mardls, TSSM = Two-spotted spider mne, T wtlcae, GECR = German cockroach, Blatella germamca, CA = Cotton aphid, Aphls gossyplz, RKN = Root knot nematode, Meloldogyne mcogmta
sptnosynA ISasactive asmany of the pyrethroid msecttctdes(Table 3). When tested n-rassaysthat are prnnartly contactm nature (such as toptcal, glassvial, and so on), spmosynA ISabout as active or slightly less active than pyrethroids, such as cypermethrin; however, tn assaysthat incorporate an oral component (leaf or diet assays), spmosyn A can be more active than cypermethrin (refs. 28,26, Table 1). Thus, depending on the assaysystem,sptnosyn A 1scomparable to, and m some cases supenor m acttvtty to, pyrethrotdssuchas cypermethrm(refs. 18,26; Tables 1 and 2). 4.7. Spinosyn Structure-Activity Relationships Very simple changes in structure can profoundly alter the acttvtty of the spmosyns toward larvae of H vzrescens.The presence or absence of N-methyl
179
Spinosyns Table 3 Acute Insect (H. wirescens, Topical, 48-72 h, yglg) and Mammalian (Rat Oral, Acute, mg/kg) Toxicity of Selected Insect Control Agents Compound Spinosyns Spmosyn A DDT and Pyrethrolds DDT Permethrm Fenvalerate Cypermethrm LCyhalothrm Blfenthrm Cyclodlenes Endosulfan Organophosphates Me Parathion Azmphosmethyl Acephate Profenofos Carbamates Methomyl Avermectms Abamectm Emamectm
H vwescens L&o
Rat oral L&o
VSRa
Refs
1 28-2 25
3783-5000
1681-3906
18
52-152 1 33-2 79 0 870-l -89 0 241-1.61 0 929 1 32
87 >4000 451 247 56 55
0 9-2 8 >1434-3008 239-l 139 153-1025 60 42
42,43,45 39,49,45 39,45 39,4.5 39,45,47 39,47,48
73 3
18
03
42,45
11&650 29 3-33 3 74 3 11.0
9 5 866 400
0148 02 11 7 36
39,45 4294549 45,so 39,45
4 33,26 7
17
0 6-3.9
39,45,49
1 16 0.10
10.6-l 1.3 70
9 l-97 700
41,44 46,30
‘VSR, vertebrate selectwty ratlo for Rat oral/Hv toxlclty Not necessarily representatwe for other insect pests
groups on the ammo group of forosamme (spinosynsB and C) or a methyl group at C6 (spmosyn D) does l&e to alter the biological activity relative to spmosyn A. However, lossof a methyl group at C2 1 or Cl 6 of the tetracyclic ring (spinosynsE and F, respectively) reduces activity (Table 1). Most dramatic, however, are the activity changesassociatedwith the loss of O-methyl groups on the rhamnose nng Loss of the methyl group m the 2’ or 4’ position (spinosynsH and K, respectively) reducesactivity by about an order of magnitude; loss of the methyl group at the 3’position (spmosyn J) decreasesactivity by more than two orders of magnitude (>2OOx),compared to spinosyn A (Table 1). Most of the other spinosynsrepresent combmatlonsof spinosynsH, J, or K associatedwith the altered methylation patterns found m spinosynsB, D, E, and F. Thus, the natural spmosynsexhibit simultaneous variations in N-, C-, and 0- methylations.These spmosynsare all much lessactive than spinosyn A, with one notable exception: spinosynQ (spmosynH with a methyl
180
Sparks et al.
group at C6) (Table 1). There is also a general trend m which the C6-methyl analogs of the 2’-, 3’-, or 4’0demethylrhamnose derivatives (spinosyns Q, L, 0, respectively) are more active than their respective parents (spinosyns H, J, K) (Table 1) Loss of either sugar (forosamme or the trt-O-methylrhamnose) to yield the C 17 and C9-pseudoaglycones, respectively, or both sugars (aglycone), results m a loss of activity (ref. 27, Table 1). A stmtlar trend 1sobserved for the two pseudoaglycones and the aglycone of spmosyn D (methyl at C6) Thus, none of the more than 20 naturally occurring spinosyns, their aglycones, or pseudoaglycones, listed m Table 1, 1smore active against neonate larvae of H v~~~cens than spmosyn A. Cotton leaf-dip activity of the spmosyns toward larvae of H vzrescens revealed a pattern that was very simtlar to that of the neonate drench assays In the cotton leaf-dip assay, spmosyns A and D clearly show then superior activity compared to the other spmosynsexamined (Table 1) In both of the H vzre,scey1s assays,spmosyn A was as active as the commercial pyrethroid cypermethrm, a trend observed in a variety of other assaysystems(18) Although they apparently lack the residual activity crtttcal to succeed as an acartctde, the spmosyns do exhibit acute toxtctty to two-spotted spider mites, Tetranychus urtzcae (acute LCsO= 0.9 ppm, Table 1) Structure-activtty relattonshtps for T urticae present a significant departure from that of H vzrescens, m that the best btologtcal activity against T. urtzcae is exhibited by spmosyns K and 0, but spmosyns H and Q are relatively weak (Table 1). Regression analysts of spmosyn activity toward neonate H vzrescenslarvae vs acute toxictty to T. urtzcae revealed only a relatively weak correlatton (r’ = 0.5 18,s = 0.655, F = 0.0037). Thus, there appears to be little relationship between spmosyn acttvtty against mites and activity against H. vzrescens Although the spmosyns possesssome acute acartcidal activity, residual activity toward mites is weak compared to commerctal standards, rendermg the spmosyns unsuttable as acaricides within the context of our current knowledge of this chemistry (22). In addition to their demonstrated activity on lepidopterans, mites, and dtpterans (21,28), the spmosyns are also active on some homopteran species, such as the aster leafhopper, Macrosteles severznz, which 1sused as a model for Asian plant- and leafhopper pest species Although the current data set 1smcomplete, an exammatton of the data m Table 1 shows that several spmosyns (A, B, K, 0, V) possessnearly equivalent contact activity against adults of M severznr, and spmosyns K and 0 are again among the most active of the series. Although the contact activity of the spmosyns toward M severznz 1sinteresting, they are much less active than extstmg commerctal products, such as ethofenprox (Table 1). Similar conclustons would also apply to other hopper pest species (22) 5. Mode of Action A number of modes of actton for insect control agents are known, mcludmg acetylcholmesterase mhibitors (organophosphorus and carbamate msecticides),
Spinosyns
181
sodmm-channel blockers (DDT, pyrethroids), channel blockers for y-ammobutyrtc acid (GABA)-gated chloride channels (cyclodlenes, fiproles), mcotmlcreceptor agonists (tmtdacloprrd), octopamine receptor agonists (formamtdmes), and inhibitors of mttochondrtal respiration (chlorfenapyr, rotenone) (29,30). Currently available mformatron based on extensive mode-of-action studies clearly indicates that the mode of action for spmosad is drstmct from all of the forementioned groups, or any other insect control agent whose mechanism IS known. Electrophysrological studies have shown that spmosyn A acts on the insect central nervous system to increase spontaneous acttvtty, leading to mvoluntary muscle contractrons and tremors (31). This increase in excttatton appears to result from the persistent activation of mcotmtc acetylcholme receptors and prolongatton of acetylcholine responses, in a manner that IS drstmct from other mcotmtc active molecules, such as tmidacloprrd and mcotme (31). In addmon, the spmosyns can also alter the function of GABA-gated chloride channels, again m a manner distinct from all known insect control agents (31), which may or may not also contribute to the btologtcal activity of this novel class of insect-control agents. Thus, based on our present understanding, the mode of action of spinosad appears to be unique. 6. Environmental and Toxicological Profile The pyrethrotd levels of msecttctdal activity observed for spmosyn A and spinosad contrast sharply with Its relative safety to many beneficial insects. Spmosad was an order of magnitude less toxic to honeybees and a whitefly parasitold (24 h LCsO = 11.5 and 29.1 ppm, respectively) than cypermethrin (24 h LC50 = 1.2 and 1.9 ppm, respectively) (25). For the hemipteran, coleopteran, and neuropteran benetictals studied (e.g., minute pirate bug, convergent lady beetles, common green lacewing), spinosad was nontoxtc at the highest dose tested (24 h LC5,, = >200 ppm), in contrast to cypermethrin, which was htghly toxic (24 h LCsO= ~0.8 ppm) (25,32,33). Thus, spinosad provides a high degree of selecttvity toward beneficial insects, making it an attractive tool for insect-pest management programs that seekto preserve beneficial populations as a means to improve overall pest-insect control, and reduce the risk of secondary pest outbreaks. A compound can possessexcellent levels of activity against target msectpest species and yet have limited utility, tf tt IS highly deleterious to beneficial insects, mammals, or other nontarget species. The fact that a compound IS a natural product does not necessarily guarantee good envuonmental and/or pest management compatibility. However, m the case of spinosyn A and spmosad, excellent levels of activity against target-pest species are indeed coupled with an excellent envn-onmental/toxrcologrcal profile. In testmg conducted for EPA registration, spinosad was not shown to leach or persist m the environment. Toxicity to mammalian, avran, and aquatic species is relatively low when com-
Sparks et al.
182
pared to many currently used insect control agents (Table 4) One approach to quanttfymg the relative selectivity of a compound for target (insect) vs nontarget (i.e., mammalian) species is to calculate a therapeutic Index. Although such mdices certamly possess hmitations (34), such as dependence on only one pest/nontarget species and one apphcation method, a therapeutic index, such asvertebrate selectivity ratio (VSR = acute rat oral LD,, mg/kg/msect LD50 pg/g; 34), can illustrate the relative selectivity of an insect control agent for the target-insect species vs nontarget mammals in a given cropping system. Certainly, many of the older msecticides, such as methyl parathion and EPN have comparatively high toxicity to mammals, and only comparatively moderate activity on the target-insect pest, resultmg m low VSRs (VSR = 2000 Not irritant >2000 >2000 30 96 96 33,51
Compared
Rat oral (mg/kg) Rat dermal (mg/kg) Rabbit skm irritation Mallard duck, acute oral (mg/kg) Quarl, acute oral (mg/kg) Rambow trout, acute 96 h (mg/L) Carp, acute 96 h (mg/L) Daphma magna, 48 h (mg/L) Refs
A (Technical) Spinosyn A
of Spinosyn
Test
Table 4 Toxicity Profile
106-113 84 2000 0.0032 0 042 0 00034 44,52,53
Abamectm
with Selected
247 >2000 Moderate irritant >10,000 0.025 0 0016 0 0013 45,48,54,55
Cypermethrin
LW .
Insect Control
(Technical)
97 >2000 Not rrritant >2150 11.3 0.25 0.43 0 19 56
Fiprornl
Agents
450 HO00 31 >32 57.58
Imidacloprid
184
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(18), or known to possessspectfic target site- or metabolism-based mechamsms.
However, some variation m susceptibihty is expected for any new insect-control agent, as demonstrated by the range of LDso values observed for several pyrethroids 2 yr prior to their commercial mtroduction (39). Likewise, some variation has also been observed for spmosad, with some field strains having higher and some lower LDsOs,compared to a laboratory reference colony (38). The unique mode of action of spinosadand the spmosynscertainly renders crossresistancecausedby altered target site (I.e., knockdown resistance,altered acetylcholmesterase)asvery unlikely. Likewise, laboratory colomes of the diamondback moth possessmg enhanced detoxification systems (glutathione transferases, monooxygenases; Chih-Nmg Sun, personal communication) showed little crossreststanceto spmosyn A (IS). These observations are consistent with recent studies indicating that pest lepldopterans, such as H vzrescens, do not readily metabolize spinosyn A (40). Thus, the potential for the rapid development of pestInsect resistanceto spinosadmay be reasonably low, making spinosadan attracttve and a potentially useful tool in insecticide-resistancemanagement programs However, as the history of insecticide resistancehas aptly demonstrated, resistanceto any insectcontrol agent can occur If sufficient selection pressure1sapplied through overuse or misuse. In an effort to ensure the long-term utilrty of spmosad, DowAgrosciences is mvesttgatmg and, where appropriate, providing use recommendations designed to munmize the chanceof resistancedevelopment.
8. Summary The discovery and subsequent development and registration of spmosad (Tracer@), demonstrates that natural products contmue to provide a fertile source of new, novel insect control agents. Although more than 20 spmosyns have been isolated and identified, thus far spinosyns A and D (the primary components of spmosad) remain the most active against lepidopterous larvae such as H. virescens. The different spmosyns arise from varrations in substitution patterns on the two sugars (forosamme and 2’,3’,4’-trr-O-methylrhamnose) and the tetracychc ring system. Many of the spinosyns were isolated from mutant strains lacking a specific O-methyltransferase for one of the hydroxyl group positions on rhamnose. Among the spmosyns, small changes m their structure can result in large changes m biological activity, especially modrfications to the rhamnose moiety and at C 16and C2 1of the tetracychc ring. Although spinosyn A IS the most active of the spmosyns toward lepldopterous larvae, spinosyns K and 0 are among the most active for T urtzcae and M sevennz. However, at this time, thesespmosyns lack the necessaryacttvny and/or residual properties to be considered as potenttal products for mite and leafhopper pests Available mformation indicates that the mode of action of spmosyn A is unique. Compared to other insect control agents, the spmosyns also possess
Spinosyns
185
very favorable environmental and toxtctty profiles, and are also comparattvely safe to beneficials Vertebrate selectivity ratios (a type of therapeuttc index contrasting vertebrate and insect toxtcrty levels) for spinosyn A on H vzrescens larvae are among the most favorably observed to date for insect control agents. Thus, these novel compounds represent a new genre of unique, naturally derived insect control agents that possess pyrethrotd levels of acttvity, an excellent toxtcologtcal and environmental profile, and a lack of cross-resistance to the currently available insect control agents (based on available data) (28).
Acknowledgments We gratefully acknowledge the assistance of our many colleagues at Dow Agrosctences (DAS) and Lilly Research Laboratories (LRL), includmg Larry L. Larson (DAS), James Gtfford (DAS), Joe Schoonover (DAS), John Babcock (DAS), James Dripps (DAS), John R. Skomp (DAS), Vmce Salgado (DAS), Larry Creemer (LRL), Patrick J. Baker (LRL), M. Chris Broughton (LRL), Mary L. Huber (LRL), James W. Martin (LRL), Walter M. Nakatsukasa (LRL), Karl Michel (LRL), Raymond Yao (LRL), and Jonathan W. Paschal (LRL).
References 1 Menn, J J. (1983) Present msecticides and approaches to discovery of environmentally acceptable chemicals for pest management, in Natural Products&r Innovatwe Pest Management (Whitehead, D. L , and Bowers, W. S , eds ), Pergamon, New York, pp 53 1 2 Geissbuhler, H., d’Hondt, C , Kunz, E., Nyfeler, R , and Ptister, K. (1987) Reflections on the future of chemrcal plant protection research, m Pestlclde Sczenceand Blotechnology (Greenhalgh, R. and Roberts, T R., eds ), Blackwell, Boston, pp 3-14 Hodgson, E and Kuhr, R J (1990) Introduction, m Safer Insecticzdes* Development and Use (Hodgson, E and Kuhr, R. J., eds.), Marcel Dekker, New York, pp l-l 8 Hedm, P A., Menn, J J , and Hollmgworth, R. M , eds. (1994) Natural and Englneered Pest Management Agents American Chemical Society, Washmgton, DC Godfrey, C. R A., ed (1995) Agrochemzcals from Natural Products. Marcel Dekker, New York Casida, J E., ed. (1973) Pyrethrum The Natural Insecticide. Academic, New York Hansen, D. J., Cuomo, J., Khan, M., Gallagher, R. T , and Ellenberger, W P (1994) Advances m neem and azadnachtin chemistry and bioactivity, m Natural and Engmeered Pest Management Agents (Hedm, P A., Menn, J. J , and Holhngworth, R. M., eds.), American Chemical Society, Washmgton, DC, pp. 103-129 8 Mrozik, H (1994) Advances in research and development of avermectms, m Natural and Engmeered Pest Management Agents (Hedin, P A., Menn, J J., and Holhngworth, R M., eds.), American Chemical Society, Washington, DC, pp 54-73 9 Addor, R. W. (1995) Insecttcides, m Agrochemlcals from Natural Products (Godfrey, C R. A , ed ), Marcel Dekker, New York, pp l-62 10 Kornis, G. I. (1995) Avermectms and Milbemycins, in Agrochemzcals from Natural Products (Godfrey, C R A., ed.), Marcel Dekker, New York, pp 215-255
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11 Kuhr, R J and Dorough, H. W (1976) Carbamate insecttctdes Chemutry, Btochemtstry and Tox~ology CRC, Cleveland, OH 12 Henrrck, C A (1995) Pyrethrords, m Agrochemrcals from Natural Products (Godfrey, C R A., ed.), Marcel Dekker, New York, pp. 63-145 13 Henrrck, C A (1995) Juvenotds, m Agrochemzcals from Natural Products (Godfrey, C. R A , ed ), Marcel Dekker, New York, pp, 147-2 13 14 Knst, H A , Mrchel, K H , Mynderse, J. S., Chro, E H., Yao, R. C , Nakatsukasa, W M , et al (1992) Discovery, isolation and structure eluctdatron of a family of structurally unique, fermentanon derived tetracychc macrohdes, m Syntheses and Chemzstry of Agrochemtcals Iii (Baker, D R , Fenyes, J G , and Steffens, J J , eds ), American Chemical Society, Washmgton, DC, pp 2 14-225 15 Mertz, F P and Yao, R C (1990) Saccharopolyspora spznosa sp nov. isolated from so11 collected m a sugar ml11 rum still Int J Cyst Bactertol 40, 34-39 16 Sparks, T C , Thompson, G D , Larson, L. L , Kn-st, H A, Jantz, 0 K , and Worden, T V (1995) Brologrcal characterrsttcs of the spmosyns a new class of naturally derrved insect control agents, m Proceedmgs of the 1995Beltwtde Cotton Production Conference,Nattonal Cotton Councrl, Memphis, TN, pp 903-907 17 Krrst, H A , Mtchel, K H , Mynderse, J. S , Creemer,L C , Chro, E. H , Yao, R C., et al (199 1) A83543 A-D, unique fermentation-derrved tetracychc macrohdes Tetrahedron Lett 32,4839-4842 18 Sparks, T C , Ktrst, H A , Mynderse, J. S., Thompson, G D , Turner, J R , Jantz, 0 K , et al. (1996) Chemistry and btology of the spmosyns components of spmosad(Tracer@), the first entry mto DowElanco’s Naturalyte class of Insect control products, m Proceedtngs of the I996 Beltwtde Cotton Productton Conference, Natronal Cotton Counctl, Memphts, TN, pp 692-696. 19 Mynderse, J S , Martm, J W , Turner, J R., Creemer, L C , Knst, H A , Broughton, M C , and Huber, M L B (1993) US Patent 5202242 20 Chen, S. T , Hensens,0 D , and Schulman,M D (1989) Biosynthesis,m Zvermectm and Abamectm (Campbell,W C , ed ), Sprmger-Verlag,New York, pp 55-72 21 Thompson, G D , Busacca, J D , Jantz, 0. K , Borth, P. W., Noltmg, S P , Wmkle, J R , et al (1995) Freld performance m cotton of spmosad.a new naturally dertved insect control system, m Proceedings of the 199.5Beltwtde Cotton Production Conference, National Cotton Councrl, Memphts, TN, pp 907-910 22 DeAmtcrs,C V , Dnpps,J. E., Hatton,C J., andKarr, L L (1997)Physicalandbtologlcal propertiesof the spmosynsnovel macrohdepestcontrol agentsfrom fermentatron,m PhytochemtcalsforPestControl(Hedm,P A ,Hollmgworth,R ,Masler,E P, Mlyamoto, J , andThompson,D , eds.),Amerxan ChemrcalSociety,Washmgton,DC, pp. 144-154 23 Evans, D A and Black, W C. (1992) Asymmetric synthesesof macrohde (+)A83543A (leprctdm) aglycon. J. Am Chem Sot 114,2260-2262 24 Evans, D A and Black, W C (1993) Total synthesis of (+)-A83543A [(+)leptcrdm A] J Am Chem Sot 115,4497-45 13 25 Thompson, G D , Busacca, J D , Jantz, 0. K , Larson, L L , and Sparks, T C (1995) Spmosyns an overview of new natural managementsystems,In Proceedmgsof the 199.5Beltwtde Cotton Productron Conference, National Cotton Councd, Memphis, TN, pp 1039-1041
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26 Larson, L L (1995) Laboratory toxicity of spmosad to late second mstar tobacco budworm compared to commercial standards, 1994. Arthopod Manage Tests 20,356 27 Klrst, H A. (1998) Fermentation-derived compounds as a source of new products Pure Appl Chem , m press 28 Edwards, J M , Karr, L. L , Schneider, M B , and Paterson, E (1995) Potential of spmosad, a Naturalyte insect control product, as a control agent for Dlptera. Entomological Society ofAmenca National Meetmg, December 17-20, 1995, Las Vegas, NV 29 Eldefrawl, M E. and Eldefrawl, A. T. (1990) Nervous system-based Insecticides, m Safer Znsecticzdes Development and Use (Hodgson, E. and Kuhr, R J , eds ), Marcel Dekker, New York, pp 155-207 30 Sparks, T C (1996) Toxicology of insecticides and mltlcldes, m Cotton Znsects and Mites Characterlzatzon and Management (King, E. G., Phillips, J. R., and Coleman, R J , eds.), Cotton Foundation, Memphis, TN, pp 283-322 31 Salgado, V L , Watson, G. B , and Sheets, J J (1997) Studies on the mode of action of spmosad, the active ingredient m Tracer@ Insect Control, in Proceedings of the 1997 Beltwlde Cotton Production Conference, National Cotton Council, Memphis, TN, pp. 1082-I 086 32 Schoonover, J R and Larson, L L (1995) Laboratory activity of spmosad on non-target beneficial arthropods, 1994 Arthropod Manage Tests 20,357 33 Borth, P W , McCall, P J , Blshoff, R F , and Thompson, G D (1996) The environmental and mammalian safety profile of Naturalyte Insect Control, m Proceedmgs of the 1996 Beltwide Cotton Productzon Conference, Natlonal Cotton Council, Memphis, TN, pp 69&692 34 Hollmgworth, R M (1976) The biochemical and physlologlcal basis of selective toxlclty, m Insectrczde Bzochemtstry and Physiology (WIlkinson, C F , ed ), Plenum, New York, pp 43 l-506 35. Sparks, T C (1980) Development of msectlclde resistance m HellothIs zea and Hellothzs vlrescens m North America Bull Entomol Sot Am 27, 186-192 36 Sparks, T C , Graves, J B , and Leonard, B R (1993) Insectlclde resistance and the tobacco budworm. past, present and future, m Reviews In Pestlclde Toxrcology, vol 2 (Roe, R M and Kuhr, R J, eds.), Toxicology Commumcatlons, Raleigh, NC, pp 149-183. 37 Martin, S H , Graves, J B , Leonard, B R , Burns, E , Mlcmskl, S , Ottea, J A , and Church, G. (1994) Evaluation of msectlclde resistance and the effect of selected synergists tn tobacco budworm, in Proceeding of the 1994 Beltwlde Cotton Productzon Conference, Natlonal Cotton Council, Memphis, TN, pp. 8 l&823 3x Leonard, B R , Graves, J B., Burrls, E , Mlcmskl, S , and Mascarenhas, V (1996) Evaluation of selected commercial and experimental msectlcides agamst lepldopteran cotton pests m Louisiana, m Proceedmgs of the 1996 Beltwzde Cotton Production Conference, National Cotton Council, Memphis, TN, pp 825-830 39 Leonard, B. R , Graves, J. B., Sparks, T. C , and Pavloff, A M (1988) Varlatlon m field populations of tobacco budworm and bollworm (Lepldoptera. Noctuldae) for resistance to selected msectlcldes. J Econ Entomol 81, 152 1-l 528 40 Sparks, T. C., Sheets, J. J , Skomp, J. R., Worden, T V., Larson, L L., Bellows, D., Thlbault, S., and Wally, L (1997) Penetration and metabolism of spinosyn A
188
41
42 43 44 45 46 47 48 49
50
5I 52
53 54
55 56
57.
58
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into leptdopterous larvae, III Proceedings of the 1997 Beltwzde Cotton Production Conference Natlonal Cotton Council, Memphis, TN, pp 1259-1264 Bull, D. L. (1986) Toxicity and pharmacodynamlcs of avermectm m the tobacco budworm, corn earworm and fall armyworm (Nocturdae Lepldoptera). J Agrzc Food Chem 34,74-78. Graves, J B , Clower, D F , Bagent, J L , and Bradley, J R (1964) Bollworms increasing m resistance to msectlcides. LA Agrlc 7,3,16 Graves, J. B , Clower, D. F , and Bradley, J R. (1967) Resistance of the tobacco budworm to several insecticides m Louisiana J Econ Entomol 58, 583,584. Lankas, G. R and Gordon, L R (1989) Toxicology, m Ivermectln and Abamectln (Campbell, W C., ed ), Springer-Verlag, New York, pp 89-112 Ware, G W (1983) Pestlcldes Theory and Applzcation W H Freeman, San Francisco Merck (1995) Emamectln Benzoate Inseclzczde, Technzcal Data Sheet. Merck, Three Bridges, NJ Melster, R. T., ed (1996) Farm Chemzcals Handbook ‘96 Meister, Willoughby, OH Naumann, K (1990) Synthetic Pyrethrozd Insectlczdes Structures and Properties Sprmger-Verlag, New York Palazzo, R. J (1976) Comparison of the responses of adults and larvae of five lepldopteran species to seven msectlcldes. M.S Thesis, LouIslana State Umverslty, Baton Rouge Rose, R L and Sparks, T C (1984) Acephate toxlclty, metabohsm, and antlchohn-esterase activity m Helrothzs vzrescens (F ) and Anthonomus grandis grandts (Boheman) Pestle Blochem Physlol 22,69-77 DowElanco (1994) Spmosad Technical Gmde DowElanco, IndIanapolls, IN Wlslockl, P. G., Grosso, L S , and Dybas, R A. (1989) EnvIronmental aspects of abamectm use in crop protectlon, in Ivermectin and Abamectin (Campbell, W. C,, ed ), Springer-Verlag, New York, pp 182-200 Lasota, J A and Dybas, R. A. (1991) Avermectins, a novel class of compounds implications for use m arthrodop pest control. Ann Rev Entomol 36, 9 1-I 37 Hill, I R (1985) Effects on non-target organisms m terrestrial and aquatIc envlronments, m The Pyrethrold Insectlcldes (Leahey, J P , ed ), Taylor and Francis, Philadelphia, pp. 15 l-262 Lltchfield, M. H. (1985) Toxlclty to mammals, m The Pyrelhrold Insectlczdes (Leahey, J P , ed ), Taylor and Francls, Phlladelphla, pp. 99-150 Hamon, N., Shaw, R., and Yang, H (1996) Worldwide development of fiproml msectlclde, m Proceedings of the I996 Beltwzde Cotton Productlon Conference, Natlonal Cotton Council, Memphis, TN, pp. 759-765. Elbert, A , Overbeck, H , Iwaya, K., and Tsuboi, S (1990) Imrdaclopnd, a novel systemic mtromethylene analogue msectlcide for crop protectlon. Brighton Crop Protect Conf Pests Dls 1,21-28 Mullms, J. W (1993) Imldaclopnd. A new mtroguamdme msectlclde, m Pest Control wzth Enhanced Environmental Safe& (Duke, S 0 , Menn, J. J , and Plmuner, J R., eds ), American Chemical Society, Washington, DC, pp. 183-l 98.
12 Bacillus
thuringiensis
Na fural and Recombinant Bioinsecticide Products James A. Baum, Timothy B. Johnson,
and Bruce C. Carlton
1. Introduction Worldwide sales of Bacdlus thurznglensis (Bt) dwarf those of any other biopesticide product. Annual sales in the early 1990s were estimated at $100 million, accountmg for l-2% of the global insecticide market (1,2). The largest market for Bt-based bioinsecticides, estimated by van Frankenhuyzen (3) to be -60% of the total Bt market m 1990, is m the protection of vegetable and horticultural crops from lepidopteran pests. The remainder of the Bt market Includes applications for the control of forest pests (3), particularly m North Amertca, dtpteran pests that act as vectors of human diseases (2), lepidopteran pests on cotton, and coleopteran pests on solanaceous crops, Lambert and Peferoen (2) and van Frankenhuyzen (3) provide fine historical overviews of the development of Bt as a commercial bioinsecticide. Over the past 15 yr, much progress has been made in understanding the molecular and genetic basis of Bt insecticidal activity. The recent review by Cannon (4) covers many aspects of Bt molecular biology. In this chapter, we will highlight advances in the development of improved btoinsectrcide products based on recombinant or genetically modified strams of Bt. 2. The Bacterium and Its Crystal Proteins Bt is a Gram-positive spore-forming bacterium that produces parasporal inclusions (or crystals) during stationary and/or sporulatron phase, the mclusions bemg composed of crystal (Cry) proteins that are toxic to a wide variety of insect species. The presence of parasporal rnclusions distmguishes Bt from From Edlted
Methods by
tn B!ofechnology,
F R Hall
vol 5 &opesttcdss
and J J Menn
0 Humana
189
Press
Use and De/wry Inc , Totowa.
NJ
190
Baum,
Johnson,
and Car/ton
the common so11bacterium Baczllus cereus Although Bt can be isolated from the sot1 (5) and from fohar surfaces (6), it IS most abundant m gram dust, the debris recovered from gram ~110sand other gram storage faclhtles. Bt IS classtfied primarily on the basis of flagellar antigen serotypmg (7) This classlficatlon system, comprising 45 distinct serotypes representmg 55 serovars of Bt (8), correlates well with morphologlcal and blochemlcal characteristics of the bacterium, but IS a poor predictor of msectlcldal actlvlty Dlstmct serovars are classified as subspecies of Bt, for Instance, subspecies kurstakt, a~zawu~, mornsonz, and wuelensu. Although certain CT genes are commonly found m certain serovarsor subspecies(e.g.,cvyl Cu m subspeciesu~zawuz and entomoczdus), the correlation IS, m general, very poor. For instance, strains of the subspecies mowzsonzhave ylelded crystal proteins with lepldopteran, coleopteran, or dlpteran toxlclty Fmally, the use of subspecies designations as an Indicator of msectlcldal actlvlty IS even less reliable when discussing recombinant or genetically modified Bt strams, since virtually any combmatlon of crystal protem genes may be constructed usmg molecular genetic techniques Corporate, mstttutlonal, and government strain collections of Bt contain thousands of strain Isolates from around the world. The rapid growth m new cry genes reported m the sclentlfic and patent literature over the past few years, mostly becauseof the genediscovery programs of companiesmvolved m Bt blomsectlclde and transgemc plant development, has prompted the adoption of a new nomenclature system that categorizesthe encoded Cry proteins on the basis of ammo-acldsequenceidentity (9), rather than on msectlcldal activity (IO) The Cry proteins of Bt, also referred to as &endotoxms, comprise a diverse group of msectlcldal agents. As of this writing, there are -70 different classes/subclasses of Cry proteins, representing at least four distinct protein families that have apparently co-evolved toxicity toward insects (II). Cry proteins with toxtclty toward leprdopteran, dlpteran, and coleopteran insect larvae have been well documented. Proteins with toxicity toward nematodes,protozoans, flatworms, and mites have also been reported (22). Strategies for identifying new Cry proteins and their genes rely heavily on bioassay screening and on molecular methods employing the polymerase chain reaction (PCR) or colony blot hybridlzatlon and gene-specific ohgonucleotldes as PCR primers or as hybridization probes (13-15) Insect colonies resistant to certain classes of Cry proteins (26) can be particularly valuable m ldentlfymg toxins with different modes of action Recent reviews are available that discuss cry gene expression m Bt (27,18), cry gene dlverslty and evolution (12,19), and Cry protein structure and function (20). 3. Development of a Successful Bioinsecticide The emergence of Bt as a successful blomsecticlde necessitated technical advances m a number of dlsclplmes outside of molecular biology. Among those
Bt. Bioinsecticide
Products
191
key developments was the lsolatton of strain HDl (21), a kurstakz strain with potent toxicity toward a number of important lepidopteran pests, which for many years has been a standard mdustrtal production strain. Other important developments included the adoption of an international standard for potency, improvements in fermentation yield, the introduction of standardized, and, subsequently, more concentrated formulattons, and developments m field apphcation technology (3). Finally, the tdentificatton of Bt strains with toxtctty toward dipteran (22) and coleopteran (23) pests expanded the use of Bt-based btoinsecttctdes to other markets. Most Bt-based btoinsecttctde products are produced using naturally occurrmg strains of Bt, and utrhze only a small fraction of the known Cry proteins. In the United States and Canada, derivatives of Bt strain HDl subsp kurstakz have become the major pesticide used to control the gypsy moth, Lymantrla dlspar (24), and the spruce budworm, Choristoneura fumzferana (3), respectively. Examples of strain HD 1-based products for forestry use are marketed under the registered product names Foray@ 48B and Dtpel@ 6AF (Table 1) Other forest pests controlled by Bt include the nun moth (Lymantrza monacha), the Asian gypsy moth (L dispar), the pme processtonary moth (Thaumetopoea pztyocampa), and the European pine shoot moth (Rhyaczonzabuohana) (25). Bt products based on Bt subsp zsraelensis(“Bti”) have proven to be effective m the control of mosquitoes and black flies worldwrde (26). Examples of registered Bti-based products include Vectobac@(Abbott), Bactlmos@(Solvay/ Duphar), Teknar@ (Therm0 Trtology), and Skeetal@(Abbott). In agrtculture, Bt products have been used successfully m the vegetable, cotton, and specialty crop (frurts, nuts) markets, almost exclustvely for the control of fohar-feeding leptdopteran pests. Although this use 1slimited, compared to that of conventional msectictdes, renewed interest in integrated pest management to slow insect-resistancedevelopment, public concern about conventtonal pesticide use, and the rising costs of developing new synthettc msecttcides all suggest that this btologtcal control agent will become increasingly important in the years to come. Table 1 provides a listing of some of the better-known Bt-based biomsectictde products, as well as some recently registered products. 4. Opportunities for Improving Bt-Based Bioinsecticides Htstorically, several factors have limrted the use of Bt m plant protectton, particularly m agriculture Bt strains have a narrow spectrum of msecttctdal activity when compared to conventional msecttctdes, typically exhtbttmg slgnificant toxtctty toward only one order of insect species. Even wtthm an order of insects (e.g., Lepidoptera), dramatic differences in sensitivity are exhibited among species. For instance, the beet and fall armyworms (Spodoptera spp) are notortously difficult to control with Bt-based biomsectlcides based on strain
Baum, Johnson, and Carlton
192 Table 1 Registered
B&Based
Bioinsecticide
Products
Strain
Product Able Agree BlobIt Bactospeme Condor Costar CRYMAX Cutlass Design Dlpel Foil Foray Florbac Futura Javelin Lepmox MATTCH MTRAK MVP Novodor Raven Steward Thurlcide Trident Vault Xentari
for Agricultural
Use
Insect
background
CompanyC
order
kurstakl azzawai HD 1 kurstakz kurstakc kurstakl kurstakl kurstakz kurstakz alzawal HD 1 kurstakz kurstakz HD 1 kurstakz azzawal kurstakl HDl kurstah kurstaki Pseudomonas Pseudomonas Pseudomonas tenebrlomb kurstakl HD 1 kurstakr HD 1 kurstah tenebnoms HD 1 kurstakz aizawal
Therm0 Trlology Therm0 Trlology Abbott Abbott Ecogen Therm0 Trlology Ecogen Ecogen Therm0 Trlology Abbott Ecogen Abbott Abbott Abbott Therm0 Trlology Ecogen Mycogen Mycogen Mycogen Abbott Ecogen Therm0 Triology Therm0 Trlology Therm0 Trlology Therm0 Triology Abbott
L L L L L L L L L L L/C L L L L L L C L C L/C L L C L L
Comments Transcorqugant Bt TransconJugant Bt -
Recombinant Bt Transcoqugant
Bt
Transcotqugant Bt Transcoqugant Bt Recombinant Bt EC” EC EC Recombinant Bt -
“Encapsulated crystal proteins. %enebnoms = subspecies mormonc ‘Abbot Laboratories, Chlcago, IL, Ecogen, Inc , Langhome, PA, Mycogen Corp , San Dlego, CA, Therm0 Trilogy Corp , Columbia, MD L, lepldopteran-toxw, C, coleopteran-toxvz
HDl,
but the tobacco budworm (Helzothu vzrescens) and the diamondback xylostella) are not. In agriculture, these sensitlvlty dtfferences have a sq+?cant impact because multispecies pest complexes are typically the rule rather than the exception. In contrast, the speclfictty and safety of Bt 1s an advantage m the forestry and vector control markets, m which major target pests are fewer m number, and in which Bt-based btoinsectictdes are sprayed on relatively complex ecosystems, where nontarget orgamsms abound.
moth (Plutella
Bt Bioinsecticide Products
193
The efficacy of Bt is also limited by the nature of its mode of action. The Cry protems must be Ingested m order to effect mortality. The longer the Cry protem is presented to feeding larvae, the greater the chances for insect control. Thus, the efficacy of Bt-based bioinsecticides is affected by the timmg of spray application, spray coverage, larval feeding behavior, the ram-fastness of the formulation, and by the inactivation of both the spore and crystal by sunlight Improvements m Bt formulation can address many of these issues, including sunlight inactivatron (27). Encapsulation of crystal proteins within the host cell has been advanced as a means to improve persistence (28,29), yet the major environmental factor impactmg field persistence of Bt Cry proteins is almost certainly UV light (30,31), and encapsulationper se offers no protection against UV mactivation. Indeed, reports of a twofold increase m foliar persistence of encapsulated Cry protems (28) may not be as dramatic as improvements in msecticrdal potency and Cry protein yield resulting from genetic manipulation of the Cry protein genes m Bt (see Subheading 7.)
5. Genetic Manipulation of Bt The genetic manipulation of cry genes m Bt offers a promising means of improving the efficacy and cost-effectiveness of Bt-based bioinsecticide products. Certain combmations of Cry proteins have been reported to exhibit synergistic toxicity toward lepidopteran (32,33) and drpteran pests (34-36). In addition, the presence of spores can also synergize the activity of Cry protems against certain lepidopteran pests (37-40), and may forestall the development of msect resistance to Cry proteins (38). The contrrbution of the spore to Insect mortality, and its posstble utrlrty m resistance management, has been largely ignored by those advocating the expression of cry genes in alternative hosts. Other factors may contribute to the entomopathogemc character of Bt, mcluding the vegetative insecticrdal proteins (VIP) (#I), a-endotoxm (42), and a variety of secondary metabohtes (43), including Zwittermycm (44,45). These too may be amenable to genetic manipulation. The cry genes are almost exclusively localized on large plasmids (46,47), frequently on multiple plasmids, some of which can be transferred from one Bt strain to another by a conjugation-like process (4849). Thus, the natural processes of plasmid curing and plasmid transfer have been used to construct transconlugant strains with improved msecticidal properties (50). The curing and transfer of native or resident cry plasmids has hmrtattons, however, from the standpoint of product improvement. Most cry genes are not readily transferred by conmgal transfer. Furthermore, cry genes tend to be linked on the same large plasmrd (e.g., the -110 MDa plasmid of strain HDI, the -75 MDa plasmid of Bti), so that genes encoding superior toxins (for a partrcular target pest) cannot be readily separated from genes encodmg inferior toxins.
194
Baum, Johnson, and Carlton
The use of recombmant DNA methodologies can circumvent these problems associated with Bt strain improvement. In addition, the ability to transfer cloned genes into Bt means that modified Cry proteins engineered for improved productron or toxicity can now be readily used as active ingredients. Coqugation (48,49) and transduction 1.51)have been used to transfer recombinant plasmids from a donor Bt to a recipient Bt; however, the preferred method of gene transfer employs the use of electroporatron, for which numerous protocols are available (see ref. 50 for review). A variety of Eschenchm c&z-Bt shuttle vectors have been constructed to facrhtate the mtroduction of cloned cry genes in Bt Some of these employ plasmid rephcons derived from other Gram-positive bacteria (e.g., pBC 16, pC 194); others employ rephcons isolated from native Bt plasmtds (52-54) In addition to these shuttle vectors, mtegrattonal vectors have been used to insert cloned cry genes into resident plasmtds (55,56), or mto the chromosome (57), by homologous recombmatron Figure 1 illustrates the use of a temperature-senstttve mtegratronal vector for thrs purpose. In several Instances, the transfer of a cloned cry gene mto a Bt host strain has resulted in an improved spectrum of msectlcidal toxicity (52,54,55,57) Heterologous promoters may be used to improve the expression of certain cry genes, mcludmg the promoters for the B. subtrlzs a-amylase gene (54), cry3Aa (18), and cry3Bb (17). Unlike most cry genes, the cry3A’a (and presumably cry3Bb) gene IS sporulation-independent and is induced or derepressed during stationary phase, presumably by transition-phase regulators (for reviews, see refs. 2 7 and 28) The use of these sporulatron-independent promoters may be useful in improvmg the production of sporulation-dependent Cry proteins Homologous recombmatron may be used, not only to integrate cry genes mto a resident plasmid, or mto the chromosome, but also to disrupt genes of interest Integrational vectors based on temperature-sensitive plasmid rephcons, such as pE194ts (58), are well suited for this purpose Examples of successful gene disruption experiments mclude disruptions of cytlA (cytA; 59), cryilA (cry1 VD, 60) hknA (61), spoOA (62), and apr (63), an alkaline protease gene m Bt. Dtsruption of spoOF (64) and a mutation m an uncharacterized spo0 gene (62) have each been shown to increase the productron of Cry3Aa encoded on a native plasmid by -2.5-fold. Dtsruption of apr by homologous recombination has been shown to enhance the production of Cry1 proteins m some instances (63). The use of recombination m Bt strain development was advanced further by the deployment of a site-specific recombination (SSR) system, to selectively delete ancillary or foreign DNA elements (e g , antibiotic resistance genes) from recombinant cry plasmtds after their mtroduction mto a Bt host (65,66) This SSR system IS composed of the TnpI recombmase of Tn.5401 (67,68) and its cognate site-specific recombmatton site, or internal resolution site (IRS)
Bt: Bioinsecticide
Products Of/-f.5
f
195 cat 1
restdent plasmid
Integrated
gene
Fig 1. Schematic diagram depicting the use of homologous recombmatlon to target cloned genes to specific genomic sites m Bt, employmg a pE 194ts mtegratlonal vector A cloned cry gene (solid box) IS subcloned mto a target DNA fragment (shaded) having sequence slmllarlty with a Bt plasmid or chromosome Preferably, at least 1 kb of target DNA 1spresent on either side of the cloned cry gene. Recombmatlon m Bt 1s allowed to occur by cultivating the recombinant strain at 30°C under selection for chloramphemcol resistance Subsequent plating under chloramphemcol selection at 41°C, the restrlctlve temperature for pEl94ts replication, allows for the isolation of colonies m which recombmation has occurred. Indlvldual colonies are then cultivated m 200 mL of 1X bram-heart mfuslon (Dlfco Laboratones, Detroit, MI), 0.5% glycerol (BHIG) at 3O”C, with subsequent passages m 2 x 200 mL of BHIG at 4 1‘C, to allow for resolution of the co-integrate intermedlate and loss of the temperature-sensitive mtegratlonal vector, giving rise to two possible outcomes that may be dlstmgulshed, for example, by PCR amphfication using flanking primers (arrowheads) and subsequent restriction enzyme analysis Structural maps of two E. co/z-Bt shuttle vectors, contammg duplicate copies of the IRS, are depicted m Fig. 2. The SSR plasmlds pEG939 and pZG940 are distinguished only by the Bt plasmld replication orlgm used to ensure stable maintenance m Bt. In this gene-transfer system, depicted m Fig. 3, a cry gene 1s inserted rnto the SSR vector, and introduced into a suitable Bt host by selectmg for tetracycline resistance The resulting recombinant strain is then trans-
196
Baum,
Johnson,
and Carlton
Sfil - Eagl . Clal Sstl Xhol BamHl Bhll Smal Asp71 8 Pstl Yh3l i
-___-.
pTZ19u
\
Xbal Sfil Salt (NsPISP) ’
B Sfil Eagl Sphl Hpal Clal Sstl Xhol BamHl Blnl Smal Asp71 8 Pstl Xbal
9u
Fig. 2. Schematic diagrams of the Bt-E. coli shuttle vectors pEG939 (A) and pEG940 (B). The pTZ19u fragment contains a replication origin functional in E. coli and the b-lactamase gene-encoding ampicillin resistance. Designations: oui43 and ori = Bt plasmid replicons (82), tet = tetracycline-resistance gene from the B. ce7eu.s plasmid pBC16, IRS = internal resolution site region from Tn5401 containing the TnpI recombination site. The restriction endonuclease sites Asp718, BamHI, BlnI, PstI, SmaI, SphI, and X/z01 (bold type) occur only once in the plasmids.
Bt: Bioinsecticide Products
197
IRS ori-Ec
cat
amp
tet
IRS
ori- ts 30 c tnpl
~
b
cat 37 c ori-ts
tnpl ori
pEG348 A
recipient cell Fig. 3. Use of the SSR vector system to introduce cloned cry genes into Bt. A crylC gene was inserted into the SSR vector pEG940 to yield plasmid pEG348. Plasmid pEG348 was introduced and maintained in Bt by selecting for tetracycline resistance at 30°C. The temperature-sensitive plasmid pEG922, encoding the Z’npI recombinase, was introduced into the recombinant strain by electroporation, selecting for chloramphenicol resistance at 30°C. The introduction of pEG922 resulted in expression of the TnpI recombinase, and a subsequent site-specific recombination event between the duplicate copies of the IRS. Plating of the recombinant strain at 37-41”C allowed for the isolation of colonies that have lost pEG922, but have retained the crylC plasmid pEG348A. Designations: amp, ampicillin resistance gene; ori-Ec, E. coli replication origin; cat, chloramphenicol acetyltransferase gene conferring chloramphenicol resistance. Other designations are described in Fig. 2.
formed with the temperature-sensitive Tn.5401 vector pEG922 (67), this time selecting for chloramphenicol resistance. The TnpI recombinase protein encoded by Tn5402 catalyzes the recombination event between the duplicate copies of the IRS on the cry-encoding SSR plasmid, resulting in the deletion of the E. coli replicon, ampicillin
resistance gene, and tetracycline
resistance gene,
198
Baum, Johnson, and Carlton
Table 2 Recombinant Bt Bioinsecticide Products Product
Strain
Raven
EG7673
CRYMAX
EG7841-I
Lepinox
EG7826 construct 11724
cry genes (no ) crylAc (2) cry3A cry3Bb” ciylAc (3) cry2A crylca crylAa crylAc (2) cry2A
US EPA reglstratlon January 1995
February 1996
December 1996
cryIF-IAc” “Encoded by recombmant plasmld
and the generation of a cry plasmld composed of a CT gene, a Bt plasmld rephcation origin, and a vestigial copy of the Tn5401 IRS region. The Tn.5401 vector pEG922 1ssubsequently cured by cultivation of the recombinant stram at 37’C, the restrlctlve temperature for pEG922 rephcatlon (67). The resulting recomblnant Bt strain contams only the modified cyyplasmld, and 1sfree of foreign DNA elements. This gene transfer system has been employed m the development of several new Bt-based blomsectlclde products (see Table 2). A stmllar SSR plas-
mid based on the Bt transposon T&430 has recently been described (69) 6. Bioinsecticide Products Based on Genetically Modified Bt Strains A number of bloinsecticlde products are based on transconjugant strains of Bt, including Agree @,Condor@, Cutlass@,Design@, and Foil@ (Table 1) For the constructIon of Condor and Cutlass, a self-transmissible cry1A plasmld from an aizawaz strain was transferred via conjugation to a kurstakz recipient strain. In the case of Agree/Design, a cry1 plasmld from a kurstaki strain was transferred to an alzawaz recipient strain. The active ingredient m Foil OF,
strain EG2424, produces both Cry1 AC and Cry3A protein, and exhibits toxlclty toward both lepidopteran and coleopteran pests This expanded insecticidal host range was accomplished by transferring a -88 MDa Cry3A-encoding plasmid from EG2 158 subsp mormoni to an HD263 subsp kurstakz-derived reclpl-
ent strain (50). The yield of Cry3A protein in large-scale production has been increased through the use of genetically modified strains. Bt strains used to produce Novodor@ FC (NB 176) and Foil BFC (an EG2424 variant) exhibit an oligo-
Bt. Bioinsecticide
Products
199
sporogenous phenotype and produce unusually large rhomboid crystals composed primarily of Cry3A protein Strain NB 176 was obtained by gamma Irradlatlon of Bt tenebrionls strain NB 125 (70); the Foil BFC strain was isolated as a spontaneous variant (Ecogen, unpublished data) The Cry3A overproduction phenotype of these strains appears to be caused in part by the sporulatlon-mdependent nature of cry3A expression, the prolonged synthesis of Cry3A protem during the terminal stationary phase of asporogenous cells, and the absence of sporulatlon-dependent proteases m asporogenous cells (17,18, 61,62,6#). In the case of Novodor stram NB176, a duphcatlon of the cry3A gene on its native plasmid probably contrlbutes to Cry3A overproductlon (56). 7. Bioinsecticide
Products Based on Recombinant Bt Strains Field testmg of recombmant Bt strains began m 1990, with small plot trials conducted by Sandoz Crop Protection. Since that time, a number of companies, including Abbott (711, AgrEvo USA (72), CIBA (73), Ecogen (74), and Sandoz Agro (75) have pursued the development of recombmant strams for commercial use Currently, there are three blomsectlclde products based on recombinant Bt strains that are registered with the US Environmental Protection Agency (EPA) (Table 2). In general, the reglstratlon of these products was obtained within 1 yr of submlsslon of the registration packet to the EPA. It may be concluded that there IS no serious impediment to the registration of recomblnant Bt-based biomsectlcldes of this nature m the United States.A brief descriptlon of the recombinant strains follows. The T&401-derived SSR system (described above) was used m the construction of strain EG7673, a recombmant Cry3-overproducmg strain that was approved as the active mgredtent m Raven TM Biomsectlcide by the EPA m January of 1995. Strain EG7673, contammg the recombinant cry3Bb plasmld pEG930.96, produces 3-4 times more Cry3 protein than the progemtor strain EG2424, the active mgredlent m Foil OF bloinsecticlde (66). This increase m crystal protein yield, presumably caused by the high copy-number of the cry3Bb plasmid (I 7), allows for more cost-effective use of this product for the control of Colorado potato beetle (Leptinotarsa decemlineata) larvae. The construction of CRYMAX strain EG784 I- 1 (Table 2) involved a series of genetic manipulations that included plasmid curing, conJugatlon, transformation, and site-specific recombmatlon. EG7841-1 IS a derivative of strain EG3 125, a naturally occurring kurstakz strain Isolated from a North American gram dust sample. EG3 125 contains two crylh genes and a cry2Aa gene on a - 110 MDa plasmid and a cry/& gene on a -46 MDa plasrmd. A cured denvatlve of EG3 125 missing the 46 MDa plasmld, designated EG60 12, was used as a recipient m a series of conJugation experiments to Introduce cry-encodmg plasmlds from other strains of Bt. One transcoqugant, designated EG4923,
200
Baum, Johnson, and Carlton
was Identified as having improved msecticldal actrvrty compared to EG3 125 m quantitative broassaysagainst a variety of leprdopteran pests.The introduced plasmrd m EG4923, a 56 MDa plasmid from Bt strain HD74 (761, encodes a crylAc gene, Thus, EG4923 contains an unusual cry gene cornpositron: three cryIAc genes and one cry2Aa gene. The multtple copres of crylAc allow for hrgher levels of Cry1 AC production than can be achieved with strains harboring a single cryZAc plasmtd (e.g., HD73). A spontaneous colony morphology variant of EG4923 recovered from a starch agar plate was found to produce 30-40% more Cry1 AC protein than strain EG4923. This uncharacterrzed EG4923 variant was subsequently used as a host strain for the mtroductron of a cloned crylC gene on plasmid pEG940 (Fig. 2B) by the method described above (Fig. 3). The resulting recombmant strain, EG7841-1, produced an additional -30% more Cry1 protein than the progenitor strain n-r small-scale fermentation, using a standard productton medium. Since the CrylC protoxm migrates slower than the Cry1 AC protoxin on SDS-polyacrylamide gels, the proportion of Cry 1C protoxin could be estrmated to be 30-40% of the total Cry 1 protem. Transcrrptron of the cry1 C gene from its native promoter on plasmrd pEG940 did not adversely affect cell growth or sporulatron Accordmgly, rt IS not necessary to use heterologous or sporulation-independent promoters to ensure increases in Cry1 production or effictent sporulation (77). A WDG (water-dispersible granule) formulation prepared by extrusron of the cell paste, as opposed to spray drying, provides CRYMAX WDG with desirable handling properttes and good coverage of folrar surfaces. Extensive field trtals with CRYMAX have demonstrated excellent efficacy when compared to other btoinsectrcrde products at recommended usage rates. CRYMAX WDG at 0.5 lb/acre was equivalent to Xentarr WDG at 1 lb/acre, and superior to MATTCH at 1 qt/acre for the control of the cabbage looper, Trzchopluszanz (Fig. 4). Furthermore, CRYMAX WDG at 0.75-l lb/acre provided better control than either Xentarr at 1 lb/acre or MATTCH at 2 qt/acre. Against diamondback moth populatrons showing resistance to Cry1 A- and Cry1 F-type proteins, CRYMAX WDG provided superior crop protection when compared to the azzawazproducts Xentart and Florbac, and comparable control when compared to the chemical msectrcides Agrrmek@ and Regent@(Fig. 5). The Cry 1C protem in CRYMAX contributes to rts toxicity toward armyworms: Against the yellowstrtped armyworm, Spodoptera ornithogalb, CRYMAX at 0.5 lb/acre provtded supertor crop protectton (Fig. 6) when compared to either Xentari (1 lb/ acre) or MATTCH (2 qt/acre), two products that also contain Cry1 C protem. Lepmox strain EG7826 construct 11724 (Table 2), a derrvatrve of Condor strain EG2348, was constructed using a Tn.5401-based SSR plasmrd contammg a chrmerrc cryZF’vyZAc (crylF-IAc) gene. The encoded fusion protein
Bt. Bioinsecticide
Products (field
Ambush
teals from Jan 1994 - Aug
1995)
2EC 0 I lb a.1 /a
MATTCH
2 0 qtla
MA’II
CH I 0 qtla
Xentari
WG I 0 lb/a
CRYMAX
I 0 lb/a
CRYMAX
0 75 lb/a
CRYMAX
0 5 lb/a
0
20
40
60
60
100
Mean Percent Control (range)
Fig 4. Field efficacy of CRYMAX WDG for control of the cabbagelooper. Sumof small plot trials employmg a randomizedcomplete-blockdesign (RCBD)
mary
contains a portion of the carboxyl-terminal half of Cry1 Ac Introduction of cryIF’-ZAc into the Condor host background resulted m a 25% mcrease m Cry 1 production when compared to a Condor recombinant stram containing the native cryZF gene. This yield increase IS presumed to be a result of more efficient crystal formation with the resident CrylA proteins in strain EG2348, an attribute presumably contributed by the Cry 1AC portion of the fusion protein. Expression of the cry1 F-IAc gene did not adversely affect cell growth or sporulatlon. In field trials on sweet corn (Fig. 7) and bentgrass (Fig. S), Lepmox WDG provided superior control of the fall armyworm, Spodoptera frugiperda, when compared to Condor OF, and equivalent control when compared to the chemical standards Lannate@and Scimitar@,respectively. Although different formulations were tested, the difference m field efficacy between Condor and Lepmox is representative of other comparisons using equivalent formulations, and reflects the improved potency toward S. fmgiperda contributed by the Cry1 F toxin. 8. Conclusions These developments underscore the validity of genetic manipulation as a means to improve efficacy/cost-effectiveness, and to expand the markets for Bt-based biomsecticrdes. A variety of methods may be used to introduce and stably maintain cloned cry genes, and in vlvo recombmatlon techmques may be used to delete or otherwise modify resident genes in Bt. These manipulations can result in strains with improved crystal protein production and msectl-
202
Baum, Johnson, and Car/ton 25 45, z 4g 35% 3$ 251 2rB Y
1.5
4
0.5..
5
4 05
-
175
1 94
;:33
4PI 2
123
l-
o-
~$~~~~q i
0 2”6
6 3Pl
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1li
5I
30 generations, and 1s approx 1O,OOO-foldresistant (50). One gene m linkage group nine (51) contrtbuted over 80% of the resistance m this strain. 2.4. Transgenic
Cotton: The Future
There is a need for better control of bollworm on cotton than 1snow provided by the available 6-endotoxin gene constructs. Either different &endotoxm genes or entirely different genes are needed. Control of fall armyworm and beet armyworm 1s not sufficient with present F-endotoxin genes, Although control of tobacco budworm and pink bollworm are quite good wrth the present
Transgenic
Plants
Expressing
Bt Toxins
219
&endotoxin genes, additional &endotoxin genes or genes of a drfferent nature are needed for long-term resistance management The companies developing transgenic cotton technology operate m a global market. There IS a great likelihood that transgemc cotton culttvars ~111be utthzed m most major cotton-producing countries around the world. In all countries that produce cotton, there ISa need for control of leprdopteran msects,and thts technology provrdes very effective control. The prospect of global use of transgenic Bt cotton places greater emphaseson the need for resistance-managementstrategies. 3. Transgenic Corn 3.1. Hisfory and State of the Art Using microprojecttle bombardment of immature embryos, scienttsts at CIBA Brotechnology successfully placed a synthetic gene encodmg a truncated version of the CrylA(b) protein derived from Bt mto corn plants (52). Chmese screntrsts have also used mrcroprojecttle bombardment of matze cell suspensions, immature embryos, and embryogemc call1 to transform a gene from Bt into maize, and have regenerated plants, some of which expressed the toxin when evaluated agamst the corn borer, Ostrima jiirnacalls (53) Ovaries of maize inbred lures have also been transformed with the insectresistance cvylA gene from Bt (54’. This was accomplished by iqectmg ovarres on the ear 10-20 h after pollmatton with a lO--loo-pm drameter glass needle containing l-3 pL DNA solution. From 40 ovaries mjected on each of 2 16 ears, four plants carried reststanceto European corn borer m the next generation. From 12 independently transformed hnes of transgentc matze expressmg the CrylA(b) msectlctdal protein from Btk, scientists at Monsanto were able to show that eight had significantly less damage to ears, and three lines exhibited a 75% reduction in feeding by H. zea larvae, which were also stunted in growth. Concentratron of the CtylA(b) protein was 0.0-l .28 pg/g fresh wt of silks (55). Williams et al. (56) evaluated field plots of transgemc corn plants expressmg &endotoxin msectictdal proteins for southwestern corn borer, Dzatraea grandzosella Dyar, and fall armyworm, Spodoptera frugiperdu (J. E. Smnh). These transgenic hybrids offer a high level of resistance to fall armyworm, and near tmmumty to southwestern corn borer. These transgemc corn plants have the htghest levels of plant resistance documented to these two insects. Transgemc corn lines have also been evaluated in the field for resistance to the European corn borer where both first-generation leaf-feeding and second-generation stalk tunnelmg have been observed (.57,58). 3.2. Registration and Commercialization of Transgenic Corn A truncated version of a cryZA(b) gene expressed m ehte hybrrds of maize provided excellent protectton against European corn borer (0. nubzlalis) when
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challenged with over 2000 larvae/plant m the field (57). These transformed maize plants were different from most other plants expressmg 6-endotoxm genes, because these maize plants had a maize-optimized gene plus a ttssuespecific promoter, which targeted the cry1 A(b) productton to plant ttssue relevant for control of European corn borer. These plants were first grown on a commercial scale for seed productton m 1996. In 1996, transgenic corn hybrids expressmg the cryld(b) gene were sold by Mycogen (NatureGard) and CIBA (Maximizer) to growers for control of European corn borer. Transgenic corn hybrids were available to growers on a large scale m 1997. These contain the crylri(b) gene and are available from several compames. The U.S. Environmental Protection Agency (EPA) has granted three registrations for transgenic corn, Mycogen event 176, Northrup King event BT 1I (YieldgardTM, and Monsanto event MON8 10 (Y ieldgard). Expression of the Mycogen event 176 is low m the silks and ear. Expression of the event NKBTl 1 and MON810 are such that all plant parts express the toxic protein as the CaMV35S promoter is used with the gene. EPA registration requirements for these corn hybrids mclude parts of a resistance-managementplan. Mycogen is required to monitor for changes in level of response of corn borers to &endotoxm, and to continue to collect data and report to EPA. In addition, a resistance-management plan that includes a refuge must be developed by the year 2000. EPA required these same elements as conditions of registration of the event NKBTl 1 from Northrup Kmg. There were, however, two additional requirements: The corn hybrids with this event could not be sold m the South, where cotton is grown, and data were required to be obtained, to better understand the relationship of resistance development in H zeu. These two additional requirements are related to the fact that H. zea feeds on both corn and cotton. The gene in the NKBTI 1 has the CaMV35S promoter and expressesin the silks and the ear, as well other plant parts. The event MON8 10 was m hybrids sold by Pioneer, Cargtll, and Golden Harvest m 1997. EPA required all the above elements for registration of MON8 10 (Yieldgard). In addttion, Monsanto was required to collect data to validate a resistance management model Monsanto also voluntarily placed one additional requirement on the use of its Yieldgard product A refuge must be maintained on each farm that grows the product. This applies to all companies that license the product and the growers to whom they sell hybrids. Thus, EPA placed a requtrement on all three transgemc corn genes that some elements of a resistance-management plan be developed and a plan with a refugia be in place by the year 2000. 3.3. The Future of Transgenic
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Expectations are that acreage of transgenic corn will expand. Current research is underway to find genes other than &endotoxm genes to use for insect con-
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trol in corn. Rootworms and cutworms are major pests of corn that are somewhat recalcttrant to the presently used family of Bt 6-endotoxms. The Vtp proteins produced during the vegetattve phase of growth of certain Bacillus spp strains may prove to be useful for control of these pests. 4, Transgenic Potato and Eggplant A modified version of a 6-endotoxin gene, cry.%4from Bt var tenebrzonzs was used to transform potato plants, Solarium tuberosum L. (59). This conferred resistance to Colorado potato beetle, Leptinotarsa decemlineata Say, under high levels of natural field infestatron. This transformation was accomplished in Russet Burbank potato cultivar without any loss in agronomtc or quality charactertsttcs. Transgenic potatoes reststant to Colorado potato beetle were first grown commercially in the Umted States m 1995, and performed very well in the field. Transgenic potato plants containmg a redesigned cvy3A gene under the mfluence of the CaMV 35Ymannopme synthetase promoter show high levels of resistance to Colorado potato beetle. The level of insect control was highly correlated with the level of Ei-endotoxm RNA and protein (60). Plants transformed with the crylA(c) gene from Bt, strain HD-73, expressed a moderate level of leaf-feeding reststanceto the tobacco hornworm m laboratory tests (61). The potato tuber moth, Phthorminaea operculella Zeller, is a major pest of potato in the tropics and subtropics. Commercial lmes of potato transformed wtth a codon-modified cry5 gene from Bt have shown high levels of reststance, and other transgenic lmes expressing the wild-type cry1 gene have shown reduced leaf feeding by the potato tuber moth (62). The transgenic potato, NewleaF”, was the first transgemc crop plant wtth a gene from Bt to be registered by EPA. It expressesthe cry3A gene, with Colorado potato beetle as the target pest. Toxic Bt protein IS not widely used as a spray product on potatoes, because rt is only effective against early mstars of the insect. In contrast, the transgemc potato plant is considerably more effective for control of this pest. As a condition of registration, EPA requtred the developing company to continue to do research on resistance management, to monitor where the NewLeaf potatoes were planted, and to monitor for shafts m levels of susceptibility to the toxin. Data from these are to be reported to EPA. In additton to this, Monsanto voluntarily placed a requirement on growers that no more than 80% of then crop could be planted with the transgemc potato. The Colorado potato beetle feeds on several plants of the genus Solanum. Eggplant, Solarium melongena L., has been transformed wtth a synthetic cry3A gene from Bt via A. lumefaciens-mediated transformation. From 300 plants, 175 were confirmed to be transformed, and some exhibited htgh levels of resistance m the field when arttfictally infested with egg massesof Colorado potato
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beetle. Progeny from resistant plants with a single msertion segregated m typical Mendehan fashion (63). 5. Transgenic Rice A modified cryiA(b) gene from Bt has been inserted into a rice, 0 satzva L, Japomca cultivar, and confers resistance to two maJor rice insects, rice leaffolder, Cnaphalocrosis medlnalils, and striped stem borer, Chllo suppressalzs (64) This shows that genes from Bt should be useful m developing insect-resistant culttvars for specific insects m rice. The gene m race is extensively modified, and is a truncated version of the gene, based on codon usage m known rice genes The gene was mtroduced mto embryogernc rice protoplasts by cotransformation with the hygromycm-resistant selectablemarker gene 6. Transgenic Tomato Insect-resistant transgemc tomato, Lycoperszcon spp, developed m 1987, IS tolerant to tobacco hornworm, tobacco budworm, and bollworm (65). This same research suggested the feasibility of genetically engineering msect-tolerant transgemc crops by expressing the insect control proteins from Bt, and opened the way for research in cotton and corn. A truncated version of the gene from the HD-I strain of the bacteria was more effective than the full-length version of the gene m expressing the desired resistance trait m tomato plants Field tests of genetically engmeered tomatoes expressing a gene from Bt were conducted m 1987 m Illmois Plants were allowed to produce flowers and seed, and to decompose mto the soil. Similar tests were carried out with tomatoes m Florida and California m 1988 (66). Tomato plants were transformed to expressthe &endotoxm gene from Bt subsp tenebrionzs by exposing leaf disks to A. tumefaczens.These transformed plants expressedan msecticidal protein of 74 kDa that was active againstColorado potato beetle (67) Scientists m China have reported transformation of tomato with a CMV-cp genefor resistanceto a vnus and with a Bt gene for resistanceto insects Although their chemical data showed transformation, they did not report any F 1 or F2 data on resistanceof the plants to vnus or insects(68). 7. Transgenic Soybeans Soybean, Glyclne max L., was transformed via A tumefaciens, and plants were regenerated that expressed the transgenes (69). These plants expressed either the GUS gene or glyphosate tolerance inherited m a 3: 1 Mendehan fashion. These results showed that stable transformation was possible in soybean Somatic embryos of the soybean cultivar Jack were transformed using microproJectile bombardment with a synthetic Bt crylA(c) gene with the
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35s promoter gene linked to the HPH gene (70). These plants exhtbtted varymg levels of resistance to corn earworm, soybean looper (Pseudoplusza includens), tobacco budworm, and velvetbean caterpillar (Antzcarszagemmatalis Hubner). The corn earworm and soybean looper are more tolerant of the &endotoxm, thus, the transgenic plants were less resistant to these two pests than to the other two, which are more susceptible to the &endotoxm 8. Transgenic Trees The prospects for genettc engineering of insect resistance in forest trees was reviewed by Strauss et al. m 1991 (71). They suggested that, m addition to the Bt genes, other potentral strategies could mclude proteinase-inhibitor genes, chttmase, lectms, and baculovtrus genes. The &endotoxm of Bt m the form of CaMV 35S-Bt was stably transformed by electric dtscharge partrcle acceleratton into Populus alba x Populus grandldentata Crandon and Populus nlgra Betulifoha x Populus trzchocarpa hybrids. Transformed plants were highly resistant to feedmg by the forest tent caterpillar, Malacosonza disstria Hubner, and the gypsy moth, Lymantrza dlspar L. (72). Hybrid Populus plants (clone NC 5339), genetically engineered wtth a crylA(a) 6endotoxm gene, showed field resistance to forest tent caterpillar and gypsy moth, m the form of reduced feeding and weight gain; however, mortahty of late third-mstar larvae of gypsy moth drd not differ when fed on transgemc and control foliage (73). The gypsy moth IS a major pest of many forest trees around the world. Poplar, P nzgra L., trees have been genetically engineered to resist thts pest III China by transforming plants with A tumefaczensstrains carrymg a truncated gene from Bt driven by a CaMV35S promoter. Three transgenic clones were selected for resistance to gypsy moth and Apochemia czneraius, reduced morphologtcal changes, and promtsmg stlvrculture traits. These are under largescale field evaluation in SIXprovinces m China (74). Plants of poplar P alba x P grandidentata cv Crandon have been transformed to contain a truncated gene from Bt, plus the marze gene AC. Transgemc plants expressing AC and callus contammg the Bt gene were recovered (75). Transgemc plants contammg a modified Bt gene have been produced by transformatton and regeneration of excusedleaves of poplar hybrtd 741 (76). Populus deltoides plants were transformed using A. tumefaclens LBA 4404 strains contammg a gene from Bt, and two of three plants regenerated successfully integrated the Bt gene (77). The transfer and expression of the Bt toxin gene via A. rhz’zogenes-medrated transfer has been documented usmg Southern, Northern, and Western blots of needle tissue from transgemc plants of European larch trees, Larix decldua (78,79).
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9. EPA Registration and Resistance Management Several msecticldal Bt products have been used for over 30 yr as sprays for insect control. At one ttme, It was thought that use of these spray products would probably not select for resistant populations of insects. However, with their continued use on cabbage, resistant strains of dlamondback moth, Plutella xylostella L , have developed ($0). Strains of Indian meal moth, Plodra znterpunctella Hubner, resistant to the &endotoxms from Bt, have also been reported (Sl), Most transgemc plants developed to express the Gendotoxms have a constltutlve promoter. This causes the plant to express the toxic protein contmuously, and in most or all the parts of the plant. This has the potential to place a different level of selection on the pest population than pesticides apphed as sprays. This has raised the issue of development of reslstant populations of pest species. EPA has proposed the posltion that transgemc plants may produce a plant pesticide, and, if so, EPA has the authority to regulate and register these transgemc plants under the Federal Insectlclde, Fungicide, and Rodentlclde Act (FIFRA) (EPA proposed pohcy and rule announced November 23, 1994) (82). A concern that this 1snot the correct approach has been expressed by 11 scientific socletles with approx 80,000 members (83). Theprimaryconcernwith theproposedrule ISthecreationof anewcategoryof pestlclde,called‘plantpestlclde’,solelyfor thepurposeof regulationunderexlstmgstatutes EPA proposes to designate as ‘plant pestmdes all substancesresponsible for pest remtance In plants, as well as the genes needed for production of these substances Under Its proposed pohcy, however, EPA singles out for possible reglstratlon as ‘plant pestmdes only those traits Introduced Into plants usmg rDNA techniques (83)
EPA has placed different requirements on the three transgemc, insect-reslstant field crops (cotton, corn, and potato) approved for commercial use. This variation m requirements across crops has a basis m the host range of target Insects, acreage projected to be planted to the transgemc cultlvars, and the public risk perceived to be associated with development of resistance. There are some similarities m all requirements, as well as specific dlfferences required to be implemented m each crop. A major strategy for long-term use of conventional plant resistance has always Included multiple genes and new types of genes to breed mto the crop when Insect populations become resistant to the currently used genes. The companies involved with transgemc resistance are also actively working to develop addItiona toxic protein genes with different modes of action. These transgemc cultivars and hybrids should not be thought of as standalone products. They should be used as the foundation on which to build good IPM and crop management practices, Resistance management IS m Its infancy,
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and sctenttsts do not know how to best manage or slow the development of resistant strams of insects. There is a grand opportunity to learn much with the commercialization of three maJor transgemc crops. In the near future, msectresistance genes should be m crops that are not related to the &endotoxms. The use of two or more genes with different modes of action should be a maJor tool for sustaimng the vtabrhty of transgemc insect-resistant cultivars and hybrids. The use of IPM and crop management strategies will Improve as experience is gained with the cultivation of transgenic culttvars and hybrids as replacements for organic insecticides in pest control. The future looks bright, yet there is much to learn m this uncharted adventure to use biotechnology as a useful tool m plant breeding and in how to control pests on crop plants. 10. Future of Bt Transgenic Crops Movmg mto the future with plant biotechnology, genetically engineered plants that resist msects will use novel insecticidal principles to target tmportant insect pests that have escaped Bt technology (84). The arena of genetically engineered plants to control pests is very attractive. Costs associated with pestmanagement practices and chemical control of Insects approaches $10 billion annually (84). Even with this expenditure, these same authors estimate that 20-30% of global production 1s lost to insects. Advances m transformation, tissue culture, and expression of foretgn genes m plants have so improved that the potenttal exists to vtrtually transform any crop with a crop-tailored gene. The msecticidal genes from Bt led the way, and now additional genes from this bacterium, as well as novel genes from other genera, will be used to provide improved cultivars of plants that resist insects. In addition to the &endotoxms, a second class of protems effective against certain insects, some of which are not greatly affected by the cry genes, are the Vip insecticidal proteins produced by Bt during the vegetative growth of the bacteria. These proteins are dtstmct from the &endotoxm proteins and afford acute btoacttvtty in the range of ng/mL of diet for susceptible insects (8586). These genes are available for use in genetically engineered plants, Instead of, or in conjunction with, Gendotoxin genes, The clarified culture supernatant fluids collected durmg vegetative growth of other Bacillus species are also a rich source of insecticidal-activity Vip protems (4,85). These Vip proteins are a class of msecticidal protems dtstmctly different from the delta endotoxins. V1p111A from Bt show acute bioactivity m the nanogram range against a wide spectrum of lepidopteran insects, particularly black cutworm, Agrotis zpszlon(Hufnagel), fall armyworm, Spodoptera fruglperda (J. E. Smith), and beet armyworm, Spodoptera exzgua (Hubner) (85). This makes these proteins promismg candidates for use in conjunctton with the &endotoxins.
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5 Gasser, C and Fraley, R T (1989) Genettcally engineered plants for crop improvement Sczence 244, 1293-I 299. 6 Fraley, R (1992) Sustammg the food supply Bzo/Technology 10,40-43 7 Oerke, E C (1994) Esttmated crop losses due to pathogens, ammal pests and weeds, m Crop Productzon and Crop Protectzon Estzmated Losses In MaJor Food and Cash Crops (Oerke, E C , Dehne, H. W., Schonback, F , and Weber, A, eds ), Elsevier, Amsterdam, pp 72-78 8 Barton, K A , Whlteley, H R , and Nmg-Sun, Y (1987) Baczffus thurzngzenszs delta endotoxm expressed m transgemc Nzcotiana tabacum provides reststance to leptdopteran Insects Plant Physzol 85, 1103-I 109 9 Vaeck M., Reynaerts, A , Hofte, H , Jansens, S , De Beukeleer, M , et al (1987) Transgenic plants protected from Insect attack Nazure 328,33-37. 10 Klem, T M , Wolf, E. D , Wu, R , and Sanford, J C (1987) High velocity microproJecttles for delrvermg nuclerc acids into ltvmg cells Nature 327, 70-73 11 Chrtstou, P D , McCabe, E , Martmell, B J , and Swam, B J. (1990) Soybean genetrc engmeermg-commercial productron of transgemc plants Trends Bzotechnot 8, 145-151 12 Klein, T M , Arentzen, R , Lewis, P A., and Fttzpatrtck-McEllrgott. S. (1992) Transformation of microbes, plants, and animals by particle bombardment. Bzo/ Technology 10,286291.
13 Fmer, J J and McMullen, M D (1990) Transformatton of cotton (Gossypltlm hzrsutum L ) vta parttcle bombardment. Plant Cell Rep 8, 586-589 14 Tortyama, K , Arimoto, Y., Uchrmtya, H., and Hmata, K (1988) Transgemc rice plants after direct gene transfer mto protoplasts Bzo/Technology 6, 1072-1074 15 Rhodes, C. A , Pierce, D. A , Mettler, I J , Mascarenhas, D , and Detmer, J J (1988) Genetically transformed maize plants from protoplasts Sczence 240,204-207 16 Williams, S , Frtedrich, L., Dincher, S., Carozzr, N , Kessman, H , Ward, E , and Ryals, J (1992) Chemical regulation of Baczllus thurzngzenszs delta endotoxm expresston m transgenic plants. Bzo/Technology 10,541-543 17 Trolmder, N L. and Gooden, J R (1987) Somatic embryogenesis and plant regeneratton m cotton (Gossypzum hzrsutum L). Plant Cell Rep 6, 23 l-234 18. Umbeck, P , Johnson, G , Barton, K , and Swam, W ( 1987) Genettcally transformed cotton (Gossypzum hzrsutum L.) plants Bzo/Technology 5,263-266
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19 Jenkins, J N , Parrott, W. L , McCarty, J. C., Jr., Barton, K. A., and Umbeck, P. F (199 1) Field test of transgemc cotton contammg a Bacdlus thurzngzenszs gene. MLYS Agrx and For Exp. Sta Tech Bull 174, 14. 20 Perlak, Fredrlck J., Deaton, W R , Armstrong, T. A., Fuchs, R. L., Sims, S. R , Greenplate, J T., and Fischoff, D A (1990) Insect reslstant cotton plants. Blo/Technology 8,939-942 21 Perlak, F. J., Fuchs, R. L , Dean, D. A , McPherson, S. L , and Flschoff, D. A (1991) Modlficatlon of the coding sequence enhances plant expression of insect control protein genes Proc Nat1 Acad. Scz USA 88,3324--3328. 22 Benedict, J H , Altman, D. W., Sachs, E. S , Deaton, W. R , and Ring, D R. (1991) Field performance of cotton genetically modified to express msectlcldal protein from Bacdlus thurrnglenszs, in Proceedings Beltwzde Cotton Production Research Conference, San Antonio, TX(Brown, J , ed ), National Cotton Council of America, Memphis, TN, p 577. 23 Deaton, W. R (1991) Field performance of cotton genetlcally modified to express insecticidal protein from Baczllus thurrnglensu, mtroductlon, m Proceedzngs Beltwlde Cotton Production Research Conference, San Antonio, TX (Brown, J , ed.), Natlonal Cotton Council of America, Memphis, TN, p. 576 24 Gannaway, J R , Rummel, D R., and Owen, D F (1991) Field performance of cotton genetically modified to express insectlcldal protein from Baaflus thurznglensu, in Proceedings Beltwide Cotton Productron Research Conference, San Antonlo, TX(Brown, J , ed.), Natlonal Cotton Council of America, Memphis, TN, p 578 25 Jenkins, J N., Parrott, W L., and McCarty, J C., Jr. (1991) Field performance of transgemc cotton containing the Bt gene, m Proceedmgs Beltwzde Cotton Productzon Research Conference, San Antonro, TX(Brown, J , ed ), National Cotton Councrl of America, Memphis, TN, p 576. 26 Micmskl S and Caldwell, D W. (1991) Field performance of cotton genetically modified to express msectlcldal protein from Bacdlus thurlnglensls, m Proceedlngs Beltwlde Cotton Production Research Conference, San Antonio, TX (Brown, J , ed.), National Cotton Council of America, Memphis, TN, p. 578. 27 Micmskl, S., Caldwell, W. D., Fltzpatnck, B. J., and Griffin, R. C. (1992) First Loulslana field trial of insect-resistant transgenic cotton LA Agriculture 35, 8-l 0 28. Jenkms, J. N (1993) Use of Bacillus thuringzensis genes in transgemc cotton to control Lepldopterous insects, in Pest Control wzth Enhanced Environmental Safety (Duke, S 0 , Menn, J J , and Plimmer, J R , eds.), American Chemical Society Symposmm Series 524, Washington, DC, pp. 267-280. 29 Jenkins, J N (1995) Host plant resrstance to insects m cotton, m Proceedzngs of World Cotton Research Conference I Challengrng the Future (Constable, G A and Forrester, N W., eds ), Brisbane, AU, Feb 14-17, 1994, pp 359-372. 30. Benedict, J H , Sachs, E S , Altman, D. W , Rmg, D. R., Stone, T B., and Sims, S. R (1993) Impact of delta endotoxm producing transgemc cotton on msectplant mteractlons with Helzothts vzrescens and Hellcoverpa zea (Lepldoptera Noctuidae). Environ Entomol. 22, l-9 31. Wilson, F. D and Flmt, H M (1991) Field performance of cotton genetically modified to express msectlcldal protein from Bacillus thunnglenszs, m Proceed-
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Jenkins zngs Beltwlde Cotton Production Research Conference, San Antonzo, TX(Brown, J., ed.), National Cotton Council of America, Memphis, TN, p 579. Williamson, D R. and Deaton, W R. (1991) Field performance of cotton genetltally modified to express msectlcldal protem from Bacillus thunngzensu, m Proceedmgs Beltwtde Cotton Productton Research Conference, San Antonlo, TX (Brown, J , ed ), National Cotton Council of America, Memphis, TN, p 577 Trolmder, N L. and Xhixlan, C (1989) Genotype specificity of the somatic embryogenesls response m cotton Plant Cell Rep 6,23 l-234 Jenkins, J N , McCarty, J. C , Jr, Buehler, R E., Klser, J., Willlams, C , and Wofford, T (1997) Resistance of cotton with delta endotoxm genes from Bacdlus thurrngrenszs berlmer kurstakl on selected lepldoptera Insects. Agronomy J 89,768-780 Umbeck, P. G , Barton, K. A , Nordhelm, E V , McCarty, J C , Jr, Parrott, W L , and Jenkins, J N (1991) Degree of pollen dispersal by Insects from a field test of genetically engmeered cotton J Econ Entomol 84, 1943-1950 Jenkins, J. N , Parrott, W. L , McCarty, J C , Jr, Callahan, F E , Berbench, S A , and Deaton, W R (1993) Growth and survival of Hellothzs vlrescens (Lepldoptera* Noctuidae) on transgemc cotton containing a truncated form of the delta endotoxin gene from Bacillus thunnglensrs. J Econ Entomol 86, 18 l-l 85 Jenkms, J N , McCarty, J. C., Jr, and Wofford, T (1995) Bt cotton, a new era m cotton production, m Proceedings of Beltwrde Cotton Conferences, Blotechnology Workshop (Herber, D J. and Richter, D A , eds ), National Cotton Council of America, Memphis, TN, pp. 17 1-173 Durant, J. A (1994) Evaluation of treatment thresholds for control of bollworms and tobacco budworms in transgemc Bt cotton m South Carolina, m Proceedzngs ofBeEtwlde Cotton Conferences (Herber, D. J. and Richter, D. A., eds ), National Cotton Council of America, Memphis, TN, pp. 1073-1075 Mahaffey, J S , Bacheler, J. B , Bradley, J. R., and Van Duyn, J. W. (1994) Performance of Monsanto’s transgemc B T. cotton against high populations of lepldopterous pests m North Carolina, in Beltwlde Cotton Production Conference, San Antonro, TX(Herber, D. J and Richter, D. A , eds ), National Cotton Council of America, Memphis, TN, pp. 106 l-l 063. Fischoff, D. A. (1992) Management of Lepldopteran pests with insect reslstant cotton recommended approaches, in Proceedings Beltwlde Cotton Production Research Conference, San Antonlo, TX(Brown, J., ed.), Natlonal Cotton Council of America, Memphis, TN, pp 75 l-753. Gould, F. (1991) Arthropod behavior and the efficacy of plant protectants. Ann Rev Entomol 36,305-330. Forrester, N W , Hokkanen, H M T , and Deacon, J , eds. (1994) Proceedings of an OECD workshop on ecologlcal lmplicatlon of transgemc crops contammg Bt toxin genes, Jan. (1994) New Zealand Biocontrol Scl Technol 4,549-553 Davis, M K , Layton, M B., Vamer, J D., and Little, G (1995) Field evaluation of Bt transgemc cotton in the Mississippi Delta, in Proceedmgs of Beltwlde Cotton Conferences (Herber, D. J and Richter, D. A , eds.), National Cotton Council of America, Memphis, TN, pp 77 l-775
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44. DuRant, J A. (1995) Efficacy of selected seed mtxes of transgenic Bt and nontransgenic cotton against bollworms and tobacco budworms m South Carolina, in Proceedings of Beltwtde Cotton Conferences (Herber, D. J. and Richter, D A., eds.), Nattonal Cotton Council of America, Memphis, TN, ppq 769-77 1 45. Rummel, D R , Arnold, M. D., Gannaway, J. R., Owen, D F., Carroll, S C., and Deaton, W. R (1994) Evaluatton of Bt cottons resistant to mJury from bollworm* imphcations for pest management m the Texas southern htgh plams Southwest Entomol 19, 199-207. 46. Luttrell, R G. and Herzog, G A. (1994) Potential effects of transgemc cotton expressing BT on cotton IMP programs, m Proceedings of Beltwtde Cotton Conferences (Herber, D I. and Richter, D. A., eds.), Nattonal Cotton Councti of Amertca, Memphts, TN, pp. 806-809. 47. Fttt, G P , Mares, C. L , and Llewellyn, D. J (1994) Fteld evaluation and potential ecologtcal impact of transgemc cotton (Gossypzum hrrsutum) in Australia, m Proceedings of an OECD Workshop on Ecologtcal Impltcattons of Transgenic Crops Contatntng Bt Toxtn Genes. New Zealand. 48. Fttt, G. P. and Jones, D. D. (1994) Field evaluation of transgenic cotton in Australia environmental constderations and consequences of expanding trial size. The biosafety results of field tests of genetically modified plants and microorgamsms Proceedtngs of the 3rd lnternattonal Symposium, Monterey, CA. 49 Pannetier, C., Guiderdom, E., and Hau, B. (1995) Genetic engmeermg and improvement of rice and cotton Agrtcultural Dev. 6, 16-27. 50 Gould, F., Anderson, A., Reynolds, A., Bumgarner, L., and Moar, W. (1995) Selectton and genettc analysis of a Heliothis vu-escens (Lepidoptera: Noctmdae) stram with high levels of resistance to Bacillus thurmgzenszs toxins. J Econ. Entomol 88, 1545-1559. 5 1 Heckel, D. G , Gahan, L C , Gould, F., and Anderson, A (1997) Identtfication of a linkage group with a major effect on resistance to Bacillus thurtngtensts Cry 1A(c) endotoxin in the tobacco budworm. J Econ Entomol 90,76-86. 52. Hill, M., Launis, K., Bowman, C., McPherson, K , Dawson, J., Watkms, J , et al. (1995) Btohstic mtroduction of a synthetic Bt gene mto ehte maize. Eucarpia Genetic Manipulation in Plant Breeding section meeting, Cork, Irish Republic, Euphytica 85, 119-l 23, 53 Wang, G Y , Du, T B., Zhang, H., Xie, Y. J., Dal, J. R , Mi, J. J., et al. (1995) Transfer of BT toxin protem gene mto maize by htgh velocity microproJectile bombardments and regeneration of transgenic plants. Sczence zn China Series B. Chemt., Lfi Set Earth Set. 38(7), 8 17-824. 54 Dmg, Q. X , Xie, Y. J., Dai, J. R., Mi, J. J , Li,T. Y , Tian, Y. C., et al. (1994) Introducmg Bt gene into maize with ovary InJection. Sczence tn Chrna Series B Chemt , Life Set. Earth Sci, 37(5), 563-572 55 Sims, S. R , Pershing, J C , and Reich, B J. (1996) Field evaluatton of transgemc corn contammg a Baczllus thurzngzensts Berliner msectictdal protein gene agamst Heltcoverpa zea (Leptdoptera Nocturdae). J Econ. Entomol. 31,340-346. 56. Willhams, W. P., Sagers, J B., Hanten, J. A., Davis, F. M , and Buckley, P M. (1997) Evaluation of transgenic corn for resistance to fall armyworm and southwestern corn borer. Crop Scr 37,957-962
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57 Kozlel, M. G , Beland, G. L , Bowman, C , Carozzl, N B , Crenshaw, R , Crossland, L , et al (1993) Field performance and elite transgemc maize plants expressing an msectlcldal protem derived from Baczllus thurzngzenszs Blo/Technology 11, 19&200 58 Armstrong, C L , Parker, G B , Pershmg, J C , Brown, S M , Sanders, P R , Duncan, D R , et al (1995) Field evaluation of European corn borer control m progeny of 173 transgemc corn events expressing an insecticidal protein from Bacillus thurlnglensls Crop SCI 35, 550-557 59 Perlak, F J , Stone, T. B , Muskopf, Y M , Peterson, L J , Parker, G B , McPherson, S A , et al. (1993) Genetically improved potatoes. protection from damage by Colorado potato beetles Plant Mol Blol 22, 3 13-32 1 60 Adang, M J , Brody, M S , Cardmeau, G., Egan, N., Rousch, R T , Shewmaker, C K , et al (1993) The reconstructlon and expression of a Baczllus thuruzg~ensrs cry3 A gene m protoplasts and potato plants Plant Mol Biol 21, 1 13 l-l 145 6 1 Cheng, J , Bolyard, M G , Saxena, R. C , and Stncklen, M. B (1992) ProductIon of insect resistant potato by genetic transformation with a delta endotoxm gene from Bacillus thurwgzensu var kustakz Plant Scz Llmerlck 81, 83-91 62 Douches, D S , Llswldowatl, A., Hadl-Permadl, W P , Hudy, P , Westedt, A , and Grafus, E (1996) Progress m development and evaluation of BT transgemc potatoes with resistance to potato tuber moth (Phthormlnaea operculella Abstracts of The 80th Annual Meeting of the Potato Association of America, Annual Meetmg, Idaho Falls, ID, August 1 l-l 5, 1996 Am Potato J 73,8 63 Jelenkovq G , Bllhngs, S , Chen, Q , Lashomb, J , and Ghldu, G (1996) Englneermg transgemc eggplant (So/unum melogena L ) resistant to Colorado potato beetle (Leptuzotarsa decemllneta Say) HortSczence 31, 572. 64 Fujlmoto, H , Itoh, K , Yamamoto, M., Kyozuka, J , and Shlmamoto, K (1996) Insect resistant rice generated by mtroductton of a modified delta endotoxm gene of Bacrllus thunngzensu Blo/Technology 11, 115 1-l 155. 65 Flschoff, D A , Bowdish, K. S , Perlak, F. J , Marrone, P. G , McCormick, S M , Nledermeyer, J G , et al (1987) Insect tolerant transgemc tomato plants Bzo/Technology 5,808-8 13 66 Muench, S R (1990) Field release of genetically engineered plants m 1987 and 1988 Risk assessment in agricultural biology Proceedings of the International Conference, pp 97-10 1 67 Rhlm, S L , Cho, H J , Kim, B D., Schnetter, W , and Gelder, K (1995) Development of insect resistance m tomato plant expressing the delta endotoxm gene of Bacillus thurlngzenszs subsp tenebrlonls Mol Breeding 1, 229-236 68 Llang, X.-Y , JIU, M J , Zhu, Y. X , and Chen, X L (1994) Construction of plant expression vector with double resistance to vnus and insect and ldentlficatlon of transformation m tomato Acta Botanzcu Sinzca 36, 849-854 69 Hmchee, M. A. W., Conner-Ward, V. D., Newll, C. A , McDonnell, R. E , Sato, S J , Gasser, C S , et al (1988) Productlon of transgemc soybean plants using agrobacterlum mediated DNA transfer Blo/Technology 6, 9 15-922 70 Stewart, C N , Jr., Adang, M. J., All, J. N., Boerma, H. R , Cardmeau, G., Tucker, D., and Parrott, W A (1996) Genetic transformation, recovery, and charactenza-
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non of fertile soybean transgemc for a synthettc Baczllus thurzngrenszs cry1 Ac gene Plant Physzol 112, 12 l-l 29. Strauss, S H , Howe, G T , Goldfarb, B., Neale, D. B , and Kmlaw, C S (1991) Prospects for genetic engineermg of msect resistance in forest trees Forest btotechnology Forest Ecol Manage 43, 18 l-209. McCown, B. H., McCabe, D. E., Russell, D. R., Robmson, D J , Barton, K A, and Raffa, K F (199 1) Stable transformatton of Populus and mcorporatton of pest resistance by electrtcal discharge particle acceleratton. Plant Cell Rep 9, 590-594. Klemer, K W., Elhs, D. D., McCown, B H , and Raffa, K. F (1995) Field evaluatton of transgemc poplar expressmg a Baczllus thurzngzensls crylA(a) d-endotoxin gene against forest tent caterpillar (Leptdoptera, Lastocamptdae) and gypsy moth (Leptdoptera, Lymantrudae) followmg winter dormancy Environ Entomol 24, 1358-1364 Wang, G., Casttghone, S , Chen, Y., Lt, L., Han, Y , Ttan, Y , et al (1996) Poplar (Populus nzgra L ) plants transformed wtth a Baczllus thurmgzensls toxin gene msectictdal acttvtty and genomtc analysts Transgenic Res 5,289-301. Howe, Cl T , Goldfarb, B , and Strauss, S. H (1994) Agrobactertum mediated transformation of hybrrd poplar suspension cultures and regeneration of transformed plants Plant Cell Tzssue Organ Culture 36, 59-7 1 Zheng, J B., Zhang, Y M , Yang, W. Z., Pet, D T., Tran, Y C., and Mang, K Q. (1995) Plant regeneration from excrsed leaves of poplar hybrtd 74 1, and transformatton wtth Insect reststant B t. toxm gene J Hebez Agrzcultural Unw. l&20-25 Chen-Ymg, Han-YtFan, Ttan, Y.-C., Li, L , and Nte, S J (1995) Study on plant regeneration from Populus deltotdes explants transformed with Bt toxm gene Sclentla-Szlvae-Smxae 31,2,97-103 Karnosky, D. F., Shin, D I , Huang, Y H., Podtla, G K , Huang, Y H , Schmidt, W. C., and McDonald, K. J (eds ) 1995 Transfer and expresston of forergn genes m Lartx Opportumtres for genetic Improvement Ecology and management of Larix forests, a look ahead Proceedmgs of an Internattonal sympostum, Whttefish, Montana, USA. October 5-9, No INT-GRT-3 19, pp. 405-407. Shin, D I., Podtla, G K., Huang, Y., Karnosky, D F., and Huang, Y H (1994) Transgetuc larch expressing genes for herbrcide and insect resistance. Can J Forest Res 24,2059-2067
80 Tabashmk, B E., Cushmg, N L , Fmson, N , and Johnson, M. W. (1990) Fteld development of reststance to Bacillus thurzngzenszs m Dtamondback moth (Leptdoptera Plutelhdae) J Econ Entomol 83, 1671-1676. 8 1 McGaughey, W. H and Beeman, R. W (1988) Resistance to BaczZlus thurmgzenszs m colonies of Indtanmeal moth and almond moth (Leptdoptera Pyrahdae). J Econ Entomol 81,28-33 82 US Environmental Protectton Agency (1994) Plant-Pesticides SubJect to the Federal Insecttctde, Fungicide, and Rodenttctde Act and the Federal Food, Drug, and Cosmetic Act Federal Regzster 59,60,496-60,5 18 83 Cook, R. J and Qualset, C. 0 (eds ) (1996) Appropriate overstght for plants with mhertted traus for reststance to pests A report from 11 professtonal sctentific
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societies. Coordmatmg society. Institute of Food Technologists, 22 1 North LaSalle St , Suite 300, Chicago, IL 60601-1291 84. Estruch, J. J., Carozzi, N B., Desai, N , Duck, N B., Warren, G. W., and Koziel, M G (1997) Transgemc plants, an emerging approach to pest control Nature Blotechnol 15, 137-141. 85. Estruch, J J , Warren, G W., Mullms, M A., Nye, G. J , Craig, J A , and Koziel, M G. (1996) V1p3A a novel Bacdlus thurznglenszs vegetative msecticidal protem with a wide spectrum of activities against lepidopteran insects Proc Nat1 Acad Scl USA 93,5389-5394
86 Warren, G W , Koztel, M. G , Mullms, M A , Nye, G J , Carr, B., Desai, N , et al. (1996) Novel pesticidial proteins and strains. World Intellectual Property Organization 96, 10,083.
14 Production, Delivery, and Use of Mycoinsecticides for Control of Insect Pests on Field Crops Stephen P. Wraight and Raymond I. Carruthers 1. Introduction In 1985, Pierre Ferron reviewed the status of a “hundred-year-old hypothesis” that the entomopathogemc fungi would one day become integral components of many insect-pest management systems. He concluded his review by stating the need to “define precisely the ecosystems in which these natural enemies effectively play a positive role, and to determine the treatment strategies necessary to the expression of their potentialities, m order to have available reliable methods suitable with other phytosamtary techmques, accordmg to the integrated protection concept” (I), The hundred-year-old hypothesis IS now more than a decade older. Our understanding of the modes of action and environmental requirements of these agents has increased, and many new strategies have been developed, and old ones elaborated, to better exploit the potential of fungal pathogens. Effective use of fungi for control of a variety of pests has been implemented on many local and regional scales. Commercial use of A4etarhizzum anisopliae in Brazil and Beauveria bassiana in China and Eastern Europe has been well documented (2-Q. Nevertheless, the widespread integration of these agents mto commercial pest control systems has remained, it would seem, ever on the horizon. Reliable mycoinsecticide products remain largely unavailable to private growers, especially in high-technology field-crop production systems. Recent years, however, have seen a dramatic increase in commercialization efforts worldwide. This increase has been stimulated not only by the persistent problem of pesticide resistance and the growing economic and environmental costs of synthetic chemical insecticide use, but by a number of specific technological advances that have the potential to greatly expand the commercial From Methods /n &otechno/ogy, vol 5 Bropestrodes Use and De//very Echted by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
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feastbthty of mycomsecttctde use. This chapter ~111discuss a number of these advances in the areas of fungus productton, formulatton, and application. Wrthm the scheme of btologtcal control, use of fungal pathogens falls under all three of the broad strategies defined m DeBach (7): rmportatton, augmentation, and conservatron. Use of fungal pathogens m each of these strategies has been the subject of many recent reviews (2,4-6,8-12). This paper will focus on the mundatrve augmentation strategy and development of mycomsecttcrde products for mtcrobtal control applications against insect pests of field crops 2. Recent Advances in Development of Entomopathogenic Fungi 2.1. Development of Mass-Production Technologies This topic, though seemingly out of place in a volume on delivery and use of brorattonal control agents, IS a crmcal one m the dtscusston of the current state of the art of mtcrobtal control with fungal pathogens. The long life of the hundred-year hypothesis 1s ulttmately attrtbutable to dtfficulttes wtth field efficacy, which IS highly dependent on an affordable applrcatton rate Many years of field studies of hyphomycete fungi indicate that high rates (on the order of 1Ot3-1Ot4 spores/ha) are often required to provide acceptable levels of control (5,12). This requirement derives from a complex of factors, but one of the most Important relates to the low regression coefficients (slopes) inherently assoctated with fungal dose-host mortahty responses (13) These coeffictents typrtally vary between 0.5 and 1S. An LCSOof approx 100 spores/mm* has been reported for B bassiana against at least two key agrtcultural pests (14,15). Given a typical regression coefficrent of 1.0, the associated LC& IS nearly 4400 spores/mm*. In terms of a umform dtstrtbutton of spores applied to a planar surface, this represents a dose of 4.4 x lOI3 spores/ha. From this perspective (even without factormg m application inefficiencies or three-drmenstonal crop canopy surface areas), It is obvious that many problems of efficacy are crttrcally and inextricably linked to productron economtcs. Thts sttuatton will remam without remedy for at least some time mto the future, when tt will become possible to genetically engineer strains with greatly enhanced infecttvrty and vtrulence (16) Regarding spore-based mycoinsecticide products, efficient productton technologies exist only for select strains of a few pathogen species. Greatest production efficiencies have been achieved wtth B ~~SSZQY~U, at least m part because of the small size of the conidia relative to those of other entomopathogenic fungi. Even with this species, however, the commercial-scale production capacity necessary to support multtple applications to field crops at the high rate of 1Or3spores/ha, at costscompetrtive with synthetic chemical msecticrdes, has long represented a major production barrter. For many years, the standard technology for mass productton of M amsopliae and B bassiana
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throughout South and Central Amertca, Europe, and Asta has employed a substrate of cooked race or other grams on trays or in autoclavable plastic bags or glass Jars. Average yields of approx l-5 x IO9 spores/g (dry wt) of substrate are achrevable with selected fungal strains (3,17-20), but may be substanttally less (21). This technology IS generally adequate to support application rates of l-5 x lOI* spores/ha (22,22). Labor costs and decreasing efficiency wtth increases in scale are srgmficant constramts to continued use of these low-technology production systems.Seekmg an alternative, researchers in the Soviet Union pioneered mass production m submerged culture, using conventional fermentation equipment. Operatronal scale productton systems were developed for B basszana (23), however, no significant gains m efficiency were realized. Ltqurd fermentation supported applicattons of 4 x lOI* spores/ha. Use of the fungus at higher rates was not economtcally feasible, according to Lipa (24). Many spectes of entomopathogenic fungi can be produced m submerged culture. Under these condtttons, as in the host hemolymph, thin-walled hyphae or hyphal bodies are normally produced; hyphomycetes typically produce ovalshaped, single-celled hyphal bodies termed “blastospores.” Development of liquid fermentatton technologies for entomopathogenic fungi remams one of the most active areas of mycoinsectictde research, especially because comdra of many pathogens cannot be eftictently produced on solid substrates Much progress has been made m recent years on the productron and stabthzatton of hyphal body and mycelmm formulattons of various entomophthoralean and hyphomycete pathogens (25-30) However, the commerctal-scale productton/stabrhzation systemsdeveloped thus far are not compettttve with extstmg technologres for comdia (see followmg discussions) Durrng the past decade, major advances have been made in the solid substrate culture of hyphomycete species.Ptoneenng technologies developed tn China and Eastern Europe for mechanized production of conrdia of B. bassiana were extensively reviewed and descrtbedby Feng et al. (6). In Chma, diphastc surface-culture systemsare clanned to produce nearly pure conidial powders of B. basszana suffictent to treatmany hundredsof thousandsof hectaresannually. Cost of an application of 1.53 x 1Ot3conidta to 1ha of forest for control of pine caterprllars is reported to be only approx $2-3, depending on the formulation (32). This suggestsa remarkable level ofefficiency, but the extentof the economicanalystsanddependenceon unique Chinese labor and market condttrons ISunclear. Researchersrn Czechoslovaktaand Canadahave alsodeveloped massculture systemstn whtch conrdra areproduced at a liquid-an or solid-air interface (32,33) Thesesystemsarehighly efficient in productrig spores/kgdry wt of nutrients (32) however, surface culture 1stneffictent tn producing spores/Uof fermenter volume. Free-marketeconomtcanalysesof the Chinese and Czechoslovaktanproductton systemsare needed
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Fully automated, commerctal-scale productton of aerral comdia of entomopathogenic fungi in the West has been most aggressively pursued by prtvate mdustry. Mycotech Corporation of Butte, MT, developed a diphastc system, initially for culture of white-rot fungi for soil remediation, which IS now opttmtzed for B basszana production (34). Blastospores, produced m a liquid medium in conventional fermenters, are mcorporated mto a proprietary sohd medmm that 1sloaded mto trays m large chambers wtth forced aeration and computer-controlled envrronment. Profuse sporulatlon IS mlttated throughout the substrate wtthm a few days. After the culture matures, the spores are drted within the chamber at a controlled rate to approx 5% moisture content, and then harvested directly from the chamber, all wtth a mmrmum of labor. The extracted product IS a nearly pure comdlal powder contammg 1.2-l .8 x 10” comdia/g. According to C Bradley (personal commumcation), yields from more than 20 consecutive production runs m a large pilot faclhty during 1996 averaged 1.1 x IO’Ospores/g of substrate (dry wt). Thts translates to a yield of more than 1Or3conidta/kg of substrate occupymg less than 1 L of chamber (fermenter) space (34). Average yields of 2.6 x 1Or3were achieved m a small pilot system (341, suggestmg that the full potential of the large system has not yet been reached. The Mycotech productton technology IS certainly adaptable to other fungal pathogens that can be mass-produced on solid substrates,especially Metarhzzium and Paecilomyces spp, but tt has thus far been optimized only for B. bassiana. The level of B. basszana comdra productton by the Mycotech systemIS approx fivefold higher than the maxtmum commercial-scale production of blastospores generally achtevable m a comparable ltquid fermentation volume, VIZ., approx 2 x 1012/L (6,3.5,36). This does not mean, however, that effictency ofblastospore production m submerged culture could not one day equal that of comdra production on sohd substrates, because blastospores are produced more rapidly than aerial conidla. The productton of 2 x 1012blastospores/Lreported by Fargues et al. (35) occurred within 48 h after moculatton of the hqutd medium. A number of hyphomycete species can be induced to produce true comdra m submerged culture (23,37-39). The submerged comdta of B. bassiana are produced nearly as rapidly as blastospores, and are considerably more stable (40). Studies also indicate that efficiency of submerged comdta production has the potential to equal that of blastospores. Following an extensive screening of B basszana isolates during development of the Boverm@ product (Ukranian Sctentific Research Institute of Plant Protectton, Ktev, Ukraine), Soviet researchers rdenttfied a strain that produced exceptional yields of submerged conidia In a highly enriched medmm, 3-4 x lOI comdta/L were produced wtthm 3-5 d. However, in an economically acceptable medium, ytelds averaged only 5 x 10’ l/L (23). Maximum yields of B. basszana submerged comdta
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reported recently also have not exceeded this level (41,42). However, rates of submerged comdiation are clearly fungal species- and strain-dependent. Jenkins and Prior (38) reported substantially higher yields of Metarhzzzum Jlavoviride-submerged comdia (1.5 x 10r2/L withm 7 d) m an mexpensrve medium, and Lisansky and Hall (43) claimed that concentrattons of Vevtdlzum lecaniz comdia could reach 1013/L. Research and development of submerged spore production 1scurrently focused on improvmg spore yields and stability.
2.2. Product Stabilization The comdia of the Hyphomycetes are thick walled cells with the capacrty to persist in the envnonment under a broad range of condittons. Nevertheless, throughout the history of their development for mrcrobial control, unformulated preparations of these spores exhibited poor stability at moderate temperatures (44-46). This problem was encountered with spore preparations of nearly all entomopathogenic fungal specres, an important exception being comdia of A4 anisoplzae, which are known to survive as long as 24 mo at 26OC. However, this level of stability apparently exists only under condrtions of high humidity (46), and, according to Miller (47), normal 02/C02 concentratrons. Storage of large amounts of product under these condmons would be difficult, requiring special packaging (47) and methods to mhibit growth of microbial contaminants. These storage difficulties constantly interfered wrth field evaluations, and were a major constramt to commercialization. Coincident with the recent advances in fungus mass-productron technologies, however, have come discoveries that make possible the long-term storage of dry B bassiana and A4. anisopliae conidia under moderate temperature condittons (25°C). These discoverres represent a very significant breakthrough, considermg the many difficulties and high costs associated with cold storage. It 1sgenerally accepted that stability for 12-l 8 mo without refrigeration would be required to servtce general agricultural markets, although stability for 3-6 mo would probably suffice for products produced on contract for applications at a specific time (48,49). An important dtscovery came in the 197Os,when researchers reported that Inexpensive clay carriers, commonly used as msectrctde formulants, enhanced stability of B. basszana blastospores stored m so11over a broad range of temperatures (50). At the same time, Sovret scientists were mvestigatmg use of clays to dry B. bassiana spores produced in liquid culture systems (23), and to produce wettable-powder formulations (51). The benefits of usmg clays for formulation of fungal comdra were reviewed by Soper and Ward (52), and, m a notable unpublished report, Ward and Roberts (53) claimed that B. bassiana comdra formulated m attapulgite and kaolinite clays remamed stable for 12 mo at 26°C.
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Despite these dlscovenes, progress in the long-term, moderate-temperature stab&y of dry formulattons was slow and inconsistent over the next 10 yr. Daoust et al. (54) were unable to improve the 20°C stability of M anuopllae comdla by formulating with various clays and other materials. However, Alves et al. (55) substantially increased the room-temperature stability of comdla of A4 anisopliae to 9 mo by formulatmg with rice or corn flour, or with phylhte. An industry-developed formulation of B. basszana conidia produced m 1984 for Umted States pilot trials against Colorado potato beetle was extremely unstable (56). Zhang et al. (57) produced two wettable-powder formulations of B basszana with shelf hves of 8 mo, but this was at cool storage temperatures (lo-20°C). Imttal attempts to exploit the many advantages of anhydrous 011sas conidla formulants (see below) were also frustrated by stability problems (54,58,59) A major breakthrough came during the 1980s For many years, basic researchers, investigating stability of small samples of comdla, studied the effects of moisture expressed as relative humidity m the storage container, controlled through use of saturated salt solutions or desiccants (44-46,60). However, m most of these studies, the drying processes used to prepare the experimental spore preparations and the degree of desiccation achieved were not indicated. A few researchers dtd report that reduction of moisture content to 10% during harvest improved desiccation survival (23,481, and, m a United States patent application submitted m 1983, Jung and Mugmer (28) claimed that polymer-encapsulated B. basszana blastospores could be stabilized by a two-stage process of controlled drying to a water activity (a,) of CO.1. However, unttl recently, the effects of formulation free-moisture on long-term stability of conidial preparations of entomopathogenic fungi remamed little studied and poorly understood. China has perhaps the greatest experience with practical use of B basslana (6), and work with operational-scale quantities of comdial powders led its researchers to investigate moisture content as a more practically measurable and controllable variable. This ultimately resulted m the quantlficatlon of the substantial negative impacts of excess free water on stability of B basszana comdlal powders and formulations stored over a broad range of temperatures (61,62) According to Chen et al. (36), cited by Feng et al. (6), contdla of B bassiana, formulated in attapulglte clay with water content below lo%, showed no significant loss of virulence after storage for 12 mo at 26”C, which replicated the findings of Ward and Roberts (53). Drying of B bassiana to 80% with oatmeal and soyflour-amended granules at 220 kg/ha; nonamended granules gave only 3% control. The survival of bacteria, fungi, and nematodes m alginate formulations has been improved by coating granules with an inverting oil, followed by an oil adsorbent (22). The enhanced survival is putatively a result of a retardation of evaporation of water from the granules during the drying process. After 6 h of drying at room temperature, coated granules were at -40 bars; uncoated granules were at-74 bars. In the caseof Colletotrzchum truncatum, coated granules had three times as many colony-forming units/g as uncoated granules after 42 h of drying. The nematode Subanguzna picrzdu, a btocontrol candtdate for Russian knapweed, survived for 9 mo at -20°C with no significant loss of mfectivity when formulated with this method (23) Conmck et al. (24) recently developed granules formed by encapsulation of mycoherbictdes in a wheat-gluten matrix, using a pasta-like process, which they have named Pesta. Pasta-like dough was prepared with semolma flour, kaolm, and fungal biomass grown m shake culture. The dough was then kneaded and passed through a pasta maker repeatedly, producing an homogenous sheet. Sheets were allowed to dry until they could be broken and ground. This process produced stable moculum of Fusarzum oxysporum for sicklepod, coffee senna, and hemp sesbania (25). Through controlled humidity experiments, they have shown that the water activtty of the formulation has a profound effect on the survival of the organism entrapped in the matrix. In Pesta formulations of C truncatum (for control of hemp sesbama), they determmed that, when the water activity reached a level at which free (unbound) water was available to the fungus (a, > 0.35), fungal metaboltsm was possible, and long-
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term survtval of the fungus was adversely affected (26,27). Recently, new technology has been adapted for preparation of Pestagranules, whtch mvolves twm screw extrusion and fluid-bed drying, which can be used for commerctal quantities of mycoherbrctde formulatrons (28). More recently, a granulatton procedure has been developed utrhzmg a waterabsorbent starch, sucrose, unrefined corn oil, and silica (29) The method mvolves suspending fungi or bacteria in a sucrose solution and mtxmg wrth water-absorbent starch (Waterlock @,Muscatme, IA) and unrefined corn 011, which forms a cohesive dough. The dough is then granulated by mixing with hydrated silica (Hr-Sil 233@,Pittsburgh, PA) and air-dried. The granulation process 1svery simple when compared to preparation of alginate granules, and has been used successfully for a variety of fungi, bacteria, and a plant-pathogenic nematode (Qurmby and Zrdack, unpublished results). Thus formulatton can be used either as a granule applied to the soil, or, after sieving, as a wettable powder for spray formulatrons. Preliminary data indicate that the mclusron of sucrose m the formulatton is very important for enhancing survival of the organisms m the formulation. The sucrose putatively stabilizes the membranes during the drying process by replacing water molecules m the lipid btlayer. This has been shown for bacteria that have been freeze-dried (30) 4. Materials and Methods for Foliar Application (Historical) Several adjuvants have been shown to increase both survival of mycoherbrcrdal fungi and broherbicide efficacy. Addmon of sorbitol to moculum of Colletotrzchum coccodes for velvetleaf control increased numbers of viable spores recovered from maculated leaves 20-fold, but dew was still reqmred for infection (32). In contrast, the addition of gelatin, sorbrtol, or Bond@(Loveland Industrres, Loveland, CO), a latex product, did not increase mfectron under subopttmal moisture condmons, when used as spray additives for Phomopsis coy1voIvu1us,a broherbicide candidate for field bindweed (32). Dangle and Cotty (33) showed that a variety of additives influenced germination of Alternarza casszae comdra m vitro, and that this could be correlated with performance of the bioherbicrde in greenhouse bioassays. One percent potato dextrose broth, 0.1-l% Tween-80, and 0.02 M potassium phosphate buffer promoted germrnation m vitro, and 100% of the plants were killed after a 24-h dew period, compared to 25% kill for spores in buffer alone. Boyette and Abbas (34) reported that the addition of fruit pectin and plant filtrates to spray solutrons of Alternarza crassa actually altered the host range of the fungus. The addition of pectin to comdial suspensions resulted in 100% mortality of the weeds hemp sesbama, showy crotalaria, and eastern black nightshade. Apphcatron of the comdta in filtrates of the host plant, jimsonweed, also caused normally resrstant plants to become susceptrble. Some crop plants, including tomato, were
Zidack and Qumby also susceptible when sprayed with the amended comdta. The authors postulate that apphcatron of the spores with the amendments induced enzymes, such as pectin esterase,which may have enhanced pathogenests. They also constder the inhibition of antifungal metabohtes (phytoalexms) to be a possibility. Humectants also have the capacity to increase the infection rate of plant pathogens on the leaf surface. Psyllmm hydrophlhc mucilloid (Metamucrl@) at 0.5%, augmented disease levels when applied with mycelial moculum of Alternarza eichhornza, a pathogen of waterhyacmth (35). Dtsease caused by powdered algmate formulattons of the same pathogen was augmented by use of a hydrophilic polyacrylamide (36). The dew requirement for infection by fungal spores was reduced wtth the development of water-in-o11 invert emulsions. Original experiments showed that a mixture of mineral oil, paraffin, and lecnhm, mixed in a 6 5 ratio with the aqueous phase, drastically reduced evaporatton of water from the preparation When A. cassza spores were sprayed m the Invert emulsion wrthout dew, 88% sicklepod mortahty was achieved, compared to no mortality when spores were sprayed m the aqueous carrrer alone (37). The original, Invert emulsion formulations were extremely viscous and required spectahzed,air-assist atomlzmg spray nozzles (38). Connick et al. (39) reported on an improved invert emulsion with reduced viscosity and high water-retention capabthty. This formulatlon utilized an unsaturated monoglycertde as an emulsifier, instead of lecithin. Application of A. casszaeand A. crassa in an invert emulsion resulted in mfectton, usmg extremely low levels of moculum when compared to a stratght aqueous application. Only one spore m a 2-uL droplet was required to infect plants of Casszaobtusifolia and Datura stramonium (40). Similar results were realized when Ascochyta pteridzs was applied in an invert emulsion for control of bracken (Pterzdzumaquzlznum)(41). Amsellem et al. (42) went on to show that application of A cassiae and A crassa in invert emulsion abolished their selectivity and caused them to attack eight other plant species tested. Nonpathogenic fungi were also able to colonize plants, when they were applied m the invert emulsron The authors hypothesized that the invert emulsion may have caused cutrcular damage that allowed penetration by the fungi. Schrsler et al. (43) reported enhancement of disease by C truncatum m hemp sesbarna (Sesbania exaltata) by comoculating with eprphyttc bacteria. They identified a number of bacterial isolates that stimulated appressorla formatton and enhanced diseasesymptoms on hemp sesbania.Fernando et al. (44) reported enhanced efficacy of Colletotrlchum coccodes on velvetleaf when the fungus was comoculated wrth phylloplane bacteria. Although the bacteria decreased comdial development, appressorta formatton was stimulated and germ tube length was decreased. Thts suggested that disease may have been enhanced by reducing the saprophyttc, premfectlon mycehal growth.
Plant Pathogens for Weed Control
377
Application of bactertal pathogens to plants requires special formulatron consideratrons. Because bacteria are not able to penetrate plants directly, then entry to the plant must be artrfictally facilitated. This has been done successfully in two ways. The first is through the use of a nonionic organosilicone surfactant, which lowers the surface tension of aqueous soluttons to the point that stomates are penetrated (45). The potential of this method was illustrated m field experiments on kudzu with the bacterial pathogen Pseudomonas syrzngae pv. phaseolzcola. Field applications were made with Log 8 CFU/mL Pseudomonas m 0.2% Stlwet L-77 at 745 L/ha. Control of kudzu was not achieved in these experiments, but excellent mfectron levels were attained (46). A second form of apphcation for plant-pathogemc bacterra IS mechamcal woundmg. The pathogen Xanthomonas campestris pv. poannua was applied to golf course greens for control of annual bluegrass in conjunctron with mowing (47). The mowing wounds the plant, providing a mode of entry for the bacteria. This has proven to be an effective control for annual bluegrass, and IS being developed for commercial use in Japan (48). An example of biological weed control with bacterial plant pathogens that does not require facrhtated mfectton is the use of rhizobacterla to suppress weed growth. Kennedy et al. (49) showed an inhtbttion of downy brome and an increase m winter wheat yield m field solIs where deleterious rhizobacterra had been applied to the sot1surface, either as an aqueous spray or m infested straw. 5. Integration with Chemical Herbicides The efficacy of biological herbicides may be synergtzed by applying them with reduced rates of chemical herbicides. Sharon et al. (50) showed specific suppresston of a phytoalexin derived from the shiktmate pathway in Cassza obtustfolza L. by a sublethal dose of glyphosate. This concurrently increased the susceptibility of the weed to the mycoherbicide A. cassia. The amount of moculum needed to cause dtseasesymptoms was reduced fivefold when apphed wtth glyphosate. Synergy of bacterial plant pathogens with sulfosate and glufosinate was demonstrated by Christy et al. (51) in greenhouse and field trials. Bacterial strains that caused no symptoms when applied alone dramattcally increased the activity of sublethal rates of the herbicides when applied together. They named this approach the “X-tend” bioherbicide system.Although results were encouraging, they did not achieve commerctal levels of control. 6. Research Needs Sigmficant advances have been made m formulation and apphcatron technology, but the technology stall has not been developed that is necessary to propel a number of brological weed control products to the forefront of the marketplace. Therefore, concerted research efforts are required m a number of
378
Zidack and Quimby
areas. First, marketability of btocontrol products would be greatly enhanced by mcreasmg the shelf life of formulattons. A lofty goal would be 2 yr of storage at room temperature. This would greatly stmplify mventory management for retatlers, and increase the likelihood that they would stock btologtcal products Second, technology for pre-emergence treatments of pathogens that attack weed seeds, both dormant and germinating,
must be developed. This will require strat-
egtes that deliver moculum below the so11surface. Third, reducing the amount of moculum required for adequate mfectton would make products easier to use, and more economtcal Thus point is critical for reducing productton, transportatton, and applrcatton costs. Fmally, stgrnticant opportumty resides m the areas of pathogen vuulence enhancement and ameltoratton of plant defense response. A
recent review by Hoagland (52) describes abundant research into both plant and pathogen btochemtstry that could be exploited to enhance the efficacy of btologtcal weed control agents. The mclusron of novel synerglsts m btoherbtctde
formulations could take them past the point of research, and mto the development of efficacious, reliable, and economtcal
products for the marketplace.
References 1 Bowers, R. C (1982) Commerclabzatron of mtcrobtal btological control agents, m Brologlcal Control of Weeds wzth Plant Pathogens (Charudattan, R and Walker, H L., eds.), Wrley, New York, pp 157-I 73 2 Bowers, R. C (1986) Commerclahzatton of CollegoTM an industrralrst’s view Weed Scl 34s, 24,25 3 Boyette, C D , Qurmby, P C , Jr, Connick, W J., Jr , Dangle, D J , and Fulgham, F E (1991) Progress m the productron, formulatron, and apphcatlon of mycoherbrctdes, m Mlcroblal Control of Weeds (TeBeest, D 0 , ed ), Chapman and Hall, New York, pp 209-222 4 Jackson, M A., Shasha, B S., and Schrsler, D A. (1996) Formulation of Colletotrlchum truncatum mlcrosclerotta for improved biocontrol of the weed hemp sesbama (Sesbanla exaltata). BIOI Control 7, 107-l 13 5 Jackson, M A. and Schisler, D A (1992) The composrtion and attributes of Collectotrlchum truncatum spores are altered by the nutritional environment Appl Envzron Mlcrobrol S&226&2265 6 Stlman, R W , Bothast, R. J , and Schrsler, D A (1993) Productron of Collectotrlchum truncatum for use as a mycoherbiclde: Effects of culture, drying and storage on recovery and efficacy Blotech Adv 11,56 l-575 7 Agnes, G N (1988) Plant diseases caused by prokaryotes, m Plant Pathology Academic Press, San Drego, CA, pp 5 1O-586 8 Kenney, D S (1986) DeVme@-The way tt was developed-an mdustrtallst’s view Weed Scl 34(Suppl. l), 15,16 9 Zomer, P. S (1996) Mycogen Corporation, San Dtego, CA. Personal commumcatlon IO. Brosten, B S and Sands, D C (1986) Field trials of Sclerotmza sclerotzortlm to control Canada thistle (Clrszum arvense) Weed Scl 34,377-380
Plant Pathogens for Weed Control
379
11. Jones, R. W and Hancock, J. G (1987) Conversron of vtrtdm to vtrtdtol by vtrtdmproducmg fungi. Can J Mzcrobiol 33, 963-966 12. Jones, R. W , Lanmr, W. T., and Hancock, J. G. (1988) Plant growth response to the phytotoxm viridtol produced by the fungus Glzocladzum virens Weed Scz 36, 683-687. 13 Backman, P. A and Rodrtquez-Kabana, R. (1975) A system for growth and delrvery of biologrcal control agents to the sot1 Phytopathology 65, 8 19-82 1. 14. Jones, R W., Pet& R. E , and Taber, R A. (1984) Lignite and sttllage: carrter and substrate for applicatron of fungal brocontrol agents to so11 Phytopathology 74, 1167-1170 15 Norman, D J. and TruJlilo, E. E. (1995) Development of Colletotrzchum gleosporzozdes f. sp. clzdemzae and Septoriapasszflorae into two mycoherbrctdes with extended vtabtltty Plant DES 79, 1029-1032. 16 Walker, H L , and Conmck, W. J., Jr. (1983) Sodium algmate for productron and formulation of mycoherbtcrdes. Weed Sci 31,333-338 17 Martmsen, A., SkJak-Braek, G., and Smrdsrod, 0 (1989) Algmate as immobrbzatron matenal. I Correlation between chemical and physical properties of algmate gel beads Bzotechnol Bzoeng 33,79-89 18. Marois, J. J , Fravel, D R , Conmck, W J , Jr, Walker, H. L., and Qunnby, P C. (1989) US Patent 48 18530 19 Papavtzas, G. C , Fravel, D. R , and Lewrs, J A (1987) Prohferatron of Talaromycesflavus m sot1 and survival in alginate pellets Phytopathology 77, 131-136. 20. Boyette, C D and Walker, H L (1985) Productton and storage of moculum of Cercospora kikuchzz for field studies. Phytopathology 75, 183-l 85 21. Werdemann, G. J (1988) Effects of nutrmonal amendments on cotndtal production of Fusarzum solanz f. sp. cucurbztae on sodmm alginate granules and on control of Texas gourd Plant Dzsease 72,757-759. 22. Quimby, P C., Jr, Birdsall, J L , Caesar, A. J , Connick, W. J , Jr., Boyette, C D , Caesar, T C., and Sands, D C (1994) US Patent 5358863 23 Caesar-Tonthat, T C., Dyer, W. E., Quimby, P C., Jr, and Rosenthal, S S (1995) Formulatton of an endoparasitrc nematode, Subanguzna pzcrzdis Brzeskt, a btological control agent for Russian knapweed, Acroptzlon repens (L) DC. Bzol Control 5,262-266. 24 Connick, W J , Jr., Boyette, C D , and McAlpine, J R (199 1) Formulation of mycoherbtcrdes using a pasta-like process. Bzol Control 1,281-287. 25. Boyette, C D., Abbas, H. K., and Connrck, W. J , Jr. (1993) Evaluatton of Fusarzum oxysporum as a potential bioherbrcrde for sicklepod (Cassza obtuszfolza), coffee senna (C occrdentalis), and hemp sesbania (Sesbanza exaltata) Weed Scz 41,678-68 1 26. Connick, W J., Jr, Dargle, D. J , Boyette, D D , Wrlliams, K S , Vmyard, B T , and Quimby, P C., Jr. (1996) Water activity and other factors that affect the viability of Colletotrzchum truncatum conidia m wheat flour-kaolin granules (‘Pesta’). Bzocontrol Scz Technol 6,277-284
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27. Connlck, W , Jr., Dangle, D., Williams, K , Vinyard, B., Boyette, D., and Qmmby, P , Jr (1996) Shelf life of a bioherblcide product. Am Bzotechnol Lab 14, 34,35 28. Dangle, D J , Conmck, W J , Jr., Boyette, D D , Lovlsa, M. P., Wllhams, K. S , and Watson, M (1997) Twm-screw extrusion of ‘Pesta’-encapsulated blocontrol agents. World J Microblol Blotechnol., in press. 29 Qulmby, P C., Jr, Caesar, A J , Birdsall, J. L , Conmck, W J , Jr, Boyette, C D., Zldack, N. K., and Grey, W E. (1996) Granulated formulation and method for stablhzing blocontrol agents US Patent Application 08/695249 30 Leslie, S B , Israeli, E , Lighthart, B., Crowe, J H , and Crowe, L M (1995) Trehalose and sucrose protect both membranes and proteins in intact bacteria durmg drying Appl Environ Mcroblol 61,3592-3597 31. Wymore, L. A., and Watson, A. IS (1986) An adJuvant Increases survival and efficacy of Colletotrlchum coccodes, a mycoherblclde for velvetleaf (Abuflon theophrustl) Phytopathology 76, 1115,1116. 32 Morm, L., Watson, A K., and Relleder, R. D (1989) Effect of dew, moculum density, and spray additives on infection of field bmdweed by Phomopsis convolvulus. Can J Plant Path01 12,48-52 33 Dangle, D. J and Cotty, P. J (1991) Factors that influence germination and mycoherblcidal activity of Alternarla cassiae Weed Technol 5, 82-86 34. Boyette, C D and Abbas, H. K. (1994) Host range alteration of the bloherblcldal fungus Alternarla crassa with fruit pectin and plant filtrates Weed Scl 42,487-491 35 Shabana, Y M., Charudattan, R , and Elwakll, M. A (1995) Identification, pathogenicity, and safety of Alternarra erchormae from Egypt as a bloherblclde agent of waterhyacmth. Biol Control 5, 123-l 35 36 Shabana, Y M , Charudattan, R , and Elwakll, M A (1995) Evaluation of Alternarla eichhorniae as a bloherblcide for waterhyacmth (Elchhornia crasszpes) m greenhouse trials. Brol Control 5, 136-144 37. Qulmby, P. C , Jr., Fulgham, F E., Boyette, C D , and Connick, W J., Jr (1988) An invert emulsion replaces dew in biocontrol of sicklepod-a preliminary study, m Pesticide Formulations and Application Systems (Hovde, D A. and Beestman, G B , eds ), American Society for Testing and Materials, Philadelphia, PA, vol. 8, pp 264-270 38 Qulmby, P C., Jr, Fulgham, F E., Boyette, C. D., and Hoagland, R E. (1988) New formulations nozzles boost efficacy of pathogens for weed control Proc Weed Scl Sac 28,52. 39 Conmck, W J., Jr, Dangle, D. J , and Quimby, P. C , Jr (1991) An improved invert emulsion with high water retention for mycoherblcide delivery. Weed Technol 5,442-444 40. Amsellem, Z., Sharon, A , Gressel, J., and Qulmby, P. C., Jr (1990) Complete abohtlon of high moculum threshold of two mycoherblcides (Alternana casslae and A crassa) when applied m invert emulsion. Phytopathology 80,925-929 41 Womack, J G. and Burge, M. N (1993) Mycoherbicide formulation and the potential for bracken control. Pestwde Sci 37,337-34 1.
Plant
Pathogens
for Weed Control
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42. Amsellem, 2 , Sharon, A , and Gressel, J (199 1) Abolition of selectivity of two mycoherbtcidal orgamsms and enhanced vn-ulence of avtrulent fungt by an invert emulsion Phytopathology 81, 985-988. 43 Shisler, D A., Howard, K M., and Bothast, R. 3 (199 1) Enhancement of dtsease caused by Colletotrichum truncatum in Sesbania exaltata by comoculatmg wtth eptphyttc bacterta. Blol Control 1,26 l-268 44. Fernando, W. G. D., Watson, A. K., and Paulttz, T C. (1994) Phylloplane Pseudomonas spp enhance disease caused by Colletotrwhum coccodes tn velvetleaf. Blol Control 4, 125-l 3 1. 45 Ztdack, N K , Backman, P. S , and Shaw, J J (1992) Promotion of bacterial mfectron of leaves by an organosihcone surfactant. tmphcattons for btologtcal weed control. Bzol Control 2, I1 1-l 17 46. Zrdack, N. K. and Backman, P A. (1996) Biological control of kudzu (Puerarza lobata) with the plant pathogen Pseudomonas syrmgae pv, phaseolzcola. Weed Sa 44,645-649 47 Johnson, B. J. (1994) Biological control of annual bluegrass wtth Xanthomonas campestrw pv. poannua m bermudagrass. HortSclence 29, 659-662. 48. Savage, S (1996) Formerly of Mycogen Corporatton, San Diego, CA Personal commumcation. 49 Kennedy, A. C., Elhot, L. F., Young, F L., and Douglas, C L. (199 1) Rhtzobacteria suppresstve to the weed downy brome. Sol1 Scl. Am. J 55,722-727 50. Sharon, A., Amsellem, Z., and Gressel, J (1992) Glyphosate suppresston of an ehctted defense response. Plant Physiol. 98, 654-659 5 1 Christy, A L , Herbs& K A , Kostka, S J., Mullen, J P., and Carlson, P S. (1993) Synergizing weed biocontrol agents with chemrcal herbrcides, in Pest Control wzth Enhanced Envzronmental Safety (Duke, S. O., Menn, J J., and Plmmer, J R , eds.), ACS Symposmm Serves524, American Chemrcal Society, Washmgton, DC, pp 87-100 52. Hoagland, R. E. (1996) Chemrcal mteractrons with bioherbictdes to improve efficacy. Weed Technol 10,651-674.
V OTHER BIORATIONALTECHNOLOGIES
21 Pheromones
for Insect Control
Strategies and Successes D. R. Thomson,
L. J. Gut, and J. W. Jenkins
1. Historical Perspective There IS general agreement among government agencies, research mstttuttons, industry, grower organizations, and the public that there is a need to reduce reliance on broad-spectrum msectrcides by acceleratmg efforts to incorporate ecologically sound technologies mto agrrcultural pest-management programs. The development and implementation of pest control technology based on behavior-controllmg chemicals, or semlochemicals, offers a umque opportunity to move m this direction. Semrochemrcals are chemical messages that organisms use to communicate with each other. Among the semtochemrcals, insect sex pheromones have probably recerved the most attention from the scienttfic, regulatory, and agrtcultural commumties. Sex pheromones are chemical messagesbetween individuals of the same specres,whrch facrhtate mating. By their nature, pheromones are highly specific and then use for insect control would not disrupt other brological mteractrons wrthm a cropping system. The first published rdentrfication of an msect sex pheromone was that of the silkworm moth Bombyx morz L. (I). During the 1960s the pheromones of 11 other insects were rdenttfied (2) Research on sex pheromones increased m subsequent years, as efforts were made to utilize these materials for managmg insects. Currently, the pheromones of more than 1600 species have been rdentified (3,4). The productron of synthetic copies of sex pheromones has led to the development and widespread commercial use of sex-pheromone traps for monitoring and trapping insect pests m many sectors, mcludmg agriculture, forestry, government detection and quarantine programs, and consumer protection, From Methods VI Botechnology, vol 5 B~opeshndes Use and De//very Edited by F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
385
Thomson, Gut, and Jenkins
386 Table 1 Mating-Disruption
Products
Pest Pink bollworm Codlmg moth Tomato pinworm Oriental fruit moth Gypsy moth Peachtwig borer Peachtree borer Tufted apple bud moth Grape berry moth Omnivorous leafroller Leafrollers Other (aphids, mites) aObllquebanded,
Registered
Abbreviatron PBW CM TPW OFM GM PTwB PTB TABM GBM OLR LRa
by USEPA,
1997
Year of first registratron Registrations Companies 1978 1991 1982 1987 1983 1995 1995 1994 1990 1996 1997
9 5 5 3 2 2
1 1
4 4 3 3 2 2 1
1
1
1
1
1 1
1 2
2
blackheaded fireworm, pandemls
The potential of using sex pheromones to control insect pests was first demonstrated 30 yr ago (5). This and other early research (6-9) demonstrated that the release of large amounts of synthetic sex pheromone mto the atmosphere of a crop could interfere with mate locatton, thereby controlling the pest by delaymg or preventing matmg. Despite the successdemonstrated m these studtes, the first commerctal mating-disruption product registered m the Urnted States for the control of an insect pest was not until 1978, when the pheromone of the pmk bollworm (PBW) Pectinophora gossyplella (Saunders), was registered (10). Currently, there are over 30 mating-disruption products registered by the US Environmental Protection Agency (EPA) for control of more than 12 pests (Table 1). Several factors have enhanced the development and commerctal use of mating-disruption technology for the control of insects In the United States and elsewhere, regulations governing the registration and field application of conventional insecticides have become more restrictive. The cost and time to register these materials has increased substantially, and is viewed as a barrier to the development of new products (22). Stmtlar concerns associated with new data requtrements for reregistration have made many products economtcally marginal to their registrants, resulting m then removal from the market. For the manufacturers of mating-dtsruptton products, the registration process was also considered an impediment to the development of technology (12). The time and the costs to register these narrow-spectrum products could not be Justified by small market size.
Pheromones for Insect Control
387
The EPA has implemented many changes in the regulatory process to accelerate the development and registration of pheromone-based control technologies (13,111). The EPA established a toxicology-based, tiered testing requirement for pheromones and other biochemical products. Longer-term toxicology studies are required if adverse results are obtained m the initral acute tests. Further, the EPA exempted from the requirement of tolerance all inert Ingredients of pheromone products formulated m dispensers made of polymeric matrix materials. This exemption applied to dispensers large enough to be retrieved from the field, and enabled companies to contmuously improve their formulations without the need to seek EPA approval (14). In 1994, the EPA issued a general exemption from tolerance requirements for all arthropod-pheromone active ingredients, again in large, polymeric materials, and when applied at ~370 g active mgredient/ha/yr. In addition, the EPA increased the amount of area that could be treated wtth pheromone products without an Experimental Use Permit (EUP) from 4 to 100 ha. In 1995, the EPA expanded regulatory relief to include sprayable pheromone formulations, by issumg tolerance exemptions for all lepidopteran pheromones, and increasing the acreage cutoff to 100 ha for these formulations as well. In order to better manage the registration of pheromones and other biochemical technologies, the EPA established the Biopesticide and Pollution Preventton Division, Together, these changes have provided pheromone products with a distinct advantage in the registration process,and facilitated and accelerated then introduction into the marketplace. In 1993, the EPA published the Worker Protectlon
Standard for Agricultural
Pesticides (40 CFR, Part 170). Mandatory compliance with all the requn-ements became effective April 15, 1994. The new regulations were designed to protect farm workers and pesticide handlers from health hazards associated with pesticide exposure. The new regulations increased the restricted entry mtervals, enhanced training, required greater notification and posting, and provided for the establishment
of decontamination
sites. Compliance
with the new
regulations has made farm worker management more difficult and expensive m agricultural crops m which conventional insecticides are routinely applied. Fortunately, the EPA exempted pheromones from these regulations. As a result, m agricultural crops in which mating-disruption technology is used alone, or in conJunction with the limited use of insecticides, the management of agricultural workers is simphfied and less expensive, giving mating-disruption technology another advantage in the marketplace. It is well over 50 yr since the discovery and commerciallzatlon
of DDT. The
success of DDT and other insecticides in killing insect pests was followed closely by control problems associated with insecticide resistance (15). Currently, there are over 504 insect pests known to be resistant to msecticrdes, and the number continues to increase (16). Mating disruption, with its unique mode
388
Thomson, Gut, and Jenhrns
of action, may be able to slow or prevent the development of resistance by reducing exposure to insecticides. Resistance to pheromones has not been documented in the field, and, at least m some species, is unlikely, given the broad response to blend ratios (17). Therefore, mating-disruption products should have longer life expectancy, and may help preserve the dwmdlmg supply of effecttve conventional insecticides. Mating-disruption technology controls the target pest by manipulating certain aspects of sexual behavior (18). Pheromones are nontoxic to natural enemies. In contrast, conventional insecticides are generally broad-spectrum, killing both pest and nonpest species Greater reliance on pheromone technologies m agricultural crops will increase the potential for the biological control of secondary pests by allowmg for crop environments that can sustain high populations of predators and parasitoids. Enhanced biological control often corresponds to a reduction m the number of insecticide applications for control of secondary insects (I9-21), resulting in savmgs for the grower (22). The above discussion reviewed some of the factors that have favored the successof mating-disruption technology in the marketplace. The focus of the remainder of this chapter is to discuss how specific advances in critical areas have enhanced the development, implementation, and adoption of mating-disruption technologies m agricultural systems. It does not review the principles of mating disruption, nor does it attempt to discuss the many successful usesof this technology. These have been carefully reviewed in other publications (l&23-26). The followmg critical issueswill be discussed regarding the use of mating-disruption technology in two agricultural systems:biology and pest status; identification, formulation, and delivery system; and applied research, extension, and economics. We have selected two pest management systems, PBW m cotton and codlmg moth (CM) Cydiapomonella, m pome fruits, to illustrate how these critical issues have been addressed, and to discuss their overall tmpact on mating disruption product development and commercial adoption. PBW and CM represent two very different challenges for matmg-disruption technologies. Worldwide, mating disruption is used most extensively for the control of PBW, a serious pest of an annual row crop that is grown on large acreages. In 1996, tenders were awarded m Egypt to supply matmgdisruption products for approx 200,000 ha of cotton (24). The CM system provides a model for the successful development and adoption of this technology m horticultural crops, and provides an assessmentof the technology m a much different croppmg situation, with the added challenges of a large crop canopy, larger pest complexes, and lower damage thresholds because of high crop value. Mating-disruption technology is also extensively used to control CM in pome fruit in the United States (20,27), Italy (28), and South Africa (29). Worldwide in 1997, it is estimated that mating-disruption tech-
Pheromones for insect Control
389
nologies were used to control CM on between 24,000 and 28,000 ha of pome fruit (Thomson, personal communication). 2. Case Studies 2.1. Pink Bollworm 2.1 7. Biology and Pest Status The PBW is the most serious pest of cotton, Gossypzum hzrsutum L. and G. barbadense L, worldwide, including North and South America, Spain, Greece, Egypt, Pakistan, India, China, and Australia. In the desert southwestern United States, this pest infests approx 200,000 ha of cotton, mcludmg the highest yielding areas of Arizona and the Imperial Valley of Cahforma (30) In 1997, there were an additional approx 54,000 ha of cotton infested Just south of the United Statesborder m Mexico (R. Staten,personalcommunication) Throughout its range, PBW is usually the primary economic pest of cotton. Cotton bolls are the preferred site for ovtposition. Upon hatching, firstmstar larvae quickly enter squares or bolls. Injury is caused when larvae cut and stain fiber and feed in seeds wtthm the developmg cotton bolls. Larval damage also permits the development of decay from microorganisms. Infestations can lower quality of lint and seed, and yield reductions of 30% or higher are not uncommon (31), Quarantine programs, cultural practices (32), sterile moth releases (33,34), and conventional chemical msecticides have been used to manage PBW populations. Control with conventional msecticrdes 1sdifficult, because larvae are well protected within cotton squares and bolls. Insecticide applications are therefore normally targeted at nocturnally active adults. Insecticide costs for PBW control are high. Gonzales (35) reported that msectlcide costs during the period 1978-l 988 averaged $640/ha/yr. Furthermore the reliance on conventional chemical insecticides has led to outbreaks of secondary pests (36) and development of resistance (37). Because of the problems associated with traditional chemotherapy, PBW has been a prime candidate for development of alternative control methods. Development of mating-disruption technology for this pest began more than 25 yr ago (38). 2.1.2. Critical Issues in Identification, Formulation, and Delivery System PBW sex pheromone, gossyplure, was first identrfied by Hummel et al. (39) and Bier et al. (40). Compared to many insect pheromones, gossyplure (Z:Z and Z:E 7,11 hexadecadienyl acetate 5050) is relatively simple to synthesize, and is stable in the environment (41). Soon after its tdentification, work began on formulations and delivery systems (7,10,42). In 1978, the first matmg-disruption product was registered by EPA for PBW control (10).
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The earliestresearchon PBW mating disruption was conductedwtth hand-applied devices (7,38). Commercial successcomcided with development of mechanically applied formulations. These mvolved mixture of slow-release dispensers,such as plastic microtube fibers and lammated flakes, with stickers. The mixtures were applied by specializedequipment attachedto aircraft or tractors (20,43,44). These formulattons had greater commercial acceptancecompared to hand-applied dispensers,especially among cotton growers in the southwesternUnited States. A series of studies led to the development of an attracticide formulation. Nocturnal observations of PBW moth mating behavior, m fields treated with mechanically applied formulations, demonstrated that males approach and contact the pheromone-laden dispensers. Furthermore, moth scalescould be found m the stickers surrounding the dispensers (45). These observations led to mcorporation of small amounts of insecticide m the stickers used to adhere the pheromone dispensers to crop foliage. Control was an outcome of males contacting the sticker and absorbing a lethal dose of msecticide (46,47). Butler and Las (48) demonstrated that apphcations of attracticide for PBW control did not adversely impact beneficial insects m the field. This attracticide approach is thought to be more robust than mating disruption alone, resulting m greater efficacy under higher population pressure (49). Even though some researchers have not seen significant advantage of this approach over classical mating dtsruption (50) use of attracticide has been adopted by growers, because it allows reduced rates of synthetic pheromone, as low as 100mg active ingredient (at)/ha/d, and lower costs. Presently, most commercial applications of PBW mating disruption m the Umted States use the attracttctde approach. In certain markets, hand-applied dispensersare acceptable or even preferable These include areas where labor is readily abundant and inexpenstve, where mechanical application equipment is not available, and in crops where proper dtspenser placement is difficult to achieve with broadcast application equipment. For PBW and other pests,long-lived pheromone dispensershave been developed that protect labile pheromone-active ingredients, and provide effective release for extended periods of field exposure (51-53). These formulations can be easily applied to plant foliage, and may provide season-longpopulation suppressionfrom a single apphcatton. Furthermore, they eliminate possible gaps in coverage durmg which mating may occur. This is a frequently observed problem with shorter-lived formulations. Season-long dispensersare loaded with higher rates of pheromone, typically 147-165 mg, and are applied at 250-500 dispensers/ha.Recent measurements, using field-portable electroantennograms of pheromone movement from high-load dispensers, indicate concentrations sufficient to affect PBW mating behavior may be transported by wind up to 100 m from the emitting source (54). These observations suggestpheromone dispenserscould provide effective mating disruption when placed at much more widely spacedintervals.
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The major disadvantage of all types of mechanically or hand-apphed formulations IS the dlffculty of apphcation or the need for specialized mechanical equipment. The equipment required for mechanical applications 1snot avallable in most foreign markets, and hand-apphcation, although possible, is often not preferred. Hand labor may be scarceor expensive, and apphcation of sticky formulations can be undesirable, especially If insecticides are added. These drawbacks helped encourage the development of sprayable, mlcroencapsulated formulations for PBW mating disruption (55,.56). Commercial microencapsulated formulations are now avallable for several important insect pests m the United States. For PBW, microencapsulated formulations are applied at 5.0-12.5 g/ai/ha, and may last up to 14 d per appllcatlon, depending on temperature. They are most often used during periods of little rainfall. At lower rates, mlcroencapsulated formulations are often applied concurrently with standard rates of conventional msectlcides, as a biom-ltant strategy designed to increase pest exposure to the msectlclde (57). 2.1.3. Critical ksues in Implementation: Appljed Research, Extension, and Economics The many contributions to pheromone identification and formulation development discussed in the previous section have resulted in the establishment of mating-disruption technology as an effective and economical method for PBW management (18,31,33,58,59). One of the most successful demonstrations of the use of mating disruption for PBW control has been conducted by the Anzona Cotton Research and Protection Council (ACRPC). During 1990-l 996, ACRPC conducted a pheromone-based control program rn cotton planted m the Parker Valley along the Colorado River (60). Acreage ranged between 9575 ha and 11,430 ha. PBW control consisted of mating disruption or attracticide, and the judicious application of conventional insecticides. Control measures were applied based on intensive momtormg using pheromone-baited traps (1 trap/4 ha) and plant inspection. In 1989, m the year prior to the program, average boll infestation m the valley was more than 23% (Table 2). After the first year of the program, PBW-infested bolls were reduced by more than 50%. By the fourth year, 1993, no larvae were detected m more than 25,000 bolls inspected, at a cost to the grower of only $55.60/ha. PBW infestation increased slightly m 1994 and 1995, then m 1996, boll infestation increased substantially, to 2.63%. This caused concern among growers and program organizers. Success of PBW mating disruption is inversely density-dependent. Many studies illustrate the importance of early application while populations are still low (7,61-64). The decline m efficacy in the Parker Valley Project might be attributed to high population densities during 1996 (L. Antilla, personal com-
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Table 2 Pink Bollworm Infestation and Control Cost in Parker Valley Pink Bollworm Pheromone Program Year
1989 1990 1991 1992 1993 1994 1995 1996
Bolls inspected
Larvae found
% Infestation
Cost/ha ($)
26,879 34,726 35,477 30,064 25,200 16,109 16,520 45,597
6282 3442 507 261 0 32 63 1200
23 35 9.91 1 42 0 86 0 00 0 20 0 38 2 63
17 20 1720 22 00 9 00 11 52 13 10 20 36
SourceArizonaCotton Research and Protection Couml munication). Higher-than-normal populations entered diapause at the end of 1995, and mild overwmtermg conditions contributed to larval survival. Furthermore, population pressure was aggravated m early 1996 by uncontrolled PBW infestations coming from volunteer cotton plants which had grown undetected m nearby wheat fields. As a result, population pressure was uncommonly htgh in 1996, and approx 10% of the cotton fields withm the program experienced infestation of at least lo%, despite repeated mating disruption and insecticide applications, at a cost of more than $120/ha. However, 90% of the fields m the program were relatively clean, and the average infestation of 2.63% should not indicate a failure of mating disruption to control the pest. Although the Parker Valley Program may be considered a successful example of mating disruption, it also illustrates the tenuous nature of areawide programs. Although mating disruption has been biologically and economically effective, the organized program did not contmue in 1997. Instead, growers reduced pheromone-protected acres and increased use of transgenic Bt-cotton. This change may be attributed to some of the problems experienced m the pheromone program during 1996, and to the relatively mexpensive and low-maintenance transgenlc cotton technology. Grower cost for Bt-cotton is approx $80/ha, significantly lower than the cost of PBW control to program growers m 1996. The use of transgemc cotton more than doubled m Arizona between 1996 and 1997. It 1sestimated that approx 144,000 ha of cotton were planted m Arizona during 1997, and that nearly 50% of this area was planted to transgenic Bt-cotton varieties. At present, transgenic cotton appears to be very effective in controllmg PBW infestations, and, compared to mating disruption, easier to implement. However, there is serious concern that widespread use of the technology will place extreme pressure on insects to develop resistance to
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Bt toxin (65). Furthermore, research mdicates that the resistance factor 1san
incompletely dominant trait (A. C. Bartlett, personal communicatton). Unfortunately, the greater the degree of dominance, the less likely a high-dose strategy as presently employed is going to succeed (T. J. Dennehy, personal commumcation). Despite these concerns, the planting of trangenic cotton has reduced the use of PBW mating disruption in the desert southwest United States.Mating disruption is now limited to refugia fields, or, m a much smaller amount, to supplemental application on top of Bt-cotton fields. Termination of the Parker Valley Pheromone ProJectIS unfortunate, becausethe area-wide program employed many of the crtteria necessaryfor successful implementatron of mating dtsruptton 1 2 3. 4. 5. 6 7.
Early initiation at pinsquare stage cotton, while populatrons are relatively low Intensive monitoring with pheromone traps and frequent plant mspections, Use of economic thresholds; Careful adherence to effecttve rates and uniform pheromone dtstrrbution, Proper timing to avoid gaps between application; Reduction of immtgratton of mated females; and Judictous use of other control measures, including standard msecttcrdes.
Unfortunately, these criteria are often not used in less organized programs. There are now various methods available for management of PBW m the desert southwest United States. Mating disruption has been an effective and commercially viable method for controlling this pest for nearly 20 yr. Although recent mtroduction of transgenic cotton has decreased the use of mating disruption, in the future this technique could be combined with other methods,
such as sterile-male releases, short-season cotton and transgemc varieties to combat infestations, and manage resistance development to Bt-toxins. PBW mating disruption is likely to increase in other countries, where transgemc cotton is not yet available and PBW remains a serious pest. 2.2. Codling Mofh 2.2.1. Biology and Pest Status CM 1s a key pest of pome fruits in North and South America, South Africa, Australia, and Europe. Eggs are laid on the twigs or leaves adjacent to the fruit, or directly on the fruit. Upon hatching, larvae tunnel into the fruit. Failure to control thus pest can result m very high levels of crop loss, with at least 80% wormy fruit at harvest (66). CM is primarily controlled throughout the world by one or more applications of broad-spectrum, primarily organophosphorous, insecticides. These compounds, if used correctly, generally provide commercially acceptable levels of control, with damage to fruit kept below 1%. Unfortunately, organophosphorous compounds are highly toxic to natural enemies
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of most pests, and are a maJor factor limiting the successof btological control m pome frutt. CM resistance to organophosphate msecticrdes has been detected m parts of the western United States(67,68), and in South Africa (M. Addison, personal communication) Up to 12 sprays per season are common m South Africa, and, despite this intensive program, some orchards suffer at least 30% fruit inJury at harvest (29) Increasmg difficulty m controllmg this pest has certainly provided a sense of urgency in research efforts to develop new CM-control technologies. In North America, considerable research has been directed toward the development of more selective controls for CM, mcludmg the insect-growth regulators (IGRs; 69-72). In Europe, IGRs have been used commercrally for years. They are generally considered to be nontoxic to natural enemies, and have become an important component of apple pest management programs (28). However, Riedl and Zelger (72) have reported high levels of resistance m some regions to one class of growth-regulating compounds: the chmn synthesis inhibitors. In addition to the potential for resistance, field trials conducted m North America and Europe have indicated that IGRs are not as efficacious as organophosphates in controlling CM (J. Brunner, personal commumcatton), Therefore, it is unlikely that IGRs will be an effective and reliable stand-alone replacement for organophosphates. Other tactics tested m North America, including CM granulosis vu-us (73) and mass release of sterile males (74,75), have been demonstrated to be relatively soft on beneficial insects and mites. However, these have either been too expensive, remam unregistered, or have not been effective enough to obtain widespread commercial acceptance m the United States. The use of sex pheromones for mating disruption has long shown promise as a control for CM (7679), but only recently has rt become widely adopted (2 7,28,80,81). The total area of pome fruit production around the world treated with various mating-disruption technologies has grown from an estimated 1500 ha m 1991 to at least 24,000 ha in 1997. The results have generally been good. However, control problems still occur that may be related to issues m pheromone identification, formulation, and delivery system Control problems have also been attributed to environmental conditions, high population densities, immigration, or improper use, and extensive research and education is still required to improve the level of control and enhance use of the technology 2.2.2. Critical Issues in Identification, Formulation, and Delivery System Lab and field research on mating disruption by mdustry and university SCIenttsts m Australia, Canada, Europe, Japan, and the United States over the past 20 yr has provided the foundation for the commercial development of pheromone technology for the control of CM (79). Roelofs et al (82) identified (E,E)-8,1O-
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for lnsect
Control
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dodecadien- l-01 (codlemone) as the major component of CM sex pheromone Evidence for secondary components m the CM pheromone was reported 10 yr later by Bartell and Bellas (83). Subsequent research supported this findmg, with dodecanol-1 and tetradecanol-1 identified as the important secondary components (84-86). Rothchild et al. (87) conducted research on a blend of codlemone, dodecanol, and tetradecanol for mating disruption of CM, and subsequently patented its use. On the basis of this new mformatton, a major manufacturer incorporated the three components, codlemone, dodecanol, and tetradecanol, in their formulation. The identification of secondary compounds, and their subsequent use m a commercial formulation, was important, because many of the early trials employmg dispensers loaded only with codlemone had demonstrated inconsistent and often poor results (79). It was a widely held assumption that mating disruption worked best when the complete blend was used (88). However, many products appeared on the market m both Europe and the United States with only codlemone in the formulation. To clarify the importance of secondary components, McDonough et al. (89) looked at the behavioral responses of CM males m a wind tunnel to sources emitting codlemone, or a mixture of codlemone, dodecanol, and tetradecanol, and were unable to show differences. In small orchard plots, McDonough and colleagues further demonstrated that Inhibition of male attraction to virgmfemale-baited pheromone traps was the same whether traps were m an environment containing elevated levels of codlemone alone, or codlemone plus dodecanol and tetradecanol (90). McDonough et al. (91) concluded that male CMs were sensitive only to the major component, E,ES-lo-dodecadlen-l-01. He suggested that control problems often seen m pheromone-treated orchards were probably related to the photodegradation of the pheromone m the dispenser, and not the result of an mcomplete blend. The weight of the scientific evidence indicates that dodecanol and tetradecanol are not of critical importance to the efficacy of CM mating disruption. However, their exact role remains unclear. There is still an active search for additional components in the CM pheromone (G. Gries, personal commumcanon). If additional components are eventually identified, perhaps their inclusion m commercial formulations will enhance control of CM. McDonough et al. (91) reported that, in small plots, dispensers loaded with an equilibrium blend of codlemone and its geometric isomers resulted m a higher level of disorientation of males to virgm-female traps than dispensers loaded with htghpurity codlemone. These findings have not yet been thoroughly tested m the field to determine their importance to the efficacy of CM mating disruptton. CM pheromone has been formulated and tested for efficacy m both broadcast and retrievable dispensers. Sprayable formulations have mcluded microcapsules (92) and chopped hollow fibers (77). Retrievable formulations have
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included hollow fiber tapes (93), rubber tubing (94) laminate flakes (94), and polyethylene-tube dispensers (95). Smce 1991, the EPA has registered four dtspensing systems for the control of CM, mcluding polyethylene tubes, bagtype membranes, plastic coils, and laminate flakes. No broadcast formulations have been registered. Results from early research trials were often poor, and probably related to formulatton and delivery problems (79). Formulations and dehvery systems have improved, but control problems stall occur wtth currently regtstered commercial formulations. If codlemone is the sole component of CM pheromone, then control problems related to formulation and delivery system are probably caused by photochemical degradation (9697) and/or longevity of release from the dispenser (97). The impact of photochemical degradation on dispenser performance was investigated for the polyethylene tube formulation. McDonough et al. (96) reported that as much as 61% of the pheromone was lost through photochemically induced degradation, and only 39% through evaporation. Codlemone is a conjugated diene alcohol, and, like other similar chemicals, is prone to photochemical degradation via exposure to heat, light, and oxygen (98,99). Degradation occurs via isomerization of the double bond (ZOO),and oxidation to peroxides and furans (97,99) The amount of codlemone degradation in polyethylene-tube dispensers, first used commercially, effectively decreased the longevity and necessitated two applications of dispensers per season (96). Unfortunately, the cost of the dispensers precluded a second apphcation (22), and many attempted to get season-long control with a smgle application of dispensers. This approach often resulted in control problems late in the season. In response, new formulations of the polyethylene-tube dispenser have been developed, with substantially less photodegradation. The effective field life has increased by close to 50%, from 75-90 d to 120-140 d, depending on temperature (D. Thomson, personal communication). A field life of 140 d can provide season-long control m more temperate pome fruit-growing regions. Overall, the improved performance of polyethylene-tube dispensers has improved the efficacy of CM-mating disruption later in the season,resulting m a better rate of success,leading to enhanced adoption by growers. A related problem with current delivery systems has been inadequate field life, because of factors other than chemical degradation. Field life ts a function of the pheromone load and its rate of release from the dispenser. The loading rate is easily controlled m the lab; however, release rate in the field (assummg no photodegradation) is complex, and is affected by the physical and chemical characteristics of the dispenser, and environmental factors, such as temperature and wind. Ideally, dispensers should show a flat release rate at a constant temperature over the expected field life. However, release rates change strongly, relative to temperature, and weakly, relative to wmd velocity (M. Suckling, per-
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sonal communication). Thus, dispensers are likely to have shorter field lives m areas with high temperatures, or when conditions in a cooler region are unusually warm. This variation m release rates caused by temperature difference makes it difficult to determine the effective field life of a dispenser. Many commercial formulations have shown dramatic decreases m release rate following field exposure (101). The result has been inadequate amounts of pheromone released into the orchard later in the season. However, some manufacturers have improved their products, resultmg in substantial improvements in performance (101). Currently available commercial formulations employ either a single- or multiple-application strategy. These strategies are designed to ensure the adequate release of pheromone durmg the mating period of up to three CM generations. Control problems have occurred when dispensers have run out of pheromone earlier than expected, leavmg gaps when there is no pheromone dispensed, Dispenser manufacturers must carefully determine the expected field life of their products, to ensure proper use and performance m the field. 2.2.3. Critical Issues in lmplemen ta tion: Applied Research, Education, and Economics We believe CM matmg disruption has succeeded because the research, extension, and agricultural communitres have tried to mtegrate pheromones into pest management programs, rather than srmply adopt another technology for CM control. By implementmg a pheromone-based pest management strategy, many of the limitations to the efficacy and acceptance of pheromones imposed by the orchard-croppmg system have been mrtigated. These include highly vartable environmental conditions, a low tolerance for fruit damage, a complex CM mating system, and a diverse arthropod commurnty. Early on, it was recognized that the best opportunittes for CM control were m orchards where physical characteristics and environmental conditions, mcluding topography, size and shape, canopy structure, and wmd allowed for uniform distributton of pheromone. Relatively flat and even canopied sites have served as the primary candidates for CM mating disruption, sites with steep slopes or large numbers of missing trees have generally been avoided The borders of disrupted orchards have been especially vulnerable to CM (2478). Two processes have contributed to the development of border mfestattons. Mated females inumgrate from adjacent orchards that are not treated wtth pheromone. In addition, it is suspected that pheromone concentrations are lower on the borders than the interior, thus increasmg the likehhood of males locating females and mating on the borders. Growers have Judiciously protected the orchard perimeter by treating with insecticides, a 2x rate of pheromone, or a combination of the two. Border problems can also be remedted by
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the area-wide application of mating-disruption technology. Recently, an areawide approach to control CM with mating disruption and other suitable technologies was mitiated m western North America. In 1995, the USDA, m associatton with cooperatmg universities m California, Oregon, and Washmgton, initiated the Codling Moth Area-wide Management Program (CAMP). The excellent results achieved at all CAMP sites has increased awareness about the benefits of the area-wide application of mating-dtsruption technology The CM mating system has posed some special challenges to achievmg control with mating-disruption technology. Adults mate shortly after emergence m the spring, and mating activity is concentrated m the upper-third of the canopy (102). Thus, both the timmg of application and the posittonmg of dispensers withm the canopy can dramatically affect the efficacy of mating disruption. For example, Weisslmg and Knight (103) demonstrated that significant levels of mating occurred m the upper-half of the tree, when dispensers were placed at a mid-canopy height of 1.8 m However, little or no mating occurred m the tree when dispensers were placed high m the canopy, at 3 6 m (trees were about 4.2 m tall). The best control of CM with mating disruption has been achieved when dispensers are placed high m the orchard canopy (0.6 m from the top of the tree). In the absence of an education or trammg program, dtspensers have frequently been placed too low in the canopy (approx 1 8 m) Commercially, it is the experience of the authors and others (28,29) that low dispenser placement has resulted m many CM control problems. Improvements m methods for applying CM disruption products has greatly facilitated the use of this technology. In orchards with canopy heights >3 m, proper placement of dispensers during the first few years of commercial use could not be accomplished from the ground. Applymg dispensers with the assistance of ladders was time-consuming (up to 12.5 h/ha), and added considerably to the already high cost of control. Superior Ag (Yaktma, WA) recently introduced a very good method for applying tube and lammate dispenser types, using a combmation of a telescoping pole and a clap to whtch the dispenser is attached. Some manufacturers have engineered then dtspensers with a clip already attached Apphcation entails pushmg a clip holdmg a dispenser onto a selected branch and leaving it there when the pole 1stwisted and pulled away. It takes ProvIsional Aeglstratlon for 3 years, renewable once for another 3 years
2 years
v 7. Appkant re-submits ‘improved’ summary dossier to all Member States and to the Commission
f
I
Peer
Review
1 7. Rapporteur submits his evaluatton (Monograph) to the Commission together with a proposed declsron and addrtlonal data required
I
of Monographs
Toxicology
I
by Commission Expert Hearing of the Applicant? Environmental
9. Proposed
Fate
Groups
(5 Member
States)
Residues
Ecotoxtcology
Recommendatton
I
1
v (
9. Voting
In SCPH
I
v 9. Recommendation
3-4 years longer
to Commission
or
Fig 1. Contmued. theu- own evaluation of the dossier for provlslonal authonzatlon, when this has been requested by the Apphcant 3.1.5 Choice of Rapporteur Member Stare/Evaluation As mentioned earlier, there IS no guarantee that the choice of Rapporteur ~111 be the same as the original choice made by the Applicant. The decision IS made by Commission and Member States,depending on the workload of the countries
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3.1.6. Provisional Authorization for Plant-Protection
Products
1I Member States may grant Provisional Authorization for up to 3 yr after the Commission has confirmed that the dossier IS complete 2. However, Member States may dectde not to start evaluation until after ratilication by SCPH, I e., after monograph preparation 3. Member States may also be reluctant to take mulateral dectsions during early stages of mtroduction of Directive 91/414/EEC. 4 Provisional authorization may be very limited at first
3.1.7 Detailed Examination and Preparation of Monograph by Rapporteur (Dot 1654/V//94) The objectives are’ 1 To provide a full description of key points identified in assessing the database evaluated 2. To ensure a consistently high standard m the documentation and decision-making process. 3 To standardize the format, to ensure efficiency and economy in use of resources 4. To facilitate decision-making by Standmg Committee on Plant Health (SCPH) and by the Commission 5. To ensure transparency with respect to the basis for decisions made
3.1.8. Review of Monograph/Outcome
of Review
Proposals for decision by the Commission included m the monograph. 1. To include the active substance m Annex I of the Directive, stating the conditions of its inclusion, or 2 To postpone any decision on possible mclusion pending the submission of the results of additional trials or information specified, or not to Include the active substance in Annex I. Followmg such a decision, any existing provisional registrations would have to be revoked and the product would have to be withdrawn from the EC market.
3.1.9 Annex I Listing The proposed recommendations must be accepted by SCPH, on the basis of voting by a qualified majority. Politics of voting on mclusions plays a key role. Active substancescan be included on Annex I for a maximum period of 10 yr This procedure will cover all new biopesttcrdes to be registered tn the EU, as well as all existing biopesticides that will be the subject of the review process.
Those active substancesthat were registered m Europe prior to the pubhshmg of the Directive can continue to be marketed until they are reviewed, mcludmg the followmg: Ascherersonza aleyrodis; Agrotis segetum granuloszs virus; Bacillus sphaericus, Bacillus subtzlis, Bacillus thurzngienisz, Including; subspp azzewai; subspp israelensis; subspp kurstaki, Beauveria basszana,
Registration
in Europe
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Cephalasponum, Dacnusa sibinca, Digglyphus isaea: Meturhizlum amsopllae: nuclear polyhedrosts virus; Phleblopsls gigantea; Phytoseiulus persimllu; Steinernema feltiae, tomato mosaic wrus, Trichoderma sp; Veltlclllium dahlzae, Verticillium lecanii; vtrus granulose carp.; vnus noctuelles. 4. Data Requirements for Biopesticides as Active Ingredients Annex II, Part B, details the requirements for the mclusion of mtcroorganisms and viruses into Annex I as active ingredient, as shown in Table 2. 5. Data Requirements for Biopesticide Products Annex III, Part B, details the requirements for the dossier to be submitted for authorization of a plant protectton (formulated) product containing mtcroorganisms and viruses (not applying to genetically manipulated organisms, when tt 1s already covered under a prevtous Directive 90/220/EEC), as shown m Table 3 6. Latest Status In early 1996,EPPO (EuropeanPlant Protection Organisatton)/CABI (Commonwealth Agrtcultural Bureau Intematlonal) held an International Workshop on “Safety and Efficacy of Blocontrol in Europe.” In addition to thesebodies, representativesof the EU Commtssion, European and US government oftictals and regulators, and industry attended. The workshop recommended that, given the potential value of microbials in IPM, and the constraintsfacing small-scaleproducers of mtcrobtals, efforts should be made to make the registration of microbials more efficient and rapid. To achieve this, the workshop recommendedthat a tiered approachfor microbial testing be developed to reduce unnecessarytesting,and that changesbe made m processing time, m order to speed the process, i.e., a fast-track approach. However, in May 1996, the results of preparatory discussion in several five-expert groups on Annexes IIB and III B were provided to industry for comments. Many of those requirements listed earlier, t-e., as for chemicals, were still mcluded
The major concerns are as follows:
1. tiered structure includes 90-d toxicity studies m Tier I; 2 no flexibility m the study requirements. lack of harmonization with other OECD countries; 3, testmg of both technical and formulations; 4. residue data required m crops and environment; 5 preharvest intervals and re-entry intervals; 6. certain environmental and ecotoxlclty studies not relevant, and 7 efficacy data requirements not clear treated as “chemical ”
6.1. Uniform Principles: Delays in Directive 91/414/EEC The European Parliament issued a lawsuit before the EU Court of Justice m Luxembourg against the Uniform Principles, which establish Annex VI of the
Neale and Newton
462 Table 2 Data Requirements
for Biopesticides
as Active Ingredients
1 Identity of the organism 1 1 Apphcant (name, address, and so on) 1.2 Manufacturer (name and address, mcludmg location of plant) 1 3 Common name, or alternattve and superseded names 1 4 Taxonomtc name and strain for bacterta, protozoa, and fungi; mdicatlon whether tt IS a stock variant or a mutant strain, for vu-uses, the taxonomrc designation of the agent, serotype, strain, or mutant 1 5 Collectton and culture reference number where the culture 1s deposited 1.6. The appropriate test procedures and criteria used for tdentification (e g , morphology, biochemrstry, serology) 1 7 Composttion. microbiological purity, nature, Identity, properttes, content of any impurities, and extraneous organisms 2 Btologtcal properties of the organism 2 1 Target organism Pathogemcny or kmd of antagonism to host, infective dose, transmrsstbthty, and mformatron on mode of action 2 2 History of the organism and its uses Natural occurrence and geographical dtstrtbutton 2 3 Host-spectfictty range and effects on species other than the target harmful organism, including species most closely related to the target species To include mfecttvtty, pathogemclty, and transmtsstbtlity 2.4 Infectivity and physical stability when used according to the proposed method Effect of temperature, exposure to air radtatton, and so on Persistence under the likely environmental conditions of use 2.5 Whether the organism is closely related to a plant pathogen or to a pathogen of a vertebrate species or a nontarget invertebrate species 2.6 Laboratory evidence of genetic stab&y (i.e., mutation rate) under envnonmental condittons of proposed use 2 7 Presence, absence, or production of toxins, as well as their nature, identity, chemical structure (if appropriate), and stability 3 Further mformation on the organism 3 1 Function e.g , fungicide, herbicide, msecticrde, repellant, growth regulator 3 2 Effects on harmful organisms, e g , contact poison, mhalation poison, stomach potson, fungttoxtc or fimgistattc, and so on; systemic or not m plants 3 3 Field of use envisaged e.g , field, glasshouse, food or feed storage, home garden 3 4 When necessary, m the light of the test results, any specific agricultural, plant health, or environmental condttrons under which the active substance may or may not be used 3 5 Harmful organisms controlled, and crops or products protected or treated 3 6 Method of productton, with descrlpttons of the techniques used to ensure a umform product, and of assay methods for Its standardtzatton In the case of a mutant, detailed informatton should be provtded on its production and tsolatlon, together with all known differences between the mutant and the parent wild strains
Registration
in Europe
463
Table 2 (continued) 3.7 Methods to prevent loss of virulence of seed stock 3 8. Recommended methods and precautrons concernmg handling, storage, transport, or fire 3.9. Possrblhty of rendering the organism unmfectrve 4. Analytical methods 4.1 Methods for establtshmg the identity and purity of seed stock from which batches are produced and results obtained, including tnformatton on varrabrlrty 4.2 Methods to show microbrological purity of the final product, and showmg that contaminants have been controlled to an acceptable level, results obtamed and mformatron on variability 4.3 Methods used to show that there are no human or other mammahan pathogens as contaminants m the acttve agent, includmg, m the case of protozoa and fungr, the effects of temperature (35Y and other relevant temperatures) 4 4. Methods to determme vtable and nonvrable (e.g., toxins) residues m or on treated products, foodstuffs, feedingstuffs, animal and human body flutds and trssues, soil, water, and an, when relevant 5 Toxtcological, pathogemcity, and infectivity studies 5 1 Bacteria, fungi, protozoa, and mycoplasma 5.1 1 Toxicity and/or pathogenicity and infectrvtty 5.1.1.1 Oral single dose 5 1 1.2. In cases m which a single dose IS not appropriate to assess pathogemcrty, a set of range&ding texts must be carried out to reveal highly toxic agents and mfecttvtty 5.1.1.3 Percutaneous single dose 5.1 1.4. Inhalatron single dose 5.1 1.5 Intraperitoneal single dose 5 1 1.6 Skm and, where necessary, eye nritatron 5 1 1.7 Skin sensitrzation 5 1 2. Short-term toxrcrty (90-d exposure) 5.1.2.1. Oral administration 5.1.2.2. Other routes (mhalatton, percutaneous, as appropriate) 5 1.3 Supplementary toxtcologrcal and/or pathogemcity and mfecttvuy studies 5 1.3 1. Oral long-term toxtcrty and carcinogemcny 5 1.3.2. Mutagenicity (tests as referred to under point 5.4. of part A) 5 1.3.3 Teratogenictty studies 5 1.3.4 Multrgeneratron study in mammals (at least two generations) 5 1 3.5. Metabolic studies. absorptton, dtstrtbutron, and excretion m mammals, mcludmg elucrdatton of metabohc pathways 5 1.3.6. Neurotoxictty studies, mcludmg, when appropriate, delayed neurotoxrcrty tests m adult hens
464
Neale and Newton
Table 2 (continued) 5.1 3.7 Immunotoxicity, e.g , allergemcity 5 1.3 8. Pathogemcity and infectivity under immunosuppression 5.2. Vu-uses, viroids 5 2.1 Acute toxicity and/or pathogemcity and mfectivtty. Data as outlined under point 5.1 l,, and cell-culture studies using purified infective vnus and primary cell cultures of mammahan, avian, and fish cells 5 2 2. Short-term toxicity Data as outlmed under point 5 1.2 , and tests for mfectivrty carried out by bioassay, or on a suitable cell culture at least 7 d after the last administration to the test animals 5 2 3 Supplementary toxicological and/or pathogemcity and mfectivity studies, as outlined under pomt 5.1 3. 5.3. Toxic effects on livestock and pets 5.4. Medical data 5.4 1. Medical surveillance on manufacturing plant personnel 5 4.2 Health records, from both mdustry and agriculture 5 4 3 Observations on exposure of the general population, and epidemiological data, if appropriate 5 4 4 Diagnosis of poisoning, specific signs of poisonmg, chmcal tests, if appropriate 5 4 5 Sensrtization/allergemcity observations, tf approprtate 5.4 6. Proposed treatment first aid measures, antidotes, medical treatment, if appropriate 5 4 7 Prognosis of expected effects of poisoning, if appropriate 5 5 Summary of mammalian toxicology and conclusions (mcludmg NOAEL, NOEL, and ADI, if appropriate) Overall evaluation regarding all toxicological pathogemctty and infectivity data, and infectivity and other mformatron concerning the active substance 6. Residues in or on treated products, food, and feed 6 1 Identification of viable and nonviable (e g., toxms) residues m or on treated plants or products, the viable residue by culture or bioassay, and the nonviable, by appropriate techniques 6 2. Likelihood of multiphcation of the active substance m or on crops or food, together with a report on any effect on food quality 6 3 In cases m which residues of toxins remain in or on an edible plant product, data as outlmed under points 4.2 1 and 6. of part A are required 6 4. Summary and evaluation of residue behavior resulting from data submitted under points 6.1-d 3. 7 Fate and behavior in the environment 7.1 Spread, mobility, multiplicatton, and persistence m an, water, so11 7 2 Information concerning possible fate m food chains 7.3 In cases m which toxins are produced, data as outlined under part A, point 7 , are required, when relevant
Registration
in Europe
465
Table 2 (continued) 8. Ecotoxlcologlcal studies 8 1 Birds. acute oral toxlclty and/or pathogeniclty and mfectlvlty 8 2. Fish: acute toxicity and/or pathogemcity and infectivity 8 3. Toxicity, Daphnza magna (if appropriate) 8 4 Effects on algal growth 8 5. Important parasites and predators of target species; acute toxicity and/or pathogemclty and mfectivlty 8.6. Honeybees* acute toxicity and/or pathogenicity and infectivity 8 7. Earthworms acute toxicity and/or pathogemcity and infectivity 8 8 Other nontarget organisms believed to be at risk acute toxicity and/or pathogemclty and mfectlvlty 8 9 Extent of indirect contamination on adjacent nontarget crops, wild plants, soil, and water 8 10 Effects on other flora and fauna 8 11 In cases m which toxins are produced, data as outlined under Part A, points 8.1 2 ,8 1 3., 8 2 2 , 8.2 3., 8 2.4., 8.2.5 , 8.2.6., 8.2 7., and 8 3 3 are required, when relevant 9 Summary and evaluation of points 7. and 8. 10 Proposals mcludmg Justification of the proposals for the classification and labelmg of the active substance m accordance with Directive 67/548/EEC Hazard symbol(s) Indications of danger Risk phrases Safety phrases 11 A dossier, as referred to m Annex III, Part B, for a representative plant protection product
Plant Protectlon Dtrecttve 91/414/EEC. The European Parliament is reasoning that, for formal reasons, it was not able to check if the Unlform Prmclples adhere to the EU environmental policy, and was not heard in the leglslatlve process. This should have been mandatory, because the Uniform Prmclples have departed from the framework of the Plant Protection Directive (through derogation of the ground water standards), and violate the Drinking Water Directive (derogation from 0.1 pg/L possible). On April 30, 1996, the Advocate General proposed the annulment of the Uniform Prmclples. If the court follows the advice of the Advocate General (which It usually does), the Uniform Principles will be declared null and void. The Judgment on this case was given on June 18, 1996, In favor of the European Parliament. The matter IS still under discussion
Neale and Newton
466 Table 3 Data Requirements
for Biopesticide
Products
1 Identity of the plant protection product 1 1. Appltcant (name, address, and so on) 1 2 Manufacturer of the preparation and the acttve agent(s) (names, addresses, and so on, Including location of plants) 1 3 Trade name, or proposed trade name, and manufacturer’s development code number, or the plant protectton product, tf appropriate 1 4 Detailed quantitative and qualttatlve mformation on the composition of the plant protection product (active orgamsm[s], met-t components, extraneous organisms, and so on) Physical state and nature of the plant protectton product (emulstfiable concen15
trate, wettable powder, and so on) 1 6. Use category (insecticide, fungicide, and so on) 2 Technical properties of the plant protection product 2 1 Appearance (color and odor) 2 2. Storage stability stabtltty and shelf life. Effects of temperature, method of packaging and storage, and so on, on retention of btologtcal activity 2 3 Methods for estabhshmg storage and shelf-life stability 2 4 Technical characteristics of the preparation 2 4 1. Wettabihty 2 4 2 Persistent foaming 2.4 3 Suspenstbthty and suspension stability 2 4 4 Wet sieve test and dry Steve test 2 4.5 Particle-size distributton, content of dust/fines, attrition, and friability 2.4.6. In the case of granules, sieve test and mdtcations of weight dtstributlon of the granules, at least of the fraction with particle sizes bigger than 1 mm 2 4.7 Content of active substance m or on ban particles, granules, or treated seed 2 4 8. Emulsttiabihty, re-emulsifiability, emulsion stability 2 4.9 Flowabtlrty, pourabthty, and dustabtlity 2 5 Physical and chemical compatrbiltty with other products, mcludmg plant protection products with which its use IS to be authorized 2 6. Wetting, adherence, and distribution to target plants 3. Data on appltcation 3 1 Field of use, e g , field, glasshouse, food or feed storage, home garden 3.2 Details of intended use, e g , types of harmful organism controlled and/or plants or plant products to be protected 3 3 Application rate 3 4 Where necessary, because of test results, any specific agricultural, plant health, and/or environmental conditions under which the product may or may not be used 3.5 Concentratton of acttve substance m material used (e.g., % concentration m the diluted spray)
Registration
in Europe
467
Table 3 (continued)
4
5
6.
7
3.6. Method of application 3.7. Number and ttmmg of applications 3 8. Phytopathogemcity 3.9 Proposed mstructtons for use Further mformation on the preparatron 4 1 Packagmg (type, matertals, size, and so on), and compatibthty of the preparation with proposed packagmg materials 4 2 Procedures for cleaning application equipment 4 3 Re-entry periods, necessary wartmg penods, or other precautions to protect humans and animals 4 4. Recommended methods and precautions concerning handlmg, storage, transport 4 5 Emergency measures in case of an accrdent 4 6 Procedures for destructron or decontammatron of the plant-protectton product and its packaging Analytical methods 5 1. Analytical methods for determinmg the composttron of the plant-protectron product 5.2 Methods for determming residues m or on treated plants, or m or on plant products (e g., btotest) 5.3. Methods used to show microbiologrcal purity of the plant-protectron product 5.4. Methods used to show the plant-protectton product to be free from any human and other mammalian pathogens or, rf need be, from honeybee pathogens 5.5 Techniques used to ensure a umform product and assay methods for Its standardization Efficacy data 6 1. Preliminary range-findmg tests 6.2 Field experimentatron 6 3 Information on the possible occurrence of the development of reststance 6 4. Effects on the quality and, when appropriate, on the yield of treated plants, or effects on the qualny of treated plant products 6 5. Phytotoxrcity to target plants (including different culttvars), or to target-plant products 6.6 Observations concernmg undesirable or unintended side effects, e.g., on beneficial and other nontarget orgamsms, on succeeding crops, other plants, or parts of treated plants used for propagation purposes (e g., seeds, cuttmgs, runners) 6 7. Summary and evaluation of data presented under points 6.1.-6 6 Toxrctty and/or pathogeniclty and mfectivrty studres 7.1 Oral single dose 7 2 Percutaneous single dose 7.3 Inhalation 7 4 Skm and, where relevant, eye irrttation (continued)
468
Neale and Newton
Table 3 (continued)
7 5. Skm sensrttzatton 7.6 Available toxrcologrcal data relating to nonactrve substances 7 7 Operator exposure 7 7 1. Percutaneous absorptron 7 7.2 Lrkely operator exposure under field conditrons, including, where relevant, quantitattve analysrs of operator exposure 8 Residues in or on treated products, food, and feed 8 1 Residue data concerning the active substance, including data from supervrsed trials m crops, food, or feedingstuffs for which authorrzatron for use is sought, grvmg all experimental condmons and details Data should be available for the range of different clrmatrc and agronomic condmons encountered m the proposed area of use It IS also necessary to identify viable and nonviable residues m treated crops 8 2 Effects of industrial processing and/or household preparation on the nature and magnitude of residues, rf appropriate 8.3 Effects on taint, odor, taste, or other quality aspects because of residues on or m fresh or processed products, if appropriate 8 4 Residue data m products of animal origin, resulting from mgestron of feedmgstuffs or contact with bedding, rf appropriate 8 5 Resrdue data m succeeding or rotatronal crops, where presence of residues might be expected 8 6. Proposed preharvest intervals for envisaged uses or wrthholdmg periods, or storage perrods, m the case of postharvest uses 8 7 Proposed maximum residue levels (MRLs) and theJustification of the acceptability of these levels (for toxms), if appropriate 8.8 Summary and evaluation of the restdue behavior on the basts of the data submttted under points 8 1 -8 7 9 Fate and behavior m the environment 9.1. In cases in which toxins are produced, data as outlined under Part A, pomt 9 , are required, rf appropriate 10. Ecotoxrcologrcal studies 10 1. Effects on aquatrc organisms 10.1 1. Frsh 10.1.2. Studies m Duphnza magna, and m species closely related to the target organisms 10 1 3. Studies m aquatic mrcroorgamsms 10.2 Effects on beneficial and other nontarget organisms 10 2 1. Effects on honeybees, rf appropriate 10.2.2. Effects on other beneficial organisms 10.2 3. Effects on earthworms 10 2.4. Effects on other soil fauna 10.2.5. Effects on other nontarget organisms believed to be at risk 10 2.6. Effects on soil mrcroflora
Reglstratlon m Europe
469
Table 3 (continued) 11. Summary and evaluation of pomts 9. and 10. 12. Further mformation 12.1 Information on authorizations tn other countries 12 2. Information on established MRLs in other countries 12.3. Proposals, mcludmgJustification for the classification and labeling proposed in accordance with Directives 67/548/EEC and 78163 l/EEC Hazard symbol(s) Indications of danger Risk phrases Safety phrases 12 4. Proposals for risk and safety phrases In accordance wtth Article 15(l)(g) and (h) and proposed label 12 5. Specimens of proposed packagtng
7. The Next Steps to Harmonization of Data Requirements and Registration of Biopesticides One of the conclustons of the paper commtssroned m 1994 by the Pesticide Forum (1) was that Industry felt that the OECD’s most useful role would be m assisting m the development of public policy by providing information and possibly an international forum to promote international harmomzation of data requirements, test procedures, and criteria for interpreting the results. The OECD survey (I) has gone a long way toward this. The next step, to convmce Member Countries to accept a common approach and mterpretation of results, is difficult. However, action has recently been taken by the Canadian and United States authorities on the harmomzation of guidelines on semtochemtcals and pheromones. This is a very posttive approach, but tt must be taken on a global basis if true harmonization of regulations is to be achieved. Based on the experience of the United States, industry proposed that the tiered system used by the EPA serve as a model for all OECD countries. European regtstration requirements and registration of btopesticides, including genetically modified plants and organisms, would benefit from thts approach (for comparison, see Table 4). However, the draft Directive 91/414/EEC does not incorporate these proposals fully. Industry expressed Its disappomtment to the Commtsston and sent its comments. The next meeting of the OECD Pesticide Forum on the harmonization of test guidelmes was to take place in Autumn 1997. Unless there is a fundamental change in the recommendations and requirements listed in the Annexes IIB and IIIB, little progress 1senvisaged on real harmonization on registration of biopesticides
Residues m food or environment Biological control agents, e g , nematodes Pheromones
Ease of regulations
Exempt
Established m 1984, modified in 1994 to ease notificatron Exempt
IO (mcludmg genetically engineered Bt)
Number of new microorganisms registered m last 24 mo Regulations for GMOs
Time scale for reviews
Tier I sufficient for most bropesticides Attempting to reduce from 8 to 6 mo
Ttered testing procedures
European Union
of Biopesticides
Under review, questions on nematodes No clear policy---considered under 91/414/EEC as chemical
EU system expected 12 mo for acceptance m Brussels, plus addrtronal 12-18 mo for evaluation 0 several m the “queue,” but cannot be registered until system is in place) 9012 19lEEC 90/220/EEC 91/414/EEC Proposal for mclusion in Tier 1
Comments
Canadian requirements also lessened
EU countries are not able to register new organisms independently EU Directives under revrew
Still under discussion with Commission Registration time m EU coun varies from 15 to 24 mo
No specific regulatory body for biopesticides Annex II B / III B of 91/414/l under development
for Plant Protection
EU Standing Commntee/country’s regulatory authontres Currently covered by EC Directive 91/414/EEC, but country requirements differ EU Proposed directly mto Tier II
Union Registration
United States
States and European
EPA’s Biopestictdes and Pollution Prevention Division Subdivisron M and 40 Code of Federal Regulations Part 158
of United
Organizational/ registration unit Gmdelmes/reqmrements
Area
Table 4 Comparison
Registration
in Europe
471
InternatIonal harmonlzatlon, and the provlslon of a uniform set of rules, would not only lower costs without increasing risks, but would also give encouragement to the development of new technologies for rational and sustainable agriculture. References 1 Draft OECD Monograph No 106-Data Requtrements for Reglstratlon of Blopestlcldes m OECD Member Countries Survey Results Paris 1995 2. Neale, M. C (1996) Registration of Blopestlcides m the EU update of the OECD Harmomsatlon Program for Blopestlcides, IBC Conference, London 3 Betz, F. S (1995) Regulation of blologlcal control agents in the Umted States, m Mzcrobzal Control Agents zn Sustaznable Agrzculture, Aosta. 4 Neale, M C (1995) Mlcroblal Pestlcldes wlthm the EC Reglstratlon dlrectlve 91/ 414/EEC-the need for Harmomsatlon, m Mzcrobzal Control Agents zn Sustaznable Agrmlture, Aosta 5. Bode, E. (1995) Authorlsation of blologlcal plant protectlon agents m Germany present status and future prospects, in Mcrobzal Control Agents in Sustatnable Agrzculture, Aosta 6 Llsansky, S G (1994) International harmomsation m blopestlclde reglstratlon and Ieglslation, m Brighton Crop Protection Conference, Farnham, UK
25 Environmental
and Regulatory
Aspects
industry View and Approach Joseph D. Panetta 1. Introduction Since 1947, when the Federal Insecticide Fungicide and Rodentictde Act (FIFRA) was first passed, almost 20,000 pesticide products have been registered, mitially by the US Department of Agriculture (USDA), and, more recently, by the US Environmental Protection Agency (EPA). These products are composed of some 1000 active ingredients, but, of these, only about 150 can be defined as biopestictdes (I). Biopesticides are defined as a group of products that are distmgutshable from conventional chemical pesticides by their nontoxic mode of action, their specificity to target pests, and, most tmportantly, by the fact that they are, or can be, produced by living organisms (2). For the first 50 yr of FIFRA regulation, there were two basic categories of btopesttcides. Microbial pestictdes, including algae, bacteria, fungi, protozoa, and vtruses, are biopesttcrdes that express activity through various modes of action, such as the production of a toxin or by pathogemcity. Biochemical pesticides are not as clearly distmgmshable from conventtonal chemicals as are the microbials, but, in general, are of natural origin and act through a nontoxic mode of action. Some examples of biochemicals are natural plant-growth regulators, which inhibit, modify, or stimulate plant growth; semiochemicals or pheromones, which are emitted by a plant or animal, and effect the behavior of similar or other species; hormones that are synthesized m one part of an organism and translocated to another, where they have controlling or regulating activity; and enzymes or protein molecules that control gene expression or catalyze reactions. From Methods m Botechnology, vol. 5 B/opestmdes Use and Del/very Edlted by. F R Hall and J J Menn 0 Humana Press Inc , Totowa, NJ
473
474
Panetta
Recently, the followmg new categories of btologtcal pesttcrdes have been defined. Nonviable mtcrobtal pesttctdes, first registered m 1991, are produced as live mtcrobtals, and are inactivated prior to then formulatton as biopesticides. The only examples of these actrve ingredients that are currently registered are &endotoxms of Baczllus thuringzenszs (Bt) encapsulated m killed Pseudomonasfluorescens; and plant pesticides, first registered m 1995 m the United States,which are pestrctdal materials produced m plants To date, there are SIX registered active-ingredient plant pesticides in corn, cotton, and potato, all of which are expressed as Bt toxms. The first commercial btopestrcide was registered in the Umted States m 1948, very shortly after FIFRA was passed; this was Bacillus poplllrae, for control of Japanese beetle larvae (3). Thirteen years elapsed before commerctaltzatton of the next mtcrobtal pesticide, Bt var thurzngienszs (later replaced by var kurstakz). The real interest m microbial biopesttcides began m about 1980; smce then, 45 or so mrcrobtal pesttcides have been registered. This figure includes the most widely used active ingredients: various Bts for control of leptdopteran, coleopteran, and dtpteran larvae. The United States market for Bt products for control of pests m fruits, vegetables, and field crops has been estimated to be about $24 mrlhon (4). The successof Bt and Bt-based btopestrcrdes has far exceeded that of other btopesttctdes m terms of use and acceptance. Recently, use of Bts has increased even more as the result of several factors: the discovery of new strams with novel msect activity, such as Bt var tenebraonu, for control of Colorado potato beetle; improvements m fermentation methods, controls, and equipment, Improvements in formulation technology; use of btotechnology to improve potency, spectficrty, and persistence m the field; and development of reststance to synthetic chemicals. Registration of btologicals for control of insect pests has been far more common than that of other apphcattons, such as fungicide or herbtctde use. Recently, new types of mrcrobrals for control of insect pests have been commerctaltzed. For example, the fungal pathogen Beauvaria basszana is now being sold for control of several arthropods, including Mormon crickets, grasshoppers, locusts, and soft-bodied Insects, as well. The first nuclear polyhedroSISviruses (NPVs) for control of insects were regtstered m 1975 for control of hellothis m cotton. Smce then, NPVs have been registered for control of Douglas fir tussock moth, gypsy moth larvae, beet armyworm larvae, and alfalfa looper. These products have experienced fairly limited success,because of several factors, mcludmg a rather slow mode of action, and overlap m target pest activity with Bt products and chemical pesticides. New vn-us-based products are currently being tested in the field in the United States for control of crop pests. Recently, products containing NPV became commercially available for
industry View of Regulatrons
475
control of beet armyworm, celery looper, and codling moth. NPV products have been used for some time in Central and South America, Asia, and Africa, for control of caterpillar pests in vegetables. Current efforts to use genetic engineering techniques to enhance virus activity may lead to greater acceptance in the future (5). In the btochemtcals area, insect pheromones are being used for the most part m cotton, fruit, and vegetables, as mating disrupters. Accordmg to a US Office of Technology Assessment study m 1995, pheromone use in 1995 for control of the pink bollworm in cotton m Arizona was on about 80,000 acres, or onefourth of the state’s cotton crop. Pheromones are also bemg used successfully for control of the apple codling moth-acreage on which one such product, Isomate (Oregon State Umverstty, Corvalis, OR), has been used on about 500025,000 acres from 1991 to 1993, prmcipally because of the development of resistance to tradtttonal chemical pesticides, and as a tool m a mass suppression program (5). Biologtcal herbtcides have tradtttonally presented challenges m development and commerctahzatton, because they do not persist well m the envn-onment, and can be used only m niche markets, makmg research and development costs dtfficult to justify. Mycogen (San Diego, CA) has been undertaking research m biological herbicides since 1985, with tmprovmg success,as these factors are addressed through better formulatton and improved potency One product showing much promise contains Pseudomonas syringae for control of Canada thistle m soybeans and other crops. Regardless of the past limitations of biologtcal pesticides, they are becommg a more sigmficant force m crop protectton. Btopestictdes have been given a major role in efforts to adopt integrated pest management (IPM), because farmers, consumers, and the EPA, concerned about the potential health and environmental effects of conventional chemtcals, are m search of alternatives EPA has recently encouraged the registration of reduced-risk pesttctdes, and biological pesticides m particular, because of then typically low mammalian toxicity and envtronmental impact. The renewed interest in these products has spurred the growth of biopesticide development programs by established producers of conventtonal chemicals, and the formatton of new companies, such as Mycogen, whose sole focus 1sresearch, development, and commerctaltzatton of btological pest-control products. In 1993, the Clinton Admmistratton announced tts support of btopesticide development and commercralization, in committing to intensifying efforts to reduce the use of higher-risk pesticides and promoting IPM, mcludmg btological control. Progress in the registration of biopesticides 1sdirectly related to efforts by the biopestlcide industry and EPA’s Office of Pesticide Programs (OPP), working together to obtain a more effective and efficient product-registration pro-
476
Panetta
cess.The focus thus far by industry has been to identify market niches m which there is a need for a biopesticide because there are no acceptable means of control. In some cases,m which resistance has developed to a synthetic chemrcal pesticide, a biopesticide can fill the need for a control product. Biopesticides have also been used as alternatives to some more acutely toxic chemical products. EPA shares responsibility for field release of biopesticides with USDA’s Animal and Plant Health Inspection Service (APHIS), which is responsible for permittmg field release of nonmdigenous organisms with the potential to be plant pests. While significant progress has been made in streamlining the review processes of both EPA’s OPP and the USDA’s APHIS, but there are opportunities for the biopesticide industry and the two government agencies to work together to develop and more efficiently review data for approval of products. The formation of the Biopesticides and Pollution Prevention Division within OPP/EPA has provided a more effective focus on the uniqueness of btopesticide registration, moving away from what was in the past a process of treatmg btopestictdes m the review process generally as chemicals with fewer data requirements At the same time, there are areas in which improvements are needed, in terms of legislation and regulations, in particular. These aspects are discussed m the following sections m greater detail. 2. Industry’s Progress in Product Development Before movmg into a discussion of the progress of the regulatory process, it is tmportant to consider advances in product development and the current state of the art in terms of available biopesticide products. Why are more biopesticides being used now than in the past, aside from the obvious fact that more are available now? As mentioned, biopesticide products present a number of advantages to users. Chief among these is the fact that bropesticides are typically of low toxicity to mammals and other nontarget organisms. This results m direct and indirect advantages. For example, a direct advantage is that fieldworker exposure concerns are minimized by the application of a biopesticide. An example of an indirect advantage ts that a biopesticide restdue on a crop is normally inconsequential from the standpoint of human dietary exposure, because most biopesticrdes and all microbial pesticides are exempted from the requirements of crop-residue tolerances. When comparing all of the available biopesticide products to available conventional synthetic chemical products, one fact clearly stands out: biopesticide products are not subjected to the complex battery of toxicity and crop-residue tests required to evaluate potential long-term effects, such as carcinogemcity, chronic toxicity, and reproductive effects. In addition, most biopesticides are not subjected to the extensive battery of tests to evaluate persistence and other long-term effects m the environment. These studies can cost $10-20 million,
hdustry View of Regulations
477
depending on the number of crops on which the product is to be applied, making the development of a conventional chemical pesticide a significant cost factor. A positive result m any one test can result in severe restriction of uses or failure to obtain registration. Biopesticides, in contrast, are not nearly as exposed to registration costs or potential failures m the registration process. Mycogen has incurred biopesticide registration costs of lOO L/ha (30). This very expensive form of application can beJustified in order to achteve timely moculatron of a pathogen that develops epizootlcs tn semmatural environments of a mountamouscountry with an ecologically aware populace 3.2.2. Rotary Atomizers: Appropriate Deployment and Tools for Research Hydraulic spraying IS notortously inefficient (31) and many appltcatton research efforts have attempted to use less pesticide by applying it more efficiently (32). Of all the controlled droplet application (CDA) techniques, the use of rotary atomizers has been most widely adopted. One of the most conspicuous exceptions to the use of hydraulic sprayers has been m ULV applica-
516
Baternan
tion of bropesttcrdes for the treatment of natural and semmatural ecosystems (e.g. forestry [20,33,34J and locust control [35]). Lowermg volume application rates has necessitated detailed analysts of formulatton, droplet size, and recovery (36). Parkm and Merritt (3 7) emphasized the need to establish protocols for evaluating such issues as spray drift and to build a comprehenstve database, but unfortunately, despite maJor initiatives, such as the Spray Drift Task Force in the United States,little of this information 1sm the pubhc domain. Although the final ObJectivemust be to adapt btopesttctdes to existing applrcation practrce, small spinning disk sprayers have been used for a wide range of laboratory and “pre-field” tests (see Subheading 3.3.). Equipment for the assessmentof pesttcides has been reviewed by Matthews (36); a particularly useful 25toothed rotary atomrzer developed by J. S. Clayton creates relatively small numbers of droplets that simulate field dosages in a confined space (38). Rotary atomizers have several advantages, includmg: 1, They produce of droplets that are more commensurateto field apphcattonsthan spray residuescreatedwrth standardequrpment,suchasthe Potter tower (36), 2. They enableeasyspray apphcation of small quantitiesof experimental products (that may also block narrow Pottertower or “air-brush” nozzles);and 3 Theyproduceanarrow dropletsizespectrumwrth aVMD that easilycanbeadJusted by regulatmgthe apphedvoltage. The residuesproducedthereforeconsistof more succmct“doses” thatsnnplify the processof pathogenacqulsrtronby the targetpest Although rotary atomrzers are very useful as research tools, rt is important to be aware of the differences between preliminary tests and field trials using hydraulic sprayers. For example, the shearmg action on a formulation by pumps and nozzles has been shown significantly to affect suspended particle dtameters, especially m formulations containing emulsified oils (27) There IS a much more substantial decrease (by a cubic function) m the volume of matter these particle diameters represent; this mathematical relationship must also be remembered when interpreting droplet size spectra, 3 2.3. Measuring and Interpreting Droplet Size Spectra Although further researchISalways needed, the droplet sizebands that are most likely to achieve satisfactory dose transfer have been published by several authors (32,39,40). A certain amount of fundamental work has also been done with chemtcal rnsectrcrdesthat relates “optimum” droplet srzeswrth application rate and field concentratton (e.g., 41). There 1sa wide range of techniques available for measuring droplet sizes,either in flight after leaving the nozzleor after collection on arttficral surfaces in the target zone (32,42). Laser particle size analyzers provrde a raprd meansof measurmgthe droplet sizespectraof spraysas they leave the nozzle; the data is processedelectronically and can therefore easily be entered mto databasesfor further analysis. Estimatesof the numbers of particles m each stzeclass
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can be deduced from this data (43), which 1suseful when developmg a formulatron and estimating an appropriate dilutron for the final tank mix. Figure 2 shows some droplet srze spectra produced by a range of both experimental and operattonal nozzles. As well as rotary ULV sprayers, pathogens have been applied at low volume apphcation rates with both thermal (#dj and cold (45) fogging equipment. Although flat fan (or hollow cone) hydrauhc nozzles are most commonly used, some biopesticrde researchers have preferred anvil tips smce they are less prone to blockage with experimental (and surprtsingly some commercial) formulattons. The spectra illustrated were measured with a “Malvern 2600” particle size analyzer (using its “model Independent” analysts) and should be constdered stmply as examples for tllustratton. This 1sa spattal sampling technique that gives similar results to temporal sampling with CDA sprays; however, some authorrties prefer to adJustfor droplet veloctty when mterpretmg hydraulic nozzle data (46-&I). Blank formulatrons have been used m these tests (water + 0.1% Agral 90 for the hydraulic nozzles), but adJuvants (which may offer the greatest scope for enhancing a pathogen’s delivery /49/arid efficacy in hydraulic systems)can have a profound effect on droplet spectra (50) Juxtaposed with the droplet sizegraphs in Fig. 2 are secondary x axes showing the numbers of colony forming units (cfu) or similar Infective partrcles (of any reasonable size) that can be expected to occur in each size class,assuming a random distrrbutron m the spray tank. These have been calculated by convertmg droplet diameters to volumes (m prcohters or 10-t* L) and multiplying by the numbers of cfu per unit volume in the tank mix; microbtologists usually work tn terms of cfu/mL so a factor of IF9 must be used. The volume scalesare simple arithmetic transformatrons from the diameters and end with a vertical lme representing the point at which there ISlO km2
1 krn2b 1okm*
0.25 ha
100 m2
Preferred plot size
Only)
0.25 hab 4 ha
Minimum plot size
Trials (for Guidance
10~1000
50-200
l-5 3-10 15-50
Track spacing (typical range)
‘Irery low volumeappllcatlon(often meaningwater-based sprayingat ~20 L/ha wltb rotary sprayers). %mallerplotsmay beexcusableunderexceptionalcmumstances, but should be avolded wherever possible
Hand-held hydraulic, VLVa and so forth Hand-held dnfi sprays Vehicle, aerial @ ~3 m off ground Aerial @ = 5 m off ground Aerial @ l&30 m off ground
Treatment type
Table 1 Plot Sizes and Spacing
10m 100m 200 m 500 m lkm
Mmlmum downwind distance to next plot
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deposItIon. The choice of plot size must, of course, take pest behavior mto account, and there may also be “trade off’ between maxlmlzmg plot size and mimmlzing the size of the total trial (or block) in order to treat reasonably homogeneous target populations. In the absence of sophisticated analytical equipment, spray deposition must be estimated from droplet numbers usmg formulation-sensltlve cards or other means of tracing spray deposits onto natural surfaces A well-known technique for appllcatlon research 1sthe use of pigments mixed mto the formulation that show the presence of droplets with portable UV lamps (#2,59). Optical bnghteners, such as “Tmopal” and “Uvltex,” can be used m a slmllar way and their addition to operational formulations could confer addltlonal benefits, mcludmg UV protection (60) and determmatlon of batch viability for mycomsectlcldes (61). An assessmentof fohar coverage 1sneeded for blologlcal herblcldes and msectlcides that have a stomach actlon (e.g., B thuringzensu, viruses). There may only be time for very approximate assessmentsof droplet size recovery under field condltlons, but these can be espectally useful if a large number of samples are taken (43). It can also be useful to assessthe level of direct contact to target insects; this may be very variable, depending on the application technique, meteorologlcal condltlons at the time of spraying, and crop architecture (2). 3.4 2. Assessing Modes of Pathogen Act/on in the field Measuring the relative importance of direct contact and secondary pick-up from fohage IS important with pathogens that have a contact action (such as mycomsectlcldes). Prefield trial studies are valuable, but should be followed by an assessmentof the acqulsltlon of pathogen propagules in the field; this may require approaches that are different from chemicals (for example, searches for locust cadavers after spraymg mycoinsecticides are often fruitless) Thomas et al. (62) used open-bottomed field cages to assessthe relative importance of the Initial contact and secondary acqulsltlon of the residue With the aid of models, such cages also can be used to assessthe decay of the spray residue and any increase m the level of moculum as a consequence of subsequent sporulatlon of cadavers. However, insects placed in cages are subject to an artificial microenvironment, especially when the pathogen-host interaction 1s sensitive to temperature and humidity (63). Cross-contammatlon and high control mortality can also be a problem. Besides accounting for direct acqulsltlon of applied blopestlcides and secondary cyclmg (horizontal transmlsslon), models may also be used to estimate. 1 Immlgratlon and emigration of mdlvlduals from trial plots, 2 The lag time between mfectlon and pest mortahty under field condltlons, and 3 Effects of the environment on pest-pathogen mteractlons (e.g , thermoregulatory behavior for combatmg infection)
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and Analysis
Further guidelines on assessing mortality of slow-acting pestlcldes used against locusts are suggested by FAO (64). It is most important to record carefully all relevant data during a trial: The FAO Pesticide Referee Group have set minimum standards of reporting. Here again, locust control provides us mternatlonally recognized protocols; unfortunately this 1sunusual m agricultural research. Cage samples are almost invariably taken to establish that dose-transfer and infection have taken place, and to ensure that at least some mformatlon 1s recovered even if other assessments fall. Data from cage mcubatlons can be treated similarly to bioassay results with results presented graphically or summarlzed with a few key statistics. One of the simplest statlstlcs to calculate IS the median lethal time (MLT): the number of days to achieve an accumulated 50% mortality (using linear interpolation of cumulative, dally mortahtles). The slgmold mortality curve may not be symmetrical, so such statistics as the average survival time (AST) are more appropriate since they incorporate all the data. Results obtained with basic AST formulas are affected by sample size and the end point of the experiment if not all the msects die Medical statistical techniques, such as Kaplan and Meier’s survival analysis method (65) overcome this problem, and have been used m the analysis of mycopesticlde trials The most substantial measure of success will always be demonstration of pest population reductions m the field, the length of time populations are suppressed, and ultimately yield increases for crops; there are several standard texts for the analysis of such data. Percent efficacy can be simply estimated using the formula of Henderson and Tilton (66). Statlstlcal procedures now exist to analyze data on a day-by-day basis using “repeated measures” techniques or split-plot ANOVA designs when the level of auto-correlation between sampling dates is small (67,68).
4. Conclusions Most successful blopestlclde development projects are achieved with multidisciplinary efforts. They start with a promising pest-pathogen mteractlon, pass through production, formulation, and application development (the “delivery system”) m conJunctlon with field testing, then contmue reglstratlon and commerciahzatlon. 1 The most likely scenario for lmplementatlon will be the development of commercial products by small- to medium-scale compames and ~111involve a “package of technology” (developed at least m part with the ald of public funds) 2 One of the most crltlcal stages in development 1s the passage from laboratory to field This IS an essential element of the practical verlficatlon process that provides a link between sclentlfic research and product development. The estabhshment of low environmental impact 1s especially Important with blopestlcldes and
524
Ba teman these studies are now rightfully being well supported Unfortunately, the thorough practical vertficatton of baste delivery systems 1sstall margmahzed, smce It is not considered to be “cutting edge” sctentific research and IS too expensive for smaller commercial enterprises There 1s a great temptation to develop a package of technology that involves novel formulation and/or appltcatton techniques. However, if biopestictde products are to have a role in broad acre agrtculture, they should be adapted to existmg delivery systems as much as possible. Farmers and growers are unhkely to adopt btopestlctdes rf they are obliged to radically alter existing practtce The examples described here in greatest detail represent an exceptional apphcatton scenarto that proves the rule: ULV spraymg is the normal method of application for locust msecticides. However, m many cropping systems such techniques as CDA are underresearched, pressures to develop alternattve methods of btopesttctde application may be given greater impetus with the genuine lmplementatton of IPM The development of models can be very useful for improving the understandmg of infection processes, but a step-by-step empirtcal approach to testing is also rigorous and provides essential data for the registration of products In the foreseeable future btopestictdes will occupy mche markets, therefore, fundmg for development research for mdtvtdual products will be hmited The refinement of protocols that maximize the cost-effecttveness of testing will Improve the chances of tmplementmg these valuable tools for integrated pest management
References 1. Georgts, R (1997) Commerctal prospects of mtcrobial msecttctdes m agriculture, m Mcroblal Insectlcldes Novelty or Necessity? British Crop Protection Council ProceedwgsMonograph Series No. 68, pp. 243-252. 2 Bateman, R P. and Thomas, M (1996) Pathogen application agamst locusts and grasshoppers: insecttctde or btological control? Antenna 20, 10-15. 3 Petch, T (1925) Entomogenous fungi and thetr use in controllmg insect pests Bulletin of the Department of Agrrculture, Ceylon, No 7 1 Government Prmter, Colombo, 40 pp 4 Jones, K A (1994) Use of baculoviruses for cotton pest control, m Insect Pests of Cotton (Matthews, G. A. and Tunstall, J P , eds.), CAB International, Wallmgford, UK, pp 477-504 5 Prior, C , Jollands, P., and Le Patourel, G (1988) Infecttvtty of 011 and water formulattons of Beauverla basslana (Deuteromycotma, Hyphomycetes) to the cocoa weevil pest Pantorhytes plutus (Coleoptera. Curculionidae) J Invertebrate Path01 52,66-72 6 Dent, D. R (1997) Integrated Pest Management and mtcrobtal insecttcides, m Mlcroblal Insecticides. Novelty or Necessity? British Crop Protection Council ProceedrngslMonograph Serves No 68, pp. 127-138 7. O’Connell, P. J. and Zoschke, A. (1996) Limitations to the development and commerctahsatton of mycoherbicides by industry. 2nd International Weed Control Congress. 6. ! Cooenhaeen. I “1“ DD. 1189-l 195
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8 Burges, D H. (ed ) (1997) Formulatton of Mcrobtal Btopestuxdes, Benefictal Micro-Organtsms and Nematodes. Chapman and Hall, London, m press. 9 Anderson, R M and May, R. M. (198 1) The population dynamics of microparasttes and then Invertebrate hosts Phil. Transact Roy Sot B 291,45 l-524. 10 Thomas, M B., Wood, S. N., and Lomer, C J (1995) Btologtcal control of locusts and grasshoppers using a fungal pathogen: the Importance of secondary cyclmg Proc Roy Sot Lond B 259,265-270. 11 Hails, R S (1997) The ecology of baculoviruses towards the destgn of viral pest control strategies, m Mzcrobtal Insecticides Novelty or Necesstty? Brttzsh Crop Protectton Councrl ProceedlngslMonograph Series No. 68, pp. 53-62 12 Munthah, D C and Scopes, N. E A (1982) A techmque for studymg the btologrcal effctency of small droplets of pestrcrde solutrons and a consrderatron of the lmphcatrons Pest Set 13,60-62. 13 Adams, A J , Chapple, A C., and Hall F. R. (1989) Droplet spectra for some agricultural fan nozzles, with respect to draft and brologtcal efficiency, m Pestztide Formulattons and Applicatton Systems 10th Volume ASTM STP 1078 (Bode, L. E., Hazen, J L., and Chasm, D. G., eds.), Amerrcan Society for Testmg and Materials, Philadelphta, pp 156-169 14 Bryant, J. E and Yendol, W. G. (1988) Evaluation of the influence of droplet size and densrty of Bacrllus thuringrensis against gypsy moth larvae (Lepidotera. Lymantriidae). J Econ Entomol. 81(l), 130-134 15. Maczuga, S. A. and Mrerzejewskr, K. J (1995) Droplet size and denstty effects of Bacillus thurmgiensrs kurstaki on gypsy moth (Lepldoptera: Lymantrndae) larvae J Econ Entomol 88(S), 1376-1379. 16. Ford, M G. and Salt, D W. (1987) The behaviour of pesttcrde deposrts and then transfer from plant to insect surfaces, m Crttical Reports on Applted Chemutry, vol 18: Pesttctdes on Plant Surfaces (Cottrel, H. J., ed.), Wiley & Sons, pp 268 1, 17. Hall, F. R. Chapple, A. C., Taylor, R. A. J., and Downer, R. A. (1994) Dose transfer of Bactllus thurrngtenszs from cabbage to the dramond back moth a graphical srmulator J Environ Set Hlth B29 (4), 661-678 18 Cory, J. S., Hnst, M. L., Williams, T., Hails, R S., Goulson, D., Green, B M , Caley, T. M., Possee, R. D., Cayley, P. J , and Bishop, D. H. L. (1994) Field trial of a genettcally improved baculovirus insecticide. Nature 37, 138-140 19 Hans, J. G. (1997) Microbial insectxides-an industry perspectrve, m Mcrobtal Insecttctdes Novelty or Necessity? Brtttsh Crop Protectton Counctl ProceedzngslMonograph Serves No 68,41-50. 20 Evans, H. F. (1994) Laboratory and field results with vn-us for the control of msects, m Comparing Glasshouse and Field Performance Ii (Hewttt, H. G., Casely, J., Copping, L. G., Grayson B. T., and Tyson, D , eds ), Brmsh Crop Protection Councrl Monograph No. 59, pp. 285-296. 21. Dulmage, H. T., Boenmg, 0. P., Rehnborg, C S , and Hansen, G. D. (197 1) A proposed standardized bioassay for formulations of Baczllus thurzngzenszs based on the international unit J Invertebrate Pathol. 18, 240-245.
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28 29.
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Bateman Bateman, R. P , Carey, M., Moore, D , and Prior, C (1993) The enhanced mfectivrty of Meturhzzzum jlavovznde m 011 formulations to desert locusts at low humtditres Annul Apple Bzol 122, 145-152 Robertson, J L and Pretsler, H K (1992) Pesticide Bioassay wzth Arthropods CRC, Boca Raton, FL. Nowierski, R M , Zeng, Z , Jaronskr, S , Delgado, F , and Swearmgen, W ( 1996) Analysis and Modelmg of time-dose-mortality of Melanoplus sanguznzpev, Locusta mrgratorza mlgratorloldes and Schzstocerca gregarca (Orthoptera Acrididae) from Beauvena, Metarhzzzum and Paecdomyces isolates from Madagascar J Invert Path01 67,236-252 (1996) Fungus stram selection for mycopestictdes. Semmar held at the Society of Invertebrate Pathology Meetmg, Cordoba, Spain, September, co-ordmated by C J Lomer Bradley, C. A , Black, W E , Kearns, R , and Wood, P (1992) Role of production technology m mycomsectrcide development, m Frontiers in Industrial Mycology (Leatham, G F , ed.), Chapman and Hall, London, UK, pp 16&173 Chapple, A C and Bateman, R P (1997) Application systems for mtcrobial pesttctdes necessity not novelty, m Mrcroblal Insectlcldes Novelty or Necessity? Bntuh Crop Protection Councd ProceedzngslMonograph Series No 68, pp 18 1-l 90 Helyer, N., Gill, G , and Bywater, A. (1992) Control of chrysanthemum pests with Vertrcillmm lecann. Phytoparasrtrca 20, 5-9 Sopp, P I , Grllespie, A T., and Palmer, A. (1990) Compartson of ultra-lowvolume electrostatic and high volume hydraulic apphcatron of Verticillium lecann for aphrd control on chrysanthemums. Crop Pro&&on 9, 177-l 84 Keller, S (1992) The Beauvena-Melolontha proJect. experiences with regard to locust and grasshopper control, m Biological Control of Locusts and Grasshoppers, (Lomer, C J and Prior, C., eds ), Pub1 CAB Intematronal, Wallingford, UK, pp 279286 Graham-Bryce, I J. (1977) Crop protectron. A consideration of the effectiveness and disadvantages of current methods and of the scope for improvement Phzlos Transact Roy Sot Lond B281, 163-179. Matthews, G A (1992) Pestzclde Applrcatlon Methods, 2nd ed Longman Scientific and Techmcal, Harlow, Essex, UK Reardon, R (1991) Aerial Spraymgfor Gypsy Moth Control A Handbook of Technology Urnted States Department of Agrtculture Forest Servtce, NA-TP-20, 167 pp Entwtstle, P F , Evans, H F , Cory, J. S , and Doyle, C (1990) Questions on the aerial application of mrcrobral pestrctdes to forests Proc Vth Znternatzonal Colloquium on Invertebrate Pathology, Adelaide, Austraha, 159-163 Bateman, R. P ( 1997) Methods of application of microbial pesticide formulations for the control of grasshoppers and locusts Memoirs Entomol Sot Cunadu 171,698 1 Matthews, G A (1997) Techmques to evaluate msecttcide efficacy, m Methods m Ecologzcal & Agrzcultural Entomology (Dent, D R and Walton, M P., eds ), CAB International, Wallmgford, UK, pp. 243-269 Parkm, C S and Merritt, C R (1988) The measurement and prediction of spray draft Aspects of Appl Blol 17,351-361
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38. Bateman, R P (1994) Performance of myco-insecttcides importance of formulation and controlled droplet apphcatton BCPC Monograph 59,275-284 39 Himel, C M. (1969) The optimum drop size for msecticlde spray droplets J Econ Entomol 62,919925. 40. Doble, S. J., Matthews, G. A., Rutherford, I., and Southcombe, E. S. E. (1985) A system for classrfymg hydraulic nozzles and other atomizers mto categories of spray quality. Proceedmgs BCPC Conference-Weeds, 1125-l 133 4 1 Johnstone, D. R. (1973) Insectlctde concentration for ultra-low volume crop spray application. Pest. Set 4,77-82. 42 Cooke, B K and Htslop, E C (1993) Spray tracmg techniques, m Applzcatzon Technology for Crop Protection (Matthews, G A and Hislop, E. C , eds.), CAB International, Wallingford, UK, pp 329-347 43 Bateman, R P (1993) Simple, standardised methods for recordmg droplet measurements and estlmatton of deposits from controlled droplet apphcattons Crop Protection 12,201-206 44. Jarrett, P. and Burges, H. D. (1982) Use of fogs to dissemmate pathogens. Proceedings Iiird Internattonal Colloquwm on Invertebrate Pathology, Brighton, UK, pp. 49-54 45. Falcon, L A. and Sorensen, A, A. (1976) Insect Pathogen-U 1 v combmation for crop pest control PANS 22 (3), 322-326. 46 Arnold, A C (1987) The dropsize of the spray from agricultural fan spray atomizers as determined by a Malvern and the Particle Measuring System (PMS) instrument. Atomtsatton Spray Technol 3, 155-167 47 Arnold, A C (1990) A comparative study of drop sizing equipment for agrtcultural fan-spray atomizers Aerosol Science Technol. 12 (2), 43 l-445. 48. Chapple, A C., Taylor, R. A. J., and Hall, F. R. (1995) The transformation of spatially determined drop stzes to then temporal equivalents for agricultural sprays. J Agrtcult Engineer Res. 60,49-56. 49. Chapple, A. C. (1996) Application of biological control agents. some theoretical considerattons of dispersal, m Proceedtngs of the 5th European Meettng of the Internattonal Organisatton of Btological Control, West and East Palearcttc Regions Mtcrobtal Control of Pests. Poznan, Poland, pp 24-28 50 Hall, F R , Chapple, A C , Downer, R. A, Kirchner, L. M., and Thacker, J R M. (1993) Pesticide application as affected by spray modtfiers Pesttctde Set 38, 123-133 5 1 Amsellem, Z , Sharon, A , Gressel, J , and Quimby, P C (1990) Complete abohtion of high inoculum threshold of two mycoherblctdes (Alternarza casszae and A crassa) when applied m invert emulsion. Phytopathology 80,925-929 52 Lawrie, J , Greaves, M P , Down, V M , and Chassot, A. (1997) Some effects of spray droplet size on distribution, germmatlon of and mfection by mycoherbictde spores Aspects Appl B1o1 48, 175-182 53. Jones, K A and Burges, H. D. (1998) Prmctples of formulation, m Formulatzon of Mtcrobial Biopesttcides, Beneficial Mtco-Organums and Nematodes (Burges, H D , ed ), Chapman & Hall, London, UK, in press
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54 Brutish Crop Protection Council (BCPC) (1994) Comparzng Laboratory and F&d Pestzclde Performance 0 BCPC Monograph No 59 (Hewitt, H. G., Casely, J , Copping, L. G., Grayson, B. T., and Tyson, D., eds.), 323 pp 55 Qmmby, P C and Boyette, C. D (1987) Productron and appltcatlon of biocontrol agents, m Methods ofApplymg Herbzczdes (McWhorter, C. G and Gebhardt, M R , eds ), Monograph No 4, Weed Society of America, Champagne, IL, 358 pp 56 Bateman, R. P., Godonou, I , Kpmdu, D., Lomer, C J , and Paralso, A (1992) Development of a novel “field bioassay” technique for assessing mycopestlcide ULV formulations, m Brologzcul Control ofLocusts and Grasshoppers (Lomer, C J and Prior, C , eds ), Pub1 CAB International, Wallmgford, UK, pp 255-262 57 Bateman, R P, Douro-Kpmdou, 0 K , Kooyman, C , Lomer, C , and Ouambama, Z. (1998) Some observations on the dose transfer of mycomsecttcrde sprays to desert locusts Crop Protectzon, 17, 151-158. 58. Prckm, S R (198 1) in Manualfor TestzngInsectzczdeson Rice (Hemrichs, E. A , Chelhah, S., Valencia, S. L., Arceo, M. B., Fabellar, L T., Aquino, 0. B., and Pickin, S R , eds ), IRRI, Los Banos, Philippines, pp 52-66 59 Bateman, R P , Price, R E , Muller, E J., and Brown, H D (1994) Controllmg brown locust hopper bands m South Afrtca with a myco-msecticide spray. Proceedings of the Brighton Crop Protectton Conference-Pests and Diseases,
60 61
62
63.
64
65 66 67. 68
November 1994, pp 60996 16 Stamland, L N. (1959) Fluorescent tracer techniques for the study of spray and dust deposits J Agrzcult Engtneer Res 4,42-81 Shapiro, M and Robertson, J L (1992) Enhancement of gypsy moth (Lepldoptera. Lymantrndae) baculovrrus activity by optical brighteners J Econ Entomol 85(4), 1120-l 124. Jimmez, J and Gillespie, A T (1990) Use of the optical brightener Tmopal BOPT for the rapid determmatton of conidtal viabilities in entomophagous deuteromycetes Mycological Res 94,27!%-283 Thomas, M B , Wood, S. N., Langewald, J , and Lomer, C J (1997) Persistence of Metarhizzum j7avovzrzde and consequences for brological control of locusts and grasshoppers Pestlclde SCI 49,47-55 Price, R E , Bateman, R P , Brown, H D , Butler, E T , and Muller, E J (1997) Aerial spray trials agamst brown locust (Locustuna pardulrna, Walker) nymphs in South Africa using oil-based formulations of Metarhlzlum jlavovzrzde Crop Protect 16,34 l-35 1 Food and Agriculture Organizatron of the United Nations (199 1) Guide-lines for pesticide trials on grasshoppers FAO Booklet, comptled by Dobson, H., Rome, 16 pp Kaplan, E L and Meter, P. (1958) Nonparametrtc estimation from mcomplete observations J Am Statzst Assoc 53,457-481 Henderson, C. F. and Tilton, E. W (1955) Tests with acartcides agamst the brown wheat mite. J Econ Entomol 48, 157-161 Perry, J N (1997) Statistical aspects of field experiments, m Methods zn Ecologzcal & Agricultural Entomology (Dent, D R and Walton, M P , eds ), CAB International, Wallmgford, UK, pp. 171-20 1.
28 Analysis, Monitoring, and Some Regulatory
Implications
Jack R. Plimmer 1. Introduction Pesticide analysis is generally conducted with one of two objectives: product analysis to determine *the quantity of active ingredient in a manufactured product or formulation, or resrdue analysis to determine amounts of material resulting from application or use. In addition, the analysis may mclude elucrdation of the composition and confirmation of the identity of the active mgredient, or its metabolites or alteration products. This summary of methods of characterizatton, analysis, and identification of biopesticides is based on examples that range in composition from homogeneous macromolecules to whole organisms. Such diversity demands a variety of analytical approaches, and presents a challenge to the ingenuity of the analyst, often requiring the use of sophisticated mstrumentation. Some regulatory topics have also been included in the discussion, because requirements for analytical data are specttied by regulatory authorities when new materials are to be used in pest management. Such analytical data is essential for risk assessmentand ensurmg that adequate safeguards to protect human health and the environment are mcorporated m applications of new technology.
1.1. Regulatory Issues The use of a material as a pesticide entails compliance with the requirements of the Federal Insecticide, Fungicide, and Rodenticide Act (FIFRA; 2) and the Food Quality Protection Act (FQPA; 2). The risk-assessment process undertaken by the U.S. Environmental Protection Agency (EPA) as part of its decision to register a pestictde relies on data obtained by measurements of residues in commodrties, environmental samples, crops, or other substratesthat From Methods IR Bofechnology, vol 5 Bopestm%s Use and De//very Edited by F R Hall and J J. Menn 0 Humana Press Inc , Totowa, NJ
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may contam residues. The term “residues” applies not only to the parent pesticide, but also to toxicologically significant metabolites, or other products that might arise by alteration of the parent molecule. The regulations provide substantial discussion of the data required by the EPA for the risk assessmentand approval process. Not least important IS the necessity to conduct studies to obtain residue data withm the legal framework of Good Laboratory Practices (3). To accommodate classes of pesticides that differed substanttally m their mode of action from conventional chemical pesticides, the EPA prepared new gmdelmes to cover the so-called “brorational pesticides” (Subpart M; 4) From the regulatory standpomt, this group of pesticidal agents was divided into biochemicals and microbials. The term “microbials” embraces both naturally occurrmg or genetically engmeered orgamsms. The guidelmes were updated m February, 1996 (5). The purpose of these new guidelines was to harmomze testing requirements described m earlier FIFRA, Toxic SubstancesControl Act (TSCA), and Organization for Economic Cooperation and Development (OECD) publications. Not only did the new classes of pesticides differ substantially m mode of actron, but they were frequently not susceptible to the methods of analysis generally applicable to conventional chemical pesttcides and their residues. Brological control agents other than some mtcroorganisms were exempted from the requirements of FIFRA (6). However, the proposal by EPA to regulate some transgenic plants as “plant pesttcides,” under FIFRA has generated controversy, because of the potentially heavy burden of additional data that might be required for approval (7), Because there is limited experience of the ecological effects of introducing organisms, or self-rephcatmg agents contammg genetic mformation, into the environment, their potential for adverse effects has drawn regulatory attention. Risks associated with the release of genetically engineered microorganisms (GEMS) may be linked to potential for pathogemcity, and for colomzmg the environment and drsplacmg existing species @I. Conventional methods of residue chemistry may often be applicable to the analysis of biochemicals (i.e., identification, detection, and quantttation). This applies to well-defined molecular species,generally synthetic products, used as pest-control agents. 1.2. Regulation of Transgenic Plants Incorporation of genes that confer resistance to herbicides mto crop plants may extend the range of pesticides currently m use, and thus prolong the economic life of herbicides that have a demonstrated history of safe and effective use. Monsanto (St. Louis, MO) has applied this approach to soybeans and cotton, and experiments are being conducted on glyphosate-tolerant canola in Canada.
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EPA is now registering genetically engineered plants capable of expressmg proteins similar to those contained m Bacillus thurzngzenszs(Bt). These are described as “plant pesticides” and are registered under FIFRA. Implicit m such approval is the requirement to analyze the products of gene expression, and monitor the environmental impact of the engineered organism. Recent patents have been issued for techniques to modify genes from Bt to optimize insecticidal protein expression m plants. Several major crop plants (including corn, cotton, canola, potatoes, and tomatoes) have been transformed with synthetic Bt genes (9). EPA has approved the sale of hybrid seed corn that incorporates B&based resistance to European corn borer (JO). A plant pesticide, targeting the European corn borer, was recently registered. It is a field corn containing the gene, pCIB443 1, responsible for the productton of the S-endotoxin protein, Bt CryIA(b), an Insect toxin. The gene produces a truncated version of the naturally occurring insecticide. In May 1995, Monsanto’s request for the first full registration of a plant pesticide was approved by the EPA. This is a Colorado-beetle-resistant potato carrying the genettc maternal required for production of Bt CryIII(a), a &endotoxin. 1.3. Nocontrol Agents and Genera/ Analytical Approaches Biocontrol agents include a variety of organisms, and the most important class of these is Bt Berliner, which also provides a source of genettc material for many products now in use. Safety evaluations of Bt following different expoSure routes showed that these entomopathogens were virtually nontoxic to mammals, provided that high dose levels were not used (11). Currently, assessmentsof acute toxicity/pathogenicity utilize colony forming units (CFU) for assessmentof exposure. A CFU ts defined as a single, viable propagule that produces a single colony (a population of cells visible to the naked eye). The analysis of Bt preparations and some of the regulatory implications are discussed later (see Subheading 5.). The analysis of microbiological pest control agents (MPCAs) 1s discussed by EPA in, the Subdivision M guidelines. Analytical methods are required for data collecTion to support tolerances, and for enforcement of the regulations (12). A monitormg method is required for all MCPAs that are exempted from the requireG>entsof tolerance. Conventional analytical procedures, such as gas chromatography (GC), mass spectrometry-(MS), or high-pressure liquid chromatography (HPLC) (or combinations thereof), are typically used for many biopesttcides. If the MPCA per se, a mutant, OF viable recipient of MCPA genetic material is a residue of toxicological concern, then various immunological methods (such as enzymelinked immunosorbent assay and dot-immunoassay) or molecular probe methods (such as dot hybridization, Southern hybridization procedure, or
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restriction endonuclease mapping) may be used for identification and/or quantitatron. Since the above methods do not necessarily determine vtable MCPAs, culturing of trssues (maceration followed by dilution plating) or infectivity assayswill frequently be necessary.Methods useful for detectton of microorganisms are discussed m Subheading 4. (13).
2. Analysis 2.1. Biochemicals and Natural Products EPA guidelmes describe four major classes of biochemical agents: semiochemicals, hormones, natural plant regulators, and enzymes. Current mstrumentation combines MS, nuclear magnetic resonance spectrometry (NMR), infrared (IR), ultravrolet (UV) spectroscopy, and X-ray crystallography wrth powerful separation techntques, such as high-pressure hquid chromatography (HPLC) and capillary electrophoresis (CE), and incorporates the capabilittes of computer-based data processing to rapidly acquire information concerning not only details of primary structures of complex natural products, but also their spatial conformatron and interactions with macromolecules, Natural products, such as pyrethrotds, rotenords, nicotine, and so on, have long been in use as pesticides, or have served as models for synthetic modifkation. The realization that the genetic potential of a plant (or other organism) may be transferred to an appropriate host and utihzed to generate commercially valuable, genetically engineered products has revitalized the quest for natural sources of biologrcal acttvity, and strmulated the Investigation of natural products and the molecular biology mvolved in thetr biosynthesis. The incorporation of genes capable of expressing toxins in baculoviruses has generated interest in natural toxins such as sprder and scorpton venoms. For example, an engineered form of the baculovn-us, Autographa calzjbmzca Speyer NPV, which expresses a scorpion toxin, was tested against the cabbage looper, and other genetic modifications are in early testing stages. New fermentanon products include Naturalyte, a spmoside derived from soilborne actmomycetes, which is produced by DowElanco (now Dow Agrochemrcals, Indianapolis, IN) at a fermentation facility. The material 1sacttve against lepidopteran pests (tobacco budworm, cotton bollworm), and rt also shows activity against termites, Colorado beetle, diptera, and other pests (14). Thts was tested on cotton m 1995-1996, and subsequently on vegetables, trees, and vines. The spinosads are a novel class of macrocyclic lactones produced by the soti actmomycete, Saccharupolyspora spuzosa (IS). The two most active insecticidal factors in the mixture are spinosads A and D. Immunoassay techniques have been developed, and are available for analysis. However, at the present ttme, EPA appears strongly committed to a preference for confirmation of residue analysesby conventional methodology.
Analysis of Hopesticides
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Products of microbial fermentation are often complex m structure, but analysis by HPLC may present dlfficultles when conventional UV detectors are used, when chromophores (aromatic or conjugated systems) are absent. In such a case, pre- or postcolumn derlvatization with a chromogenic or fluorogemc reagent may be useful to enhance the level of detection above that of the refractive index detector system. A typical example of methodology 1sthe method of analysis of gentamicin, an aminoglycoside antibiotic, which may be used as a pesticide for control of plant disease in fi-mt crops. The product is a complex mixture containing three major products and several minor components Gentamycin is formed by the attachment of two ammosugar residues (garosamine and pupurosamine) to 2-deoxystreptamine (an aminocyclitol) through glycosidlc lmkages. Several methods of analysis have been recommended for pharmaceutical preparations, including MS. A recent method employs HPLC separation, combined wtth derivatlzation with o-phthalaldehyde, and such methods can be used for determination of residues on crops (16). Derivatlzation with N-methylimidazole IS used to generate a fluorescent derivative of moxidectin (I 7), a macrocyclic derivative of nemadectin, produced by Streptom-yes sp. The derivative IS analyzed by HPLC, and the method has been used to study plasma levels. Neem extracts (Azadirachta indica A. Juss. [syn. Melra azadirachta L.]), like many crude natural-product extracts, contain a variety of compounds. The extracts of the seedspossessa wide spectrum of biological activity, Including pesticidal activities. The major insecticidally active component of neem extracts 1sazadirachtin (18). Generally, the biological activity of neem 011sIS highly correlated with their azadirachtm content (19), which may be determined by HPLC (ZO), using an HPLC spherisorb (Phase Separations, Franklin, MA) column with acetomtnle/water gradient and a variable wavelength detector at 2 10 nm. Neem extracts generally have low oral toxicity to laboratory mammals, but recently (21) it was shown that a component of the extract of seeds, nimbolide, IS cytotoxlc. Nimbohde could be isolated from neem extracts by chromatographic fractlonatlon on silica columns, followed by TLC on silica gel, and final purification by reversed-phase HPLC on a Merck 1OORP-18 column, and detection with a photodiode-array detector at 220 nm. 2.2. Analysis of Pheromones and Other Semiochemicals Semiochemicals are defined as naturally occurring or synthetic substances, or mixtures of substances,emitted by one species, which modify the behavior of receptor orgamsms of other individuals of like or different species (4). Of these, insect sex attractant pheromones are used in pest management for several purposes: in insect traps for momtoring or survey purposes; in a mass trapping program to reduce insect populations; in combination with msectl-
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ctdes to attract insects to an area treated with insecticides, or to a device contaming insecticide; and to permeate the an and suppress insect populatton by dtsruptmg mating or aggregation (in this mstance,pheromones may be regarded as btopesticides). The above usesof pheromonesrequtreextremely smallamountsof matertaland the targetsare quite specific.Many semtochemicalsare tdenttcalto, or closely resemble, other naturally occurring matenalstn then chemicalcomposttton,are generally readily degradedtn the environment, and show low toxic@ to nontargetspecies. From a regulatory standpomt, lepidopteran pheromones have recetved special constderatton, and there 1sgrowing expertence of then practical appltcatton (22). In establishing an exemption from requirement of a food tolerance for residues of certam leptdopteran pheromones (independent of formulation or mode of application), m cases m which annual appltcatton was ltmlted to 150 g active ingredient per acre for pest control, or in all raw agrtcultural communities, the EPA took a number of factors into account (23). Lepidopteran pheromones were defined as “naturally occurring compounds (or identical or substantially similar synthetic compound), designated by the unbranched altphattcs (carbon chain between 9 and 18 carbons) ending m an alcohol, acetate, or aldehyde functional group and containing up to 3 double bonds rn the altphattc backbone” (23). This defmttton included the malortty of leptdopteran pheromones, and the EPA considered that, “although other chemical structures have been demonstrated to be leptdopteran pheromones or pheromones of other arthropods, there 1s insufficient toxicity data and exposure mformatton to merit their exemption from tolerances” (23). The decision was made on the basis of the absence of significant toxtctty associated with the structural features of leptdopteran pheromones (compounds from six to 16 carbon unbranched alcohols, acetates, and aldehydes). In addtnon, subchronic toxicity of an tsomeric mixture of tridecenyl acetates mdtcated no significant signs of toxicity other than those associated wtth exposure to a hydrocarbon. Published studies indicate no stgmficant health effects from subchronic exposures to this group of chemicals. Studies of volatihzatton from a mtcrocapsule show that about 70% of the pheromone remains after 30 d. These results indicate that a considerable portion of the total pheromone 1snot capable of being released, which suggests a potential for residues to occur m the absence of any biologtcal or envtronmental factors. However, in a submitted field study, residue analyses from fieldtreated plants indicated no stgmticant amounts of pheromone could be detected on the fruit. Detectable residues of tomato pmworm pheromone on unwashed fruit ranged from 21 to 72 ppb on the day of apphcatton, decreasedto 0.948 ppb on d 15, and 0 29-l .2 ppb on d 30. Washing the fruit brought all residues below the level of detection.
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A field study was conducted and residues were determmed on apples that had received treatment wrth pheromones(52 g/ha of dodecenyl alcohol and 10 gha of tetradecenyl alcohol) (24). Application, weathering, and other envuonmental degradation processescauseda reduction in the active ingredient to a level that approached the system lrmrt of detection in the expected 3-wk hfetlme of the raw agricultural product. The literature contains many descriptions of techniques for isolation and structural elucidation of pheromones (for example, Ostrovsky and Bestmann (251 provide a useful summary). Typical approach to the isolation and Identification of a lepidopteran pheromone mvolves extraction of active mgredients, which may be achreved by analystsof solvent extracts of the sex glands, or by rinsing the gland region with a solvent. The latter method affords a cleaner extract Alternattvely, collection of the volattles secreted by the insect to elicit mating responses provides material that corresponds more closely to the composition of the pheromone blend. For further exammation, extracts may be purified by gel permeation chromatography, column chromatography, HPLC, thin-layer chromatography (TLC), or gas chromatography (GC). Identification of pheromones 1sfrequently based on spectroscoptcdata. UV, IR, and NMR (particularly FTIR and FTNMR) may provide some useful information, but MS and, most frequently, GUMS IS the method of choice. It may not be a simple matter to elucidate the geometry and posmon of the double bonds in long-chain aliphatic compounds, but reactions, such as ozonolysis, may be conducted on nanogram samples and yield fission or other products that can be characterized.Addtttonal information may be obtained by using biological detectors that respond to very specific stirnull. The major hurdle m determining pheromone structures 1susually that of accumulatmg sufficient material for investigation. Smce lepidopteran pheromones may be a blend of two or more components, tt is important to elucidate the quantitative and qualitative composition of the blend that will elicit the desired response. Trace components play a significant role m eliciting behavioral responses (26). This influences the design of effective pheromone dispensers, which must be constructed to emu vapor corresponding in composition to the natural stimulus. 3. Analysis of Biological Macromolecules Biopesttcide mvestrgattons may call for the elucidatton of structure of macromolecules important to molecular biology that are involved m the processof gene expression: nucleotides, proteins, and peptides. Attention has also focused on other macromolecules, such as the carbohydrates, n-rthen role as bioregulators. There has been substantial recent progress m adapting mass spectrometry to the investigation of macromolecular structure. It IS a preferred technique, m
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combmation with ammo acid analysis and HPLC, for the characterrzatron of peptides. Interfaces between MS and liquid chromatography systemshave been greatly improved. Electrospray ionization and matrix-assisted, laser-desorption/romzation, time-of-flight (MALDI-TOF) mass spectrometry permits determination of protein mass in excess of 100 kDa, utilizing quantities of material, sometimes as low as subprcomoles. Reducttons m cost of such mstrumentation, and improved ease of its operation, have brought the techniques within economrc reach of many laboratories, and closer to routme operation. There are limtts to the applications of MALDI, but it IS currently an extremely active field of investigation. In the MALDI-TOF technique, the analyte is desorbed from a crystallme lattice by a laser beam, and Ions are accelerated through a short distance by a high voltage (up to 30,000 V) Ions are accelerated down a linear fbght tube and their time to arrive at the detector is determined. Their mass IS a function of the square of the flight time and may be measured very accurately (better than 20 ppm at mass 1200), rf internal standards are included Very large charge-to-mass ratios can be measured by this method, and singly charged molecules up to 200 kDa can be analyzed. However, the method 1snot readily applicable to molecules of C900 amu. TOF analyzers are very sensitive and requue 4 to very few prcomoles of material for analysis.However, a relatively high sample concentration (1O-20 ClM) may be necessary.The efficiency of desorptron and detection of an ion is dependent on amino acid composition. Basic residues particularly affect peak heights. Patterson and Aebersold (27) have reviewed application of gel electrophoresis coupled with mass spectrometry for protein identification. A combination of Edman sequencing and MALDI-TOF MS provides a powerful approach to identification of peptides and proteins. Typical procedures mvolve the rsolatton of protems and peptides by gel electrophoresis, and hydrolysis by dtgestron with trypsin or a proteinase. Peptides are separated by HPLC and masses are determined. MALDI-TOF technique is widely used for studies of whole proteins in many laboratories. Fast atom bombardment (FAB) and MALDI techniques are applicable to protem mapping, and may be used to mvestigate protem-protein mteraction and tertiary structure 3.1. Characferizafion of Macromolecules Caprllary zone electrophoresis (CZE) is a method of choice for analysis of polypeptide samples. A comparatrve study of the method (on Bio-Rad-HPE m 20 cm x 25 mm capillaries) showed that tts performance was superior to TLC and paper electrophoresls, and equivalent to that of reversed-phase HPLC chromatography (29). Other separation techniques include electrophoresrs on sodium dodecyl sulfate-polyacrylamide gel electrophorests (SDS-PAGE), size-
Analysis
of Biopesticides
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exclusion chromatography (SEC), reversed-phase HPLC, and centrifugatton. Capillary electrophoresis output combined with electrospray mass spectrometer (CE + ES). ES-MS and MALDI-MS are applicable to the determmation of accurate mol wt and purity of proteins. 3.2. Sequencing Peptide primary structures may be investigated using tandem mass spectrometry (MS/MS). Primary structure may be determmed at the pmol level, and peptides obtained from purified proteins may be sequenced by MS/MS techniques. However, it has been stated that sequencing by MS/MS is not yet a routine technique, and may not be applicable to determination of the complete sequence of every peptide. Interpretation programs may not yield single unambiguous results, and it does not replace Edman degradation or make it obsolete. MS/MS may be useful for primary structure determmation at the pmol level, and it has been reported that collisron-induced dissociation (CID) processes may be useful for resolvmg details of sequencing. A modified detector, which rapidly records the CID spectrum, increases the sensmvtty of the technique, which is also enhanced by elimination of transfer losses,if the digestion sample is directly introduced from a packed-capillary HPLC column interfaced with the first mass spectrometer (30). Automated sequencersare used to analyze small quantities of proteins or DNA samples.The structure of ohgo- and polynucleotides may be investigated by mass spectrometry, but they do not give good results under conditions normally employed for peptides and proteins. Desalting of DNA is important to avoid the presence of sodium and potassium ions, which bmd to DNA and gave rise to complex spectra. A variety of matrices have been evaluated for oligonucleotide mass spectrometry, and 6-aza-2-thiothymine, dissolved m 50% acetomtrile wrth 20 mMdrammonium citrate, appears to work well for modified oligonucleotides (32). DNA fragments of up to 426 base pairs have been analyzed, and the ultimate goal of such studies IS the potential application to DNA sequencmg. MS/ MS cannot be used for sequencing of DNA. A current limitmg factor in the utility of mass spectrometric techniques for DNA sequencing is the poor efficiency of electron multiplier detectors for detecting large tons; research is being conducted to develop detectors of Improved efficiency (31). Laser vaporization and FTMS are under investigation as a technique for DNA sequencing. Traditional techniques of structural investigations of carbohydrates involved lengthy derivatizatton procedures of derivatization and identification of individual mono- or oligosaccharide units obtained on hydrolysis or degradation. This field has been revolutionized by the applications of GUMS, FT NMR, and other newer instrumental techniques, such as FAB-MS of derivatized carbohydrates, which may be useful for sequencing.
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4. Microorganisms
4.1. Genetically Engineered Microorganisms As gene transfer techniques have rapidly developed, there has been a corresponding growth in experimental and commercial production of genetically englneered microorganisms (GEMS) and plants. The fate of GEMS hasbeen amatter of concern, stnce the technology has become widespread. Although techniques of gene alteration may be applied to plants, animals, or mlcroorganlsms, technical dlfficultles associatedwith containment and monitoring the consequencesof their releaseshave become more complex. Imtlally, there were few releasesof GEMS into the environment, and they received intensive scrutiny. Much debate has taken place over the potential consequencesof releasing mlcroorgamsms. Few genes are added or deleted from the parent strain in the construction of a GEM, and the GEM may be expected to behave in the same way as the parent, unless the ecological properties are modrfied Major concerns over the release of microorganisms are that the organisms might be pathogenic or they might displace species that already exist in the environment. The need to monitor GEMS has been emphasized (8). Their ldentlficatlon m the natural environment presents problems of extraction and recognition. Assessment of the survival and persistence of GEMS m the sol1 environment has been dlscussed by Edwards (32). An accumulated decade of experience of the consequences of release of engineered organisms into the environment suggests that there do not appear to be greater risks associated wrth engineered organisms than with other organisms, either naturally occurring or genetically modified by mutation processes (chemical or irradiation), and so on. As a safeguard, a risk analysis must be built mto the process of regulatory approval, and this requires that procedures be available for detecting and monitoring GEMS in the environment
4.2. Monitoring Methodologies 4.2. I. Reporter Genes Reporter genes, or screenable markers, may be useful in ldentlfymg genetltally engineered cells, and such genesare routinely incorporated mto transgemc plants, animals, and microorganisms. Antibiotic resistance markers have frequently been used, because they allow the selection of recombinant organisms by plating onto a selective medium containing the antibiotic on which only resistant organisms will grow. An lmportant crlterlon in the selection of such a marker sequence is that it confers reslstance only to antibiotics of limited pharmaceutical use. Reporter genes most commonly used in detection and momtormg have been the GUS (P-glucuromdase: u&A) and 1acZ (P-galactosldase) genes from
Analysis of Biopestlcides
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Escherichia colz, and the luciferase gene from firefly or bacteria that encodes biolummescence. The 1acZ system encodes /3-galactosidase production, and has been used in tracking engineered Pseudomonas strains in sods Strains incorporatmg this gene can be recognized by a characteristic blue color produced by incubation with a specific substrate. Other genes that encode for chromogenic reaction potential (such as production of catechol2,3-oxgenase) have also been used. Potential usesand improvements m the utility of the Green Fluorescent Protem gene have been discussed (33). Cells transformed by this reporter gene, which is obtained from the jellyfish, show bright fluorescence under UV illummation. It can be detected by noninvasive techniques, and has potential application for monitoring organisms released into the environment Genetic modifications of maize containing a gene expressing insect resistance have been developed. A marker gene for antibiotic resistance was also mcorporated in some of these plants, but there is a concern that release of such an antibiotic resistance gene m the environment might be associated with the risk of increased resistance of bacteria to antibiotic drugs. The presence of such a gene seems likely to delay regulatory approval in Europe, and other varieties of maize, which do not mcorporate the antibiotic resistance gene, are being developed. 4.2.2. Techmques for Recognition of Organisms The three major categories of detection methods mclude culture and metabolic techniques, genetic techniques, and mnnunological techniques (13). 4.2.3. Culture of Organisms Traditional techniques of culture and metabolic techniques will be useful for confirmatory procedures. Conventronal cultural methods can be used with selective or nonselective media, and require an moculant contaming at least 100 bacteria/ml. The method of counting colonies on agar plates has been used extensively, and the data are subject to statistical analysis The orgamsm must be culturable, and, in the case of an engineered organism, an inserted marker must be present, which is stable, and without influence on metaboltsm or ultimate survival of the organism. Accepted FDA methods require enrichment m broth, followed by enrichment m agar, and culture on nonselecttve agar. This is a time-consuming procedure. Since this method provides amplification, it merits more research. If the organism is not culturable, staining may afford an alternative. Fluorescent antibodies may also be added to the plate. The sample medium may present a source of problems. The PCR technique requires 1O4organrsms/mL, and an additional hmttation is that polymerase may
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Pllmmer
be mhtbited by media. Immunoassay requires about lo4 orgamsms/mL. The generation of fluorescent bacteria may be very useful for microscopy of organisms that are viable, but nonculturable. 4.2.4. Whole Cell Analysis Helm et al. (34) have described a computer-aided procedure for identifying bacteria based on FT-IR data. They utilized a library based on 97 strains, and indicated the need for suitable databases.Pyrolysis under controlled condmons 1scapable of providing much data, but tts interpretation will depend on patternrecognmon techniques and the avatlabtlity of adequate reference libraries (35”. 4.2.5. Metabolism Analysis of spent media, or characteristic products of bacterial metabolism, will provide information that can be used to classify or identify bacteria, Data may be obtained by GLC or HPLC analysis, and, additionally, these techmques may be coupled with mass spectrometric analysts. Much mformatton is obtained that IS characteristic of the organism, but recognmon and identtficatton depends on pattern recognmon, and matching the patterns with those m existing reference databases. Profilmg of lipids has been investigated as a recognition technique: Profiles of triglycerides, wax esters, fatty acids, or phospholiptd ester-lmked fatty acids may be useful for characterization or recognition of microorganisms (36,37). Fatty acid profiles have been used to characterize Bt strains from ancient samples of ambers. Cloned colonies were grown under standardized conditions, the cell mass was saponified, and free acids were methylated and analyzed by GLC The dtstrtbutton of fatty acids was subjected to multivariate analysis to assessthe distribution of fatty acid variation m populations of similar bacteria (38). Other techmques that have been employed Include macromolecular profiles, DNA fingerprinting, electrophoretic polymorphism of enzymes or total protems DNA fingerprinting, and electrophorettc polymorphism of enzymes or total proteins (39). 4.2.6. Immunological
Methods
Immunologtcal procedures, such as the use of fluorescent-labeled, monoclonal anttbodtes, may complement macroscopic methods of identification. Immunoassays are rapid, convenient, and adaptable to field or laboratory sttuattons They reqmre antibodies specific for the gene product or microorganism of interest. A wide variety of antibodies is readily available commercially, and are in routme use for diagnosis of pathogens, mycotoxms, and so on. Detection techniques using nnrnunologtcal approaches are epifluorescent microscopy (requires observation of about 50 fields/sample), dot-blot meth-
Analysis of Biopesticdes
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ods, and agglutination (requires antiserum and 30-60 s reactton time, and can be used at log organisms/ml level [coagglutination may increase sensitivity to lo6 orgamsms/mL]). A species-specific antiserum and a fluorescent dye are required, and the specimen is viewed with an epifluorescent microscope, which reveals the cell as a fluorescent green band beneath the cell wall. Several formats may be used for immunoassays. In the simplest form, polyclonal antibodies are bound to a solid surface. A solution contammg the target analyte (antigen) is added, together with a polyclonal antibody linked to an enzyme. If an antigen is present, this binds to the polyclonal antibody at the solid surface, and the enzyme-linked polyclonal antibody also binds to antigen. If enzyme IS present, the addition of an appropriate substrate generates a colored product that can be determined spectrophotometrically. In a variatton of this method, the antigen is bound to the well of a microttter plate. A specific polyclonal antibody is added. This binds to the antigen, and the antigen-specific antibody binding is detected by the addition of another antibody conjugated with an enzyme. A chromogenic substrate is added to the wells, and the presence of antigen-antibody-enzyme complex is determined colonmetrically. Immunofluorescence techniques employ specific polyclonal antibodies that will bind to a spot of the antigen bound to a glass slide. The binding site is detected by adding an antibody conjugate labeled with a fluorescent reagent (fluorescein isothiocyanate), and viewing the plate under UV light For the dot-binding assay,antigen is bound directly to a nitrocellulose membrane, and sites that are unbound are covered with a blocker (buffer-milk powder). Spectfic polyclonal antibodies are added and bind to the antigen. The specific antibody bound to the antigen is detected by addition of a proteinenzyme conjugate, and an appropriate enzyme substrate is used to visualize the binding site. Organisms cultured in media may be concentrated by immunocapture, by adding magnetic beads coated with antibody. Beads are then added to fresh media as an inoculant. The advantages of tmmunologtcal methods are: they can detect specific bacteria within highly mixed populations; they detect total cells; sample preparation may be simpler; and nnmunological methods are less expensive than DNA-based techniques. 4.2.7. Genetic Techniques Immunological and genetic techniques are applicable to samples of large size. Genetic techmques rely on the specificity of gene probes, which detect sequencesof nucleic acids. Gene probes allow tracking of the genome, and this method can be used without culturing and without the necessity of having a specific selectable marker. Gene probes have the advantage that a gene can be detected, even if it has been transferred to another organism.
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Colony hybrrdization is the simplest molecular approach for detection of GEMS, which can be combined with conventional environmental microbiological sampling and analysis; its advantages have been summarized (40). Bacteria are grown on solidified agar media to form colonies. Specific-target nucleic acid sequences are then detected by gene probes and nucleic acid hybridization. After transfer to hybridrzation filters, colomes are lysed and hybridization is conducted. PCR-based technologies appear promising for wild-type and recombinant viruses. Complementarity is the term given to the binding of two macromolecules on the basis of sequence-specific or steric-molecular recognition. It may be used to describe the bmdmg of the two strands of the double helix of DNA, or the binding of an antibody to a protein by specific steric recognition. On this basis, a probe molecule can bmd with a target molecule to form a hybrid. If the probe is radioactively labeled, hybridization can be used to obtain information about the target molecule. The hybridization of two complementary nucleic acid sequencesprovides a specific technique for recognmon of particular sequences. This IS useful for detection of organisms that cannot be cultured, or do not have a detectable marker gene (such as resistance to antibiotics) It also has the advantage that a gene can be tracked, whether it is expressed or transferred to another organism. The technique is capable of higher sensitivity than can be achieved by other methods Three classesof genes have been used as probes (23). These are probes that target ribosomal RNA, randomly cloned sequencesof DNA unique to the organism of interest, or the engineered sequence. For a GEM, the sequenceof interest is already available, and this often determines the most convenient choice. Dot-blot, slot-blot, or Southern-blot techniques may be used for detection. The target organism usually contains many nucleic-acid sequences present m genes, mRNA, and so on. In the Southern blot procedure, the DNA is cut with restriction enzymes.The double-stranded DNA fragments have an extended-rod conformation that can be separated by electrophoresis on a solid gel support, on a mol wt basis. Bands are stained with a suitable stammg agent (such as ethldmm bromide for nucleic acids), and mol wt are estimated by comparison with standards. The DNA bands to be examined must be adsorbed on a solid support (usually nitrocellulose paper) for the hybridrzation process (“blottmg”). DNA IS transferred to the support, and, since it is double-stranded, it must be converted to the single-stranded form before hybridrzation (“denaturation”); conversion is accomplished by conductmg the transfer m a strongly alkaline buffer. The labeled probe (DNA labeled with 32P)is added to the support (after blocking sites on the filter that might adsorb the probe) and nonhybridized DNA is washed away. The amount of radroactrvity remaining is determined by autoradiography or LSC. 1O4organisms could be detected m Southern blots (41).
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Probes may be prepared from plasmids contammg the gene of interest. Fragments obtained by treatment of the plasmrd with restriction enzymes are separated by gel electrophorests. The polymerase chain reaction (PCR) technique allows the target sequence to be magnified by adding a primer unique to the target, followed by cycles of synthesis of complementary strands and denaturatton. PCR allows gene sequences to replicated m vttro and amphfied exponenttally, thus enhancing the probabthty that specrfic sequences present in GEM may be detected. The method, which requires only picogram amounts of DNA, has been used for detecting GEMS m complex environments. To perform gene probe analyses without culturmg microorgamsms by direct recovery of DNA from environmental samples, such as water or soils, cells may be collected from water samples by filtration or by centrifugatlon of ~011s. Subsequently, cells are lysed by chemical or phystcal methods. DNA may then be extracted and purified (42). Gene probes and nucleic acid hybridtzatton procedures are then used to detect DNA sequences. The combmatton of PCR technique and restriction endonuclease analysis has been used to detect baculovnuses A group of baculovnuses m which nuclear polyhedrosts virus was embedded (Autographzca callfornzca multtple-embedded nuclear polyhedrosis VU-US (MNPV), Anticarszagemmatalls MNPV, Bonzbyx mori MNPV, Origia pseudosugata MNPV, Spodoptera frugiperda MNPV, S Exigua MNPV, Anagrapha falclfera MNPV, and Hellothzs zea smgle-embedded nuclear polyhedrosis vnus) was selected for mvesttgatron Distinct profiles were obtained for each virus by amphfymg a highly conserved DNA coding sequence, and analyzing the PCR products by restrtctron analysts (43). 5. Analysis of Bacillus thuringiensis Bacillus thuringiensis (Bt) IS a major mtcrobtal msecticlde and a source of genes encodmg several proteins toxic to insects. Consequently, there IS now considerable experience with its analysts (44). Bt product IS produced by fermentation process; the broth contams a mtxture of proteins, bactertal metabohtes, spores, and growth media components. These components, whtch act synergistically, vary m their toxtctty to different insects. 5.7. Quantification of Active Components The principal toxins of Bt are the S-endotoxms or msectictdal crystal proteins (ICPs), a group of structurally related proteins that are present as crystalline inclusion bodies m sporulated cultures. 5.1.1. Standardized Methods for Potency and Analysis of Endotoxins Regulatory methods have been based on btoassay methods, and methods for the quantitative analysis of &endotoxm of Bt preparations have been revtewed
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(45). The insecticidal spectrum of each Bt subspecies differs; these have been divided mto four major classes,depending on the &endotoxins produced. Each of the four classests spectfic for insect orders. An official regulatory notice (PR 7 l-6), stating that no quantitative analytlcal procedures had been developed for &endotoxins, led to the development of a standardized bioassay to determine the active ingredient. A primary standard E61 (Bt subspp thuringiems) was adopted as international primary standard for analysis of Bt spore-crystal complexes, and was assigned a potency of 1000 IU/mg. The test insect was the cabbage looper (Trichoplusza ni [Hubner]) Product labels were required to list the active ingredient percentage, based on the assumption that a 100% product would contain 500,000 IU/mg. Newer standards of higher potency have been developed (46). A new registration standard (47) replaced the requirements of the earlier regulatory notice (PR Nottce 71-6), and required that the label specify the active mgredient in terms based on percentage by weight of insecticidal proteins determmed by analytical methods. The percentage of &endotoxms was to be specified for each order of msectsaffected. Potency umts remamed on the label as an option. Doubts have been expressed that m vitro methods of analysis ~111provtde a viable alternative to m vtvo methods for quantttatton of toxm btoactivtty (48). The retention of bioassay methods has been suggested, specifically, the flytoxicity test (49), to guarantee the absence of exotoxins that may not be detected by standard HPLC procedures. It has been proposed that ELISA-based assays may provide a convenient technique for the assayin msecttcidal protems. However, caution is required in extrapolation of the results to activity, because the proteins may be highly spectfic, and the biologtcal acttvity of combmattons of proteins occurring in Bt isolates may not be that expected from the sum of the component proteins (50). The msect toxins produced by Bt kurstaki have been detected by nnmunoassay technology developed by Strategic Diagnostics (Newark, DE) (51) The technology is apphcable to testing for transgene verification m a variety of crops A raptd, field-portable nnmunoassay test with a nonenzymattc visual detection system should be readtly adaptable to screening and monitoring the presence and tdenttty of transgenic products. Procedures have been developed for the immunoassay of msecttcidal protems, and an ELISA protocol for the total analysts of CryIA has been described (52). Results were in good agreement with those obtained by protein gel assay. ICPs toxic to lepidopterans are grouped m the class designated CryI, Cry II, and so on, and there are many related genes encoding different ICPs. Among the important questtons concerning the use of Bt is to determine how many ICP genes are present m parttcular Bt strains, and the levels of expression of
Analysis of Biopesticides
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individual genes. These questions were investigated by Masson et al. (53) by gene cloning, oligonucleotide probes, and cyanogen bromide cleavage. The &endotoxins are generally mixtures of proteins of mol wt from 27 to 140 kDa. The composttion of the mixture depends on the strain of the organtsm, but chromatographic techniques have proved inadequate to separate the proteins sufficiently to distinguish Bt subspecies. Yamamoto (549has described the isolation of the crystalline proteins from a Bt culture. Endogenous proteinaseswere removed by sodium chloride treatment, and the crystal was solubihzed at high pH. Sporesremained msoluble. The supematant was applied to a Sephacryl S-300 column, and eluted with 50 mM Tris-HCl, pH 8.0, containmg 0.1% 2-mercaptoethanol and 1mM EDTA, monitoring at 280 nm. Proteins were separatedby size.The principal components were a major protein, PI (135 kDa), and a second protein, P2 (65 kDa), responsible for mosquitoctdal activity. Then purities were assessedby SDS-PAGE or immunoelectrophoresis. Subsequently, the isolated proteins were digested with trypsm, and the complex peptide mixtures formed were separated by HPLC, using a C- 18 reversedphase column. Peptides were eluted with phosphoric acid, with a gradually increasing concentration of acetonitrile. The chromatogram provides a charactenstic fingerprint, and over 20 strains were selected for pepttde mapping. To purify protem Pl more rapidly than by Sephacryl column chromatography, an antiserum against PI from Bt kurstaki HD73 was prepared. The antibody was purified and immobilized on CNBr-activated Sepharose to provide an affinity column for chromatography. Peptide mapping provides information on the type of crystal proteins encoded by the genes present in individual strains. There are three genes termed cry1A in the HDl and some other strains of Bt kurstakz. Differences m the amino acid sequences in the protems encoded by these genes may cause significant differences in the spectrum of biological activity. Several cry genes are present in commercral Bt strains, and individual genes may be highly expressed. Information concerning which genes are expressed and the level of expression is important in the development control strategiesutilizing Bt toxins. 5.7.2. The Presence of Exotoxins In addition to the &endotoxins, some Bt strains produce a heat-stable, insecticidal, adenine-nucleotide analog, known as p-exotoxin or thuringiensm. This showed a broad range of toxicities to organisms, including mammals (moderate-to-high toxicity, oral acute LD,, rat approx 170 mg/kg). Its toxicity may be caused by its ability to inhibit DNA-directed RNA polymerase by competing with ATP, and, because mammalian mRNA polymerases are sensitive to /3-exotoxin, Bt active ingredients must be tested to show the absence of p-exotoxin as a condition of registration for use on food in the United States(55).
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A housefly, Musca domestzca,bioassay of autoclaved supernatantsIS used to detect the presenceof exotoxms.HPLC has beenused m attemptsto develop raptd, sensitive methods for detection and quantitative analysis of @exotoxm. Standard methods may require modification to reveal the complete spectrum of p-exotoxms present. A study of location of genes mvolved m p-exotoxin production showed that p-exotoxin production was plasmtd-encoded m sex strains. In the caseof the HD-12 strains, no /3-exotoxm peak was observed on HPLC. However, housefly toxtcity was observed, and a new toxic factor, termed P-exotoxm, Type II, was isolated and partly characterized.The p-exotoxms were purified on HPLC (using a Vydac 218TP54 wide-pore, reversed-phasecolumn with 57 &acetic acid mobile phase,pH 3.0) by modifymg previously developed HPLC methods. 5.2. Methods for Quantitation of Bt Preparations and Residues in Field Tests 5.2.1 ELBA Enzyme-linked tmmunosorbent assay can be used to determine the total &endotoxm proteins m residues in the field. This techmque IS useful for the investigation of the fraction of toxins deposited and their effects on nontarget organisms. 5.2.2. Total Protein Method This method is rapid and low cost, compared with ELISA, but ignores toxicity caused by spores. Determmation of total protein has been used to determine residual amounts of Bt on foliage of a spruce fir forest. Spray applications of Bt berlmer subsp kurstaki were applied to control spruce budworm (Chorzstoneura fumiferana Clem). Total protein 1smeasured by the bicmchommc acid method (56). 5.2.3. Bioassay Methods Bioassay is relatively easy to conduct. The cabbage looper has been used as the test organism m the standardized bioassay for potency. Sundaram et al. (57) have described bioassays for testing persistence of residues, using the spruce budworm, C fumzferana Clem. Determination of levels of protein expressed m transgenic plants is necessary to determine their agronomic potential, and may be accomplished by bioassay (58) 6. Analytical Requirements in Field Testing 6.1. Formulation of Active Ingredient Btopesticide efficacy is highly dependent on methods of delivery that adequately protect the agent against the action of sunlight and oxidants in the
Analysis
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of Biopesticides
envtronment. An analytical and/or bioassay process should be included m field evaluatton, to guarantee that the active ingredient remains viable. The half-life of Bt is l-4 d on the surface of bean leaves m sunlight; other microbtals are also rapidly inactivated m sunlight. Design of delivery systems must overcome these hmitations. It is necessary also to deliver droplets, each contammg a lethal dose of Bt toxin, because the toxin rapidly causes cessation of feeding. A sublethal dose may only have a temporary effect, and the Insect may recover and resume feeding.
6.2. Baculovirus Field-Test Approval by EPA Field testsof engineered organisms are subjectedto a variety of reqmrements to ensure that there are no adverse environmental effects. Small-scale field trials to assessthe impact of release of a baculovu-us AaIT strain, modified to express the insect control protein from a North African scorpion, are typical. This involved trials m 12 statesagamsttobacco budworm and cabbage looper on cotton, tobacco, and leafy vegetables, at a dose rate of 100 g active ingredient on 7.4 acres. In similar field testsconducted m 1995, EPA requested sot1sampling data to evaluate survival and persistence of the organism. In the 1996 tests, sot1 samples were to be taken at specified points during the course of the release: prior to the final application of the recombinant virus, following apphcatton, just prior to spraying with wild-type virus, and after allowmg sufficient time for dispersal of wild-type vn-us m the soil. The following assays were to be conducted: bioassay with highly sensitive insect to detect infectious polyhedra, and PCR assayto detect the recombinant gene construct. Finally, lime was to be applied to the sot1to raise pH, thus inactivating residual virus 7. Conclusion Methods of analysts are essential for effective and safe application of biopestictdes. The quantity of active ingredient applied must be known, and, to guarantee thts, the quantity present in the formulatton to be used must be measured accurately. Residues that remam m or on treated materials, and in the environment, must also be measurable, because such data is needed to assess risks entailed in using the product. Analyses of formulated products and the residues generated during their use usually require different approaches. In the latter case, higher sensitivities are required. The identity of terminal residues is important. Good analytical practices require frequent calibration of equipment and use of standards during data acquisition. Additional confirmatton of identity by spectroscoptc methods and other instrumental techniques is essential to add confidence to the data. Sensitivity m methods of pesticide analysts for quantttation of btologtcally active ingredient(s)
has increased
by orders
of magnitude
in recent decades.
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However, for many biopesticides, the question of analysts ISoften less straightforward. Biopesticides include many different types of agents, which range from complex macromolecules to whole organisms. Questions of identity and homogeneity may present difficulties, when, for example, fermentation broths are to be used. Methods of analysis may range from conventional chemical approaches to biological techniques Quantitative analysts of complex molecules, particularly those of btological origin, is becoming a routme matter, but the need for expensive, sophtsttcated mstrumentation often restricts some analyses to a limtted number of laboratories. The scope of analytical methods requires, depending on the nature of the problem, not only a sound background m analytical chemistry, but also skills that are essential to biotechnology: a comprehensive combmatton of biochemical and microbiologtcal expertise. Because approaches to the analysis of biopesticides have originated m a variety of disciplinary areas, it is no simple task to summarize their current status, in view of the rapid progress in applying new technology to the diverse areas under consideration. In addition to the problems of analysis, btologtcal matertals, such as plants or mtcroorganisms, that are capable of self-rephcation present different challenges, and are usually not amenable to classical analytical techniques. Implications of their environmental release must be investigated by appropriate biological techniques. Methods are available for the identification of genetic materials, but the assessmentof the significance of gene transfer, beyond confirmation of identity and determination of the extent to which it has occurred, lies outside the scope of the present discussion. References 1 US Statutes at Large (1910) Federal Insectzczde, Fungzczde, and Rodentzczde Act. vol 1, pp 331-335 2 US House (1996) Public Law 104-170 (HR 1627) (7 USC 136 note) Food Quality Protection Act of 1996. 110 Stat 1489. 3 (1989) Title 40 Code of Federal Regulatzons Part 160 Good Laboratory Practice Standards (EPA), (1979) Final Rule (1989). 4 Anonymous (1989) EPA Pestzcide Assessment Guzdelznes Subdzvzszon M Part A (Mzcrobzal) Series 153A. 5 EPA (1996) Mzcrobzal Pestzcide Test Guzdelznes, OPPTS 885, EPA 712-C-96280, February 1996 6 Federal Regzster 47,23928 7. Wtlkinson, C. F. (1996) When is a plant a pesttctdev Pestzczde Ozctlook 7,40,41 8 Beringer, J E and Bale, M. J (1988) The survival andpersistenceof geneticallyengineered mtcroorgamsms, m Release of Genetically-Engineered Mzcro-Organzsms (Sussman, M , Colms, C H , Skmner, F. A , and Stewart-Tull, D. E , eds ), Academtc, London, pp 2946.
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9. (1995) Chemistry and Engtneertng News, Jan 30 (1995) US Patent 538083 1 10 (1995) New York Times, 1 I Aprtl 11. McClmtock, J. T., Schaffer, C. R., and Sjoblad, R T. (1995) A comparative review of the mammalian toxicity of Bacrllus thuringzensu-based pesticides Pesttctde SC1
45,95-105.
12 (1986) Title 40 Code of Federal Regulations Part 180. Tolerances and Exemptions from Tolerances m or on Raw Agricultural Commodities. 13. Kearney P. C and TiedJe, J M. (1988) in Biotechnology for Crop Protectton (Hedin, P A., Menn, J. J , and Hollmgworth, R. N., eds ), ACS Symposium Series, 379,352-358. 14. Anonymous (1995) Agrow 225, 10 15 DowElanco ( 1994) Spinosad Technical Guzde 1994 16. Calderon, L., Brunetto, R., Leon, A., Burguera, J. L., and Burguera, M. (1996) HPLC determination of gentamicm m pharmaceutical dosage forms by postcolumn derivatization with o-phthalaldehyde Am Lab 56-59. 17 Alvinerte, M., Sutra, S. F., Badri, M., and Galtier, P. (1995) Determmatton of moxtdectm m plasma by high-performance liquid chromatography with automated solid-phase extractton and fluorescence detection. J. Chromatog. 674, 119-l 24. 18. Nakamshi, K. (1975) Structure ofthe Insect anttfeedant, azadnachtm, m Recent Advances m Phytochemutry, vol. 9 (Runeckles, C., ed.), Plenum, New York, pp. 283-298 19. Isman, M B., Koul, O., Lowery, D. T., Arnason, J. T., Gagnon, D., Stewart, J G., and Salloum, G. S. (1990) Development of a neem-based insecticide m Canada, m Neem’s Potenttal tn Pest Management Programs, Proc. USDA Neem Workshop, Beltsville MD April 16-l 7, USDA, ARS-86, 32-39. 20 Warthen, J D , Jr., Stokes, J B , Jacobson, M., and Kozempel, M. P. (1984) Estimatton of azadirachtm content m neem extract and formulations J Lzqutd Chromatog 7,59 l-598. 2 1 Cohen, E , Quistad, G B , Jefferies, P. R , and Casida, J E. (1996) Nimbohde is the prmcipal cytotoxic component of neem-seed insecticide preparations. Pesttcrde Set. 48, 135-140 22. Plimmer, J R. (1996) Regulation of natural pesticides, m Crop Protectzon Agents from Nature, Natural Products, and Analogues (Coppmg, L. C , ed.), Crtttcal Reports on Apphed Chemtstry 35, Royal Society of Chemistry, Cambridge, UK, pp 468-489. 23. Anonymous (1995) Lepidopteran pheromones: tolerance exemption, Federal Regzster. August 30,1995 (Vol. 60, No. 168) EPA, OPP 40 CFR Part 280, pp. 45,06045,062 24. Spittler, T D. (1994) Effect of regulation of pheromones as chemical pesticides on their viability in insect control, in Natural and Engineered Pest Management Agents (Hedm, P. A, Menn, J J., and Hollingworth, R N , eds.), ACS Symposium Series 55 1, ACS Washington, DC, pp. 509-5 15. 25 Bestmann, H. J. and Vostrowsky, 0. (198 1) Chemistry of insect pheromones, m Chemte der Pjlanzenschutz-und Schaedlingsbekaempfungsmittel, vol 6 (Wegler, R., ed.), Springer-Verlag, Berlin, pp. 29-164
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26 Klun, J A , Phmmer, J R , Bierl-Leonhardt, B A , Sparks, A N , and Chapman, 0 L (1979) Trace chemicals the essence of sexual communication systems m Heltothts spectes Science 204, 1328-l 330 27 Patterson, S. D and Aebersold, R (1995) Mass spectrometric approaches to the identification of gel-separated proteins Electrophorests 16, 1791-l 8 14 28 Frenz, J , Battersby, J., and Hancock, W S (1990) An exammation of the potential of capillary zone electrophoresis for the analysis of polypeptrde samples, m Proceedtngs of the Eleventh Pepttde Symposium 1989 (Rivier, J. E and Marshall, G R , eds ), ESCOM, Amsterdam, pp 430-432 29 Btemann, K , Btller, J E , Hill, J A, Johnson, R. S , Martin, S A., Pappanopolous, I A , and Vath, J. E. (1990) Determmation of the sequence of peptrdes and proteins by tandem mass spectrometry, m Proceedings of the Eleventh Pepttde Sympostum 1989 (Rivier, J E and Marshall, G R , eds ), ESCOM, Amsterdam, pp 426429 30 Lecchi, P , Le, H. M T , and Pannell, L. K. (1995) 6-Aza -2-thiothymine a matrix for MALDI spectra of ohgonucleotides Nucleic Acids Res 23, 1276,1277 3 1. Murray, K. K (1996) DNA sequencing by mass spectrometry J Mass Spectrom 31, 1203-1215 32 Edwards, C (1993) The significance of zn sztu activity on the efficrency of momtormg methods, m Monttortng Genettcally Mantpulated Organisms tn the Envtronment (Edwards, C., ed.), Wiley, Chrchester, UK, pp. l-25 33 Prakash, C S (1996) Green Fluorescent Gene. A New Reporter Gene m Transgemc Research, ISB News Report, NBIAP, VPI, Blacksburg, VA, April, pp 2-4 34 Helm, D., Labischmskt, H., Schallehn, G., and Naumann, D. (1991) Classrfication and identification of bacteria by Fourier transform infrared spectroscopy J Gen Microbial 137,69-79. 35. Magee, J T , Hmdmarch, J. M., Duerden, B. I., and Mackenzie, D W. (1988) Pyrolysis mass spectrometry as a method for inter-strain discrimmation of Candada albtcans J Gen Mtcrobtol 134,2841-2847 36 Shaw, N., and Stead, D (1970) A study of the hprd composttton of Mtcrobacter-turn thermosphactum as a guide to its taxonomy J Appl Bactertol 33,470-473 37. Snyder, A. P., McClennen, W. H., Dworzanski, J. P , and Meuzalaar, H L (1990) Characterization of underivatized lipid bromarkers from mtcroorgamsms with pyrolysis short-column gas chromatography/ion trap mass spectrometry Anal
Chem 62,2565-2573 38 Cano, R (1996) Characterizing ancient bacteria Anal Chem 68,609A--611A 39 Ricard-Pasquier, N , Ptcard, B , Heeralal, S., Krishnamoorthy, R., and Goullet, P (1990) Correlabon between rtbosomal DNA polymorphrsm and electrophoretic enzyme polymorphism in Yersinia J Gen Mzcrobiol 136, 1655-1666 40 Atlas, R M , Sayler, 0 , Burlage, R S , and Bej, A. K (1992) Molecular Approaches for environmental monitoring of organisms Bio/Technzques 12,70&7 11, 41. Holben, W. E , Jansson, J K , Chelm, B. K , and TiedJe, J M (1988) Appl
Environ Mtcrobtol
54,703.
42. Atlas, R. M. (1992) Molecular methods for environmental monitoring and containment of genetically engineered microorganisms Bzodegradatzon 3, 137-146
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43 de Moraes, R R and Marumak, J E. (1997) Detection and tdenttfication of multiple baculovuuses using the polymerase chain reaction and restriction endonuclease analysts J Vzrol Methods 63,209-2 17. 44. Htckle, L A. and Fitch, W. L., eds. (1990) Analytzcal Chemzstry of Bacillus thurmgiensis, ACS Symposium Series 432, ACS, Washmgton, DC 45. Beegle, C. C (1990) Bioassay methods for quantification of Baczllus thurzngzensls &endotoxm, m Analytzcal Chemrstry ojBacil1us thuringiensts (Hickle, L A and Fitch, W. L., eds.), ACS Symposium Series 432, ACS, Washington, DC, pp 14-21. 46. Tompkins, G., Engler, R., Mendelsohn, M., and Hutton, P. (1990) Historical aspects of the quanttftcation of the active ingredient percentage for Bacillus thurzngzenszs products, m Analytical Chemistry oj’Bacrllus thurmgiensis (Hickle, L A. and Fitch, W. L., eds ), ACS Symposium Series 432, ACS, Washmgton, DC, pp. 9-13 47 Anonymous (1988) Reference registration standard for the re-registration of pesticides containing Bacdlus Thuringzenszs as the active ingredient. Case Number 0247 EPA, OPP 1988. 48 Schwab, G. E. and Culver, P. (1990) In vitro analysis of Baczllus thurlngzensls &endotoxm action, in Analytical Chemzstry of Bacillus thuringiensis (Htckle, L. A. and Fitch, W L , eds ), ACS Symposium Series 432, ACS, Washmgton, DC, pp 3645. 49 Levmson, B. L. (1990) High performance liquid chromatography analysts of two (p-exotoxins produced by some Bacillus thurmglenszs strains, m Analytical Chemzstry ofBacillus thuringtensts (Hickle, L A and Fitch, W L , eds ), ACS Symposium Series 432, ACS, Washington, DC, pp 114-136. 50 Mtlne, R , Ge, A. Z , Rivers, D., and Dean, D H (1990) Specificity of msecttctdal crystal proteins: implications for industrial standardization, m Analytzcal Chemutry ofBacillus thurmgiensis (Htckle, L A. and Fitch, W L., eds ), ACS Symposium Series 432, ACS, Washington, DC, pp 22-35 51 (1997) ZSB News Report, National Biological Impact Assessment Program, VPI, Blacksburg, VA, September 1997, p 3. 52. Groat, R. G G., Mattrson, J W., and French, E J. (1990) Quantitative immunoassay of msectictdal proteins in Bacillus Thurlnglensls products, m Analytical Chemistry ofBacillus thuringiensis (Hickle, L A and Fitch, W. L , eds.), ACS Symposium Series 432, ACS, Washington, DC, pp. 88-97 53. Masson, L., BOSS& M , Prefontame, G., Peloqum, L., Lau, P C K., and Brousseau, R (1990) Characterization of parasporal crystal toxins of Baczllus thurznglenszs subspecies, kurstakr strains ED-1 and HD-2, in Analytical Chemzstry ofBactllus thurmgiensts (Hickle, L A and Fitch, W. L., eds ), ACS Symposium Series 432, ACS, Washmgton, DC, pp 6169. 54 Yamamoto, T (1990) Identificatton of entomocidal toxins ofBacillus thunngzensu by high-pressure liquid chromatography, m Analytical Chemistry of Bacillus thurmgiensis (Hickle, L. A and Fitch, W. L , eds.), ACS Symposium Series 432, ACS, Washmgton, DC, pp. 46-60. 55 Anonymous 40 CFR Section 180. 1011.
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56. Sundaram, A , Sundaram, K. M S , Leung, J W., and Sloane, C L. (1994) J Envzron Scl Health 24,615-703. 57 Sundaram, A, Sundaram, K M S , and Sloane, C L (1996) Spray deposttton and persistence of a Baczllus thurmglensu formulation (Foray@ 76B) on spruce foliage, followmg aerial apphcatton over a northern Ontarto forest J Environ Health SCL 31,763-813. 58. Fuchs, I. L. L., Mackintosh, S. C., Dean, D. A, Greenplate, J T , Perlak, F. J , Pershing, J C , Marrone, P 0 , and Fischoff, D A. (1990) Quantttation of Baczllus Thurzngzenszs insect control proteins as expressed m transgenic plants, m Ana1ytzcaEChemrstry ofBacillus thurmgiensis (Hickle, L A. and Fetch, W. L., eds ), ACS Symposium Series 432, ACS, Washington, DC, pp 105-l 13 59 (1966) ZSB News Report, National Biological Impact Assessment Program, VPI, Blacksburg, July 1966, pp. 1,2
29 Principles of Dose Acquisition for Bioinsecticides Hugh F. Evans 1. Introduction Although dose acquisition is a process common to all pesticides, including btopestictdes, the mformation on use of mtcrobial agents is dominated by bioinsecticides, reflecting the need to manage the many insect pests m all sectors of crop production. This chapter, therefore, deals with aspects of the dosetransfer process for bioinsecticides, concentrating on the key interactions between hosts and microbial pathogens. In this respect, dose acquisitton is considered from the three fundamental aspectsof the target host, the microbial agent, and the matching of dosage to target in the field. Discussion then concentrates on how quantitative btological information on these three aspects enables dose requirement and tank mix for the given biomsecticide to be calculated. 1.1. The Nature of Microbial Bioinsecticides Although microbial bioinsecticides are often considered to be direct analogs for chemical pesticides, particularly when they are merely substituted for them during spray applications, this disguises the many fundamental differences that must be understood to allow microbial agents to be used successfully. These dtstmctions are certainly a key theme in many of the papers m Evans (I), m which the authors discuss the biological, technological, and environmental Issues affecting use of microbtal insecticides. Evans (2) has discussed some of the principal features of microbial biomsecticides, emphasizing their biological and physical attributes, as well as the major constraints on then use for pest management. Routes of infection are determined primarily by the behavior and ecology of the target host, and, in the majority of cases,require ingestion of the infectious unit (IU), thereby placing From Methods m Botechnology, vol 5 Blopestmdes Use and Del/very Edled by F R Hall and J J Meno 0 Humana Press Inc , Totowa, NJ
553
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emphaseson host feeding habits. The ecology of the pathogen itself 1salso an important attribute m determmmg the roles of secondary inoculum m further mfection and disease expressron. In fungal pathogens, however, the prmctpal route of infection is direct contact between the fungal spore and the host integument (3). By contrast, the majority of chemical insecticides have a combination of contact, ingestion, and/or fumigant effects. Successful mfection results in etther replication, in the case of fungal, protozeal, and viral pathogens, or toxemia (possibly with rephcatron), m the case of bacterial mfections. The ability to replicate, however, is a fundamental difference between microbtal and chemical pesticides, because it introduces both a time delay in host mortality, and also results m multiplicatton of the pathogen. The latter attribute gives rise to secondary moculum and the possibility of pathogen perststence, contrrbutmg to the potential for further infection in susceptible host populations. These attributes provide opportumties, as well as constraints, m the use of mtcrobial btomsecticides, and they must be assessed quantitattvely, tf these agent are to be used effectively for pest management. The essential features of microbtal agents as pesticides are considered by a number of authors (&9J. Knowledge of the biological attributes of microbial btomsecticides 1s not only of fundamental importance to then- potential for pest management, but must also be extended to methods of application and delivery to the target hosts, The process of dose acquisition has both biologtcal and physical charactertstics, the latter being dominated by the particulate nature of mtcrobial agents, which confers limits on the degree of dilution of the pathogen that can be achieved m preparations formulated for spray application. Below a certain concentration, depending on droplet size, a point is reached at which droplets will not contain any active ingredient, and thus will not contribute to the process of dose acquisition. Particulate entitles in liquid suspenston wtll reach thts point sooner than active ingredients m solutton. The purpose of this chapter, therefore, is to bring together the biologtcal and physical processes that must be considered m designing a pathogen-apphcation system to optimize dose acqutsttion by the target organism. The prmctpal variables of the target population (Subheading 2.) and the microbial agent (Subheading 3.) are nntially considered separately, and then brought together m matching delivery to the target (Subheading 4.). 7.2. Biology and Ecology as Determining Factors in Practical Use: Historical Perspectives Eptzoottcs are the most obvious mamfestatrons of diseasesand are expressed as abnormally high levels of disease incidence, often resulting m extensive host mortality. Observattons of epizootics have been noted from early history,
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when reference was made by the Chinese to diseasesm silkworm culture. References to diseases, including descriptions of fungal, bacterial, and viral dlseases m insects, date back to the sixteenth century, even though the causal organisms themselves were not always recognized or described (IO). Fungal diseases, m particular, attracted much attention, leadmg to production of Metarhizwm anisopliae for control of Anisoplia austriaca (11). The most slgnificant observations were those lmked to pathogens that caused obvious symptoms and significant mortaltty of affected hosts. This led to the search for new pathogens, and, more importantly, to a better understanding of ecology and eplzootlology of the causal disease agents. Steinhaus (12) was one of the ploneer scientist who recogmzed this need. Although many diseases were recorded, it IS the discovery of Bacillus thuringzenszs(Bt) m 1915 (13) that brought a major breakthrough m microbial pest control. The Kurstakl strain has since become the benchmark Bt isolate for use against lepidopterous pests, although new Isolates with activity against hosts m other insect orders are being discovered regularly 2. The Target Microbial pathogens are generally unable to search actively for their potential hosts. The encounter between pathogen and host that leads to infection IS, therefore, driven mainly by host determinants, rather than by particular attributes of the pathogens themselves. Fundamental to the process of encounter between pathogen and host are the two key attributes of host susceptibility and host biology. 2.7. Host Susceptibility:
The Basis for Determining
Dosage
Successm crop protection IS determined by the ability to reduce pest populations to a level below an economic threshold. The stringency required to achieve this economic threshold will vary enormously between different crops: extremes range from no cosmetic damage, typically associated with high-value horticultural crops, to a considerable degree of damage that might be tolerated m forest crops. However, m all cases,the process of pest management aims to target the most susceptible stage of the host, relative to its potential to cause damage to the crop With few exceptions, the first-mstar larva tends to be the principal target stage, reflecting its small size and lower capacity to cause damage. For each organism, the relationship between dosage of the pathogen and susceptlbihty of the host must be determined as the basis for calculating field dosage, 2.1.1. Dosage-Mortality
Relationships
Laboratory studies of the relationships between dosage and mortality are the first steps m assessinglikely field dosage requirements. For viruses and bacte-
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95% kill (probit 6.64)
50% kill (probit 5.0)
50% kill
.
Log dose Fig 1 The influence of slope value in dosage-mortality regressionson the calculated LD,, and LDg5dosagerequirements.
rta, moculum must be delivered orally and the responses assessedas mortality over time (14). Fungal pathogens of insects requn-e topical application to the cuticle, reflecting the route of entry of the pathogen to the host (15). In all cases,the quanta1 response of interest is mortahty of the host, and tt is essential that the assays are rigidly quantified, in order to describe the data as a regression of proportionate mortaltty (usually converted by probit or other transformation) against log dosage ingested. Ideally the prectse dosage ingested in a given time should be determined, so that the result can be expressed as LD50 (the actual numbers of IUs required to kill 50% of the test population), rather than LC50 (the concentration of IUs that provides only an approximation to the precise dose ingested by each mdivtdual). Mortality levels in excess of 90% are the minimum requirement for fieldpopulation reduction, and, therefore, the slope of the dosage-mortal@ regression line must be determined accurately, to allow the required dose to be derived from the calculated regression. The tmportance of thts reqmrement is illustrated m Fig. 1, which shows, schematically, how pathogens with identical LDSovalues can have widely differing LDa5 requirements. Indeed, the mformatton gained at this stage can have far-reaching tmphcations when field dosages are calculated. In relation to relative susceptibility of different stages of msect development to applied pathogens, the great majority of studies have indicated a stg-
Dose Acquisition for Bioinsecticides
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nificant increase m dosage requirement with larval age, although this pattern may not be consistent for all pathogen groups (16). For example, LI et al. (17) demonstrated that susceptibility of obliquebanded leafroller, Chorrstoneura rosaceana, to Bt was greatest in the fourth instar and least in the sixth mstar. In this case, the early larval stages were approx one-half as susceptible as the fourth mstar, but, as the authors point out, the application of lethal concentration to the early stages, rather than precise dosage, may have obscured their true susceptibility to the bacterium. This illustrates the importance of knowmg how much food, and, hence, amount of moculum, is Ingested m a given time (see Subheading 2.2.4.). By contrast to the variability in age-related responses of larvae to Bt, larval suscepttbllity of baculovnuses tends to be strongly linked to age, although this 1smore accurately expressed as a response to mcreasmg larval weight. Evans (16) assessedthe published results for a number of studies, and calculated slope values for relatlonships between log,, LDSO/mg and log,, larval weight. For granulosls viruses (GV), slopes ranged from 0.17 for Pieris rapae to 1.77 for P. brassicae (18); for nuclear polyhedrosis viruses (NPV), slopes ranged from 0.08 for Operophtera brumata (19) to 1.02 for Hyphantrza cunea (20). The greater the value of the slope, the greater the dosage required to Infect and kill the later instars of the pest. In many cases,this can mean mcreases of several thousand-fold in IUs, which can have major cost implications for calculating field dosages. 2.1.2. Replication and Production of Secondary /now/urn Fungal and viral pathogens are characterized by massive Increases m IUs following replication within the host. Information on the rate of increase, and on the total quantity of inoculum produced on death of a given host stage, can guide design of dosage rates for field use. This knowledge can be particularly important if basic dosage-mortality responses indicate that LD,, requirements are unlikely to be economically viable. Mortahty arlsmg from the acqulsltion of primary moculum can lead to the release of secondary inoculum that is many orders of magnitude greater than the mltially applied dosage. Although this may be locally dlstrlbuted on the host substrate, it 1slikely that any hosts, mespective of their innate susceptibiltty, will succumb to the massive quantity of inoculum, should they encounter it. Several studies on baculovirus growth have indicated that peak productivity of up to 1.5 x 1Ol” polyhedral mcluslon bodies (PIBs) per individual larva can be achieved, representing around 3 x lo7 PIBs/mg body wt (NPV of Heliothis = Helicoverpa zea [21/). In relation to LDsOvalues of under 10 PIBs for first-instar larvae of most Lepidoptera, this represents a source of inoculum that can have considerable influence on the outcome of a spray operation employing baculoviruses. Similarly, fungal diseaseswill also
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yield massive quantities of secondary moculum, with potential increases m the order of 200,000-fold (22) 2.2. Host Biology: The Fundamental Basis for Dose Acquisition Drscussion in this section ~111provide the detailed basis for linking host biology to the precise point of delivery of the required dose. Knowledge of the biology of the host is fundamental to optimizing the use of microbial agents for pest control, but this 1s a relatively neglected component of the design of management programs, and one that has the potential to increase efficacy and reltabtllty, without necessarily requnmg major changes m absolute dosage requirements. 2 2 1. Recruitment and Vultinism Both the rate of recruitment (egg hatch) and voltnnsm (number of generations per year) can have profound influences on the results of dose acquisition. At its simplest level, a pest with a single generation per year ~111have a period of recruitment that, unless egg hatch occurs over a very short time period, can lead to a mix of mdividuals that range widely m susceptibtlity. Overlappmg generations add a further level of complexity that can result in virtually all stages of larval susceptibihty bemg present m the same population Therefore, sound knowledge of the stage structure of the pest populatron is essential. Such knowledge can point to methods of samplmg, such as egg counts and observed hatch rates, that will mdicate the presence of the most susceptible mdivtduals. Although simple m concept and practice, direct assessmentof hostpopulation development in real time does not allow prediction, and, therefore, offers relatively little time to make informed decisions on dosage rates and application parameters. A more sophisticated decision-support system would be based on models that use sample data to predict egg hatch and larval development rates for a particular region. Such an approach has been used for modeling both the population dynamics of target hosts and the effects of pathogens on those populations (23,24). By concentrating on the actual or predicted rates of recruitment to different life stages, and on the requirement to kill the leastsusceptible life stage present, a quantity of moculum for the whole population can be calculated. This 1sdiscussed m more detail m Subheading 2.2.3. 2.2.2. Distribution Patterns Invertebrate populations have a tendency to change dlstrrbution patterns m space, depending on the density of that population The degree of aggregation, and various mathematical mdtces that can be used to describe these changes, have been discussed by a number of authors (e.g , ref. 25). Information on the spatial distribution of a population is an important attribute that 1snot always
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considered m assessing dose acquisition m the field. This is especially true if the distribution also changes with the age of the target host, so that, for example, the first-mstar stage, although being the most susceptible to the pathogen, may actually be hidden, or, indeed, not feed at all. Such is the case with spruce budworm, Choristoneuru funziferana, which is one of the most damagmg pests of forestry in Canada and the northern United States. Timing of spray applications and placement of droplets are difficult, because the first-instar larvae do not feed, and either remain wrthin a silken hibernaculum, or, if they are disturbed or crowded, will be dispersed by wind on silken threads (26). Secondinstar larvae appear in April or May, having wintered in hibernacula, and further wind dispersal takes place. The first realistic stage of a spray operation is, therefore, the third mstar, and even this stage IS difficult to target, because of its tendency to feed cryptically on newly expanding needles, which, as they grow, will tend to dilute applied moculum per unit area. Further complication can arise when an insecticide application changes target-host density, thereby changing the distribution of the population. This factor must be taken mto account m developing appropriate sampling regimes to assesspre- and postspray pest populations. 2.2.3. Population Susceptibility Over Time Combinmg knowledge of host susceptibihty at different larval stages with information on the rate of recruitment into each of those instars provides the basis for assessingpopulation susceptibility. The need for this information will depend on the extent of damage reduction required; the mformation will also enable decisions to be made on costsof active ingredient that will be required. Figure 2 ~llustrates schematically the prmciples involved in assessingpopulation susceptibihty. Changes in the susceptibility of different larval stagesto the inoculum are lmked to the instar distrtbution pattern. Clearly, damagewill increasewith increasmg sizeof larvae, and so damage reduction ~111require targeting of theseolder larvae, with a consequent rise in inoculum requirement. In the case of insect baculovirnses, the resultmg increase in moculum costs may rule out optimal targeting of the most damaging stages.By contrast,the relatively flat dosageresponsecurves for Bt tend not to rule out its use against older larval stages. 2.2.4. Host Feeding Rate Over Time Larvae Increase feeding rate as they age. For example, the leaf area consumed by Pieris rapae increases 11S-fold from the first to the fifth mstar (27). Such increases are typical of lepidopterous larvae, and are an accurate reflection of the weight increase observed as larvae age, so that approx 90% of total food may be consumed by the final feedmg instar (28). Increasing consumption of leaf area with age has several consequences for dose acquisition.
560
Evans
Pathogen Activity (% of original)
window of opporhmity for G/ successful
Damage (feeding rate)
Time
______)
Fig. 2. Schematic representation of the three principal components of dose acquisition for application of microbial insecticides during spray operations. 1. A larger area of food consumption by a given target-insect stage provides a greater available surface for deposition of inoculum, thus potentially easing the task of droplet deposition during spray operations. This is a positive attribute that increases the likelihood of encounter between the target host and the droplets delivered to the feeding sites. 2. There is a decrease in susceptibility as larvae age, which requires delivery of much greater quantities of inoculum to feeding sites, despite the fact that increased feeding has a concomitant increase in encounter frequency between host and inoculum.
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3 Increasedareaconsumednormally equatesto increaseddamageto the crop being protected.This may beintolerable m high-value crops in which cosmeticdamage can result in seriouslossof value Pestmanagementwill normally aim to reduce damage,which, consequently,reducesperiods of feedmg andthe areaconsumed, thus limltmg the probablhty of encounterbetweenhost and inoculum A balance must, therefore, be struck between increasing the likelihood of acquisition of inoculum by increasing the area of food consumed, and the Increased dosage requirement and potential damage that could result from thts strategy. Other attributes, such as attrition of applied inoculum arising from ultraviolet (UV) light, rainfall, and so on, must also be considered in this process (see Subheading
3.1.).
3. The Microbial Agent Irrespective ofthe type ofmlcrobial agent employed asa bioinsecticlde,the fate of apphed inoculum, and Its ultimate effectiveness against target hosts,depends on a sequenceof critical events. Delivery of inoculum to the target areais the first step m this sequence,followed by the degreeof persistenceof that moculum, which determines duration of a lethal doseat the host feeding site.The final stagemay anse from the impact of secondaryinoculum on target hoststhat survived the imtlal treatment. 3.1. Field Persistence of Primary lnoculum All blomsecticides are subject to attrition once they are applied m the field The principal factor m loss of moculum IS undoubtedly UV light (29-31) Damage occurs when the microbial agents are exposed to UV light in the waveband 290-380 nm, although most absorption of UV occurs at the lower end of this scale (5). Effects can be severe, with over 50% loss of activity after a few hours of exposure of the pathogen to UV light in the field. For example, Bt, applied to vines in Australia for the control of light brown apple moth, Epzphyas postvittana, lost over half its activity within 24 h of application to fully exposed leaf surfaces (31). By contrast, Bt applied to shaded leaves still retained over 60% activity after 2 d exposure to sunlight. In a study of the relative survival of various pathogens when exposed to UV under laboratory conditions, Ignoffo et al. (32) demonstrated that the order of stabthty was Bt > Nomuraea rileyz (fungus) > entomopox virus > NPV = cytoplasmic polyhedrosis virus (CPV) > Vairimorpha necatrix (Protozoa) > granulosis vrrus (GV). However, the wavelength used in this study resulted in very rapid inactivation (half-life of 4 h or less) of all pathogens, but, nevertheless, provided useful guidance on relative rates of inactivatlon of different pathogen groups. Interactions between UV damage and temperature have also been noted, so that higher temperatures tend to increase the speed of mactlvation when pathogens are exposed to a given amount of UV. This was demonstrated m studies
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of stability of Metarhiziumflavoviride spores, in which UV exposure resulted in 20% reduction in germination at 20°C compared with 80% reduction at 50°C (33). The net effect of these two factors is to decrease the potency of the applied inoculum, sometimes at extremely rapid rates, thereby reducing the effectiveness of treatment. Awareness of the dynamics of these effects is a central component of dose acquisition, and can point to ways of alleviating the problems. 3.2. The Potential Contribution of Secondary lnoculum The majority of pathogens reproduce in their hosts, and this results in higher inoculum loads than originally delivered to the crop, although this is rarely the case with Bt. Production of significant quantities of secondary inoculum can be important in determining infection levels in hosts that may have escaped the inoculum applied in the original spray operation. The importance of secondary inoculum can be illustrated by reference to a hypothetical lepidopteran host in the family Noctuidae (in which larvae have a weight range from approx 5 mg in the first instar to around 1000 mg in the sixth instar). Infection within each instar is related to larval weight by a constant of around 1 x 1O7PIBs/mg. Thus, production of secondary inoculum will increase from 5 x 1O7PIBs for larvae dying in the first instar to 1 x 1Oi” PIBs for larvae dying in the sixth instar, representing massive multiples of a lethal dosage that may be < 100 PIBs for an early-instar larva. Likewise, an infected fourth-instar gypsy moth, L. dispar, produces around 2 x 1O5conidia on death, demonstrating the potential for secondary inoculum production (22). In terms of potential to infect further hosts, the distribution of these massive increases in inocula must be considered both spatially and temporally. Clearly, the distribution of secondary inoculum will reflect, to a very great extent, the site of death of the infected individual and the spatial structure of the population. Behavioral changes often accompany infection for baculoviruses (3435) and fungi (22,24), and are regarded as evolutionary adaptations to increase the probability of further infection and growth of the pathogen. In most cases,there is a tendency for aggregation of infected individuals, thus concentrating inoculum at specific sites in the host ecosystem. Fuxa (36) showed that populations of soybean looper (Anticarsia gemmatalis) larvae, infected by the fungus Nomuraea rileyi, were more aggregated than uninfected larvae, reflecting larval behavior and the impacts of secondary inoculum. 4. Matching Delivery to the Target The concepts outlined in Subheadings 2. and 3. provide the foundation for determining field dosage on an apriori basis, thus reducing the need for ad hoc trials, in which the optimal dosage rates are arrived at through a process of
Dose Acquisition for Bioinsecticides
563
iteration. The more detailed the information, the higher the confidence in the assumptions that can be made, and the greater the potential reliability of the field dosage rate that is calculated. This subheading deals with ways of bringing separate data together in assessing the spray window for optimal use of microbial insecticides (37). 4.7. Determining Field Dosage Rates Bateman (see Chapter 27) has discussed the choice of spray equipment and spray parameters in relation to microbial bioinsecticides, especially fungi. This information is fundamental to the calculation of concentrations of active ingredients and carrier fluids in tank mixes for the delivery of microbial agents, both to increase precision in application and to increase overall efficacy of the applied inoculum. It is assumed in the following discussion that the parameters outlined by Bateman have been included in assessing spray equipment and droplet generation characteristics. 4.1.1. Dose Acquisition Over Time: Calculation of Tank Mix for Delivery of the Microbial Agent At its simplest, the use of a microbial control agent must satisfy a single basic concept: At the host feeding sites,the distribution of droplets containing the lethal dosage must match the distribution of the susceptible host population. However, within this simplistic approach, the attributes of the susceptibility of the host population, the stability of the applied pathogen, and the host feeding rate (which equates directly to crop damage, and, potentially, economic loss) must be considered together over time. Figure 2 indicates how these parameters change together over time, so that the probability of a given dosage of pathogen inducing mortality below an economic damage threshold decreaseswith increasing time after application. This occurs through decreasing susceptibility, decreasing pathogen activity, and increasing damage over time. In essence,this results in only a limited window of opportunity to match pathogen and host at realistic cost. In most cases,the earlier the application, the greater the likelihood of delivering dosage to host within economic limits, and, thence, to acceptable mortality. Optimization of the parameters in Fig. 2 proceeds through a series of criteria derived from quantitative information on several fundamental attributes of both host and pathogen biologies. The purpose is to match the dosage requirement for a field LD9, to the deposition of droplets, and to the area consumed by the host, so that, where the three overlap, the host will consume at least an LD9, in a predetermined time (usually a low number of hours postspray). This is illustrated conceptually in Fig. 3. It is difficult to determine precisely what the field LDg5 should be for use within a spray operation, but it is possible to use the data from laboratory assays
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area consumed
Area consumed
is time limited (usually
90% mortality (37). The questton then was whether to deliver this in a single droplet or m multiple droplets at the feeding site. Based on experiments with dtfferent VMDs for delivery of droplets, rt was concluded that more effective coverage of the upper 30% of the canopy would be achteved with the smallest droplet sizes m the range of 40 to 50 pm m diameter (38). Thts required the dtstrtbutton of the LD,, dosage across several droplets. Results confirmed that thts strategy gave more effective control than placing the lethal dose m a single droplet. Further refinement was provided followmg assessment of larval behavior that indicated that moculum was encountered at both prtmary feeding sites (the newly expanding needles), and on the older needles, thus mcreasmg the apparent feeding area, r, and reducing the dosage requirement/ha (42). Thts enabled effective control to be achieved with dosages as low as 2 x 10” PIBs/ha, even though mittal calculattons had indicated a dosage requirement of up to 1 x lOI* PIBs. 4 1.3 2. FORMULATION TO REDUCE COSTS AND INCREASE EFFICACY Two key requirements of formulation are to protect the pathogen from macttvatton on the host substrate, and to enhance physical retention through the use of stickers and spreaders (42). However, the addittonal benefits of formulation must be carefully assessed against the costs of the process and the potenttal changes to droplet generation that may result from mapproprtate formulation. For baculovn-uses, recent advances have been made m UV protection through the use of stilbene optical brighteners, which also appear to increase virulence (by up to 2 14-fold), even in the absence of UV (43,441 A switch from aqueous to oil-based carrier fluid can also increase performance from a given quanttty of inoculum. An example of this approach IS descrtbed by Bateman (see Chapter 27) for the LUBILOSA project.
Droplet losses to nontarget areas may increase required dosage/ha
CE (capture efficiency of emitted droplets)
for Microbial
Half-life of activity may be only hours, mcreasmg mttial dose requirement consrderably
Constraint
Dose Acquisition
a (rate of attrition of pathogen m field)
Potentialfor
The calculated value may be very high, leading to unreahstrc costs
and Optimization
d V’95)
Parameter
Table 1 Constraints potential
1 Alter droplet spectrum and/or volume delivery rates to improve targeting. 2 Formulate to avotd evaporation 3 Use natural wind to improve selectivity of targeting.
1 If the dosage-mot-t&y slope 1s relatively low, a considerable reduction m dosage can be tolerated before mortality declmes to suboptimal levels 2 Target most susceptible stages only, acceptmg some increased damage to the crop 3 Assess potential of secondary moculum that may contribute to overall mortality. 1. Formulate to protect against UV losses, or to increase adhesion to target surface. 2 Time spray to avoid main UV daily peaks (espectally In troprcs).
Optimization
Insecticides
Dose Acquisition
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569
4.2. Transgenic Plants: A Special Case of Dose Acquisition Dose acquisttlon may also be achieved directly at the feeding site by incorporation of genes, usually Bt, within the target plant Itself (45-47). This allows more directed dose acquisition precisely at the feeding site, thus reducing the need for spray application. However, the continuous expression of the toxin gene may increase the risks of resistance developing, and, consequently, strategies for resistance management are being developed to address this possibihty (#8,49). 5. Future Requirements and Conclusions Although there have been significant advances in spray technology, and m the understanding of precise targetmg of the host feeding site, there has been a distinct reluctance to embrace this technology for control of pests m broad acre crops (50). Although it must be accepted that existing technology has a sound track record for the purpose for which it was designed, namely apphcatlon of chemical pesticides, the attributes of microbial insecticides point to the need for further appraisal of dose acquisition for these agents. This chapter has considered the interface between technology and pathogen-host interaction, concentrating on quantlficatlon of a series of key parameters that offer the potential for enhancing the efficacy of mlcroblal insecticides. A structured approach indicates areas in which improvements in application technology can be matched to the biology of both host and pathogen. Other factors, such as the need for a full lethal dose per feeding area when applying Bt, must also be considered (51). Van Frankenhuyzen et al. (51) showed that a LDg5 dosage must be ingested m one or two droplets, otherwise the larva stopped feeding and eventually recovered from the sublethal dose, effectively escaping the applied inoculum. Such considerattons can only be discovered by detailed knowledge of the parameters discussed in this chapter, and confirm the value of such information in design of management regimes employing microbial insectlcldes. Acknowledgments My grateful thanks go to Dr. Richard Jinks (Forest Research) for his constructive comments and suggestions for improvements to layout and readability. Thanks also to an anonymous reviewer for further helpful suggestions. References 1. Evans, H. F., ed. (1997) Microbial insecticides.novelty or necessity?BCPC Symposium Proceeduzgs, No. 68. British Crop ProtectionCounctl, Farnham, UK 2. Evans, H F. (1997) The role of microbial Insecticides in forest pest management, in Microbial Insectrcldes Novelty or Necessity? (Evans, H F , ed ), BCPC
570
3. 4. 5 6 7. 8 9
10 11 12. 13
Evans Symposmm Proceedings No 68, Brltlsh Crop Protection Council, Farnham, UK, pp. 29-40 HaJek, A. E. and St Leger, R J. (1994) Interactions between fungal pathogens and insect hosts Ann Rev. Entomol 39,293-322. Burges, H D , ed. (1981) Mtcroblai Control of Pests and Plant Diseases 197& 1980, Academic, London. Entwlstle, P F and Evans, H. F. (1985) Viral control, m Comprehenszve Znsect Physzology, Biochemistry, and Pharmacology (Kerkut, I. and Gilbert, L I , eds ), Pergamon, Oxford, pp 347-4 12 Granados, R R. and Fedenci, B A., eds (1986) The Bzology ofBaculovzruses,vol 1, Blologlcal Properties and Molecular Bzology, CRC, Boca Raton, FL, 275 pp Granados, R. R. and Fedencl, B. A , eds (1986) The B1oIog-y of Baculovzruses vol 2, Practical Application for Insect Control, CRC, Boca Raton, FL, 276 pp. Fuxa, J R and Tanada, Y , eds (1987) Epzzootzology of Insect Dzseases, Wiley, New York Lacey, L. A , ed (1997) Manual of Techniques zn Insect Pathology, Biologzcal Technzques Serzes, Academic, San Diego Stemhaus, E. A. (1975) Dzsease zn a Manor Chord, Ohio State Umverslty Press, Columbus, OH Stemhaus, E. A. (1956) Microbial control. The emergence of an idea A brief history of insect pathology through the nineteenth century Hilgardza 26, 107-I 60 Steinhaus, E A. (1946) Insect Mzcrobiology, Hafner, New York. Berliner, E ( 19 15) Uber die Schlaffsucht der Mehlmottenraupe. Zeltschrzft fur angewandte
Entomologie
2,29-56.
14 Hughes, P. R and Wood, H. A (1987) In vlvo and m vztro bioassay methods for baculovnuses, in The Bzologv of Baculovuxses, vol 2 Practical Appllcatlon for Insect Control (Granados, R R and Federici, B A, eds ), CRC, Boca Raton, FL, pp. l-30. 15 Vandenberg, J D (1996) Standardized bioassay and screening of Beauverza basszana and Paeczlomyces fumosoroseus agamst the russian wheat aphid (Homoptera. Aphldidae). J Econ. Entomol. 89, 1418-1423 16 Evans, H F. (1986) Ecology and epizootiology of baculoviruses, m Bzology of Baculovlruses, vol 2 Practccal Applrcatlon for Insect Pest Control (Granados, R R and Federicl, B. A., eds ), CRC, Boca Raton, FL, pp 89-132 17 Ll, S. Y , Fitzpatrick, S. M., and Isman, M. B. (1995) Susceptlblllty of different mstars of the obliquebanded leafroller (Lepidoptera. Tortncrdae) to Bacillus thuringzenszs var kurstakl. J Econ En tomol 88, 6 1O-6 14. 18. Payne, C. C , Tatchell, G. M , and Williams, C F (198 1) The comparative susceptibilities of Plerrs brasszcae and P rapae to a granulosis vu-us from P brasszcae. J lnvertebr
PathoI 38,273-280
19 Wlgley, P. J (1976) The eplzootlology of a nuclear polyhedrosls virus disease of the winter moth, Operophtera brumata L at Wlstman’s Wood, Dartmoor Unpublished D Phil. Thesis, Oxford University 20 Bouclas, D G. and Nordm, G L. (1977) Intermstar susceptibility of the fall webworm, Hyphantrla cunea, to Its nucleopolyhedrosls and granulosis vnuses J Invertebr Path01 30,68-75
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21 Ignoffo, C. M and Hmk, W. F. (1971) Propagation of arthropod pathogens m living systems, m Mtcrobial Control of Insects and Mttes (Burges, H. D. and Hussey, N. W., eds.), Academic, New York, pp. 541-580 22. Hajek, A. E., Larkin, T S., Carruthers, R. I., and Soper, R. S. (1993) Modeling the dynamICS of Entomophaga matmatga (Zygomycetes, Entomophthomles) epizootics in gypsy moth (Lepidoptera, Lymantriulae) populations. Environ Entomol. 22,1172-l 187 23 Elkmgton, J S , Dwyer, G., and Sharov, A. (1995) Modellmg the eptzootiology of gypsy moth nuclear polyhedrosis vwus. Comput Electron Agrtcult 13,91-102. 24. Carruthers, R I and Soper, R. S (1987) Fungal diseases, in Eptzootiology oflnsect Dzseases (Fuxa, J. R and Tanada, Y., eds.), Wiley, New York, pp. 357-416. 25. Taylor, L. R. (1984) Assessing and interpretmg the spatial distributions of Insect populations. Ann. Rev. Entomol 29,321-357 26. Mattson, W. J , Simmons, G A., and Wetter, J. A. (1988) The spruce budworm m eastern North America, m Dynamtcs of Forest Insect Populattons Patterns, Causes, Impltcattons (Berryman, A. A., ed.), Plenum, New York, pp 309-330 27 Tatchell, G M. (198 1) The effects of a granulosis vnus infection and temperature on the food consumption of Pteris rapae (Lep.:Pieridae). Entomophaga 26,291-299 28. Harper, J. D. (1973) Food consumption by cabbage loopers infected with nuclear polyhedrosts virus. J Znvertebr. Pathol. 21, 191-197. 29. Moore, D., Bridge, P D., Higgins, P M., Bateman, R P., and Prior, C. (1993) Ultra-violet radiation damage to Metarhzziumflavovzride conidia and the protection given by vegetable and mineral oils and chemical sunscreens Ann Appl Btol 122,605-6 16 30. Ignoffo, C. M. and Garcia, C (1994) Antioxidant and oxidative enzyme effects on the inactivation of mclusion bodies of the Heltothts baculovnus by simulated sunlight-UV. Environ, Entomol 23, 1025-1029. 3 1. Bailey, P., Baker, G., and Caon, G. (1996) Field efficacy and persistence of Bacrllus thuringtensrs var kurstaki against Epiphyaspostvtttana (walker) (Lepidoptera: Tortricidae) m relation to larval behaviour on grapevine leaves Aust J Entomol 35,297-302 32. Ignoffo, C. M., Hostetter, D. L., Stkorowslu, P. P., Sutter, G., and Brooks, W. M (1977) Inacttvation of representative species of entomopathogemc viruses, a bacterium, fungus, and protozoan by an ultraviolet light source. Environ Entomol. 6,411415. 33. Moore, D., Higgins, P M., and Lomer, C. J. (1996) Effects of simulated and natural sunlight on the germination of conidia of Metarhtztum jlavovtrtde Gams and Rozsypal and interactions with temperature. Btocontrol Set. Technol. 6, 63-76. 34. Evans, H. F and Allaway, G. P (1983) Dynamics of baculovn-us growth and dispersal in Mamestra brasszcae L. (Lepidoptera: Noctuidae) larval populations introduced into small cabbage plots Appl Envtron Mtcrobtol 45,493-50 1 35 Goulson, D. (1997) Wipfelkrankheit. modtfication of host behaviour during baculoviral infection Oecologta 109,219-228. 36. Fuxa, J. R. (1984) Dispersion and spread of the entomopathogemc fungus Nomuraea rtleyt (Momliales: Moniliaceae) in a soybean field. Environ. Entomol. 13,252-258.
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37. Evans, H. F (1994) Laboratory and field results with vuuses for the control of insects In BCPCMonograph No 59 Comparing Glasshouse and Field Pesticide Performance II (Hewitt, H. G., Caseley, J., Copping, L. G , Grayson, B. T., and Tyson, D., eds.), BCPC, Farnham, UK, pp. 285-296 38. Entwistle, P F., Evans, H F , Cory, J, S., and Doyle, C J. (1990) Questtons on the aerial application of microbial pesticides to forests. Proceedings of Vth Internatzonal Colloquium on Invertebrate Pathology, (Pinnock, D E , ed.), Adelade, Australia, pp. 159-163. 39. Evans, H. F , Stoakley, J. T., Leather, S. R., and Watt, A. D. (1991) Development of an integrated approach to control of pine beauty moth in Scotland. Forest Ecology Manage 39,19-28.
40. Evans, H F (1994) The control wmdow: a conceptual approach to usmg baculovlruses for forest pest control, in Proceedwgs VI International Colloquium on Invertebrate Pathology andMtcrobza1 Control (Bergoin, M., ed ), Montpellier, France, pp. 380-384. 4 1. Gory, J S. and Entwistle, P. F. (1990) The effect of time of spray application on mfectlon of the pine beauty moth, Panolis jlammea (Den. and Schiff.) (Lep , Noctuidae), with nuclear polyhedrosis wus. J. Appl. Entomol 110, 235-241 42 Jones, IS. A., Cherry, A. J., Grzywacz, D., and Burges, H. D. (1997) Formulation: Is it an excuse for poor application? m Mwroblal Insecticrdes: Novelty or Necesszty7 (Evans, H. F., ed.), British Crop Protection Council, Famham, UK, pp. 173-l 80 43 Dougherty, E. M., Guthne, K. P , and Shapiro, M. (1996) Optical brighteners provide baculovnus actlvlty enhancement and uv radiation protection. Biol Control 7,7 l-74 44. Evans, H. F. and Shapiro, M. (1997) Viruses, in Manual of Techniques zn Insect Pathology (Lacey, L A., ed.), Academic, London, pp. 17-53, 45. Kozlel, M. G., Carozzl, N B , Desal, N., Warren, G. W , Dawson, J., Dunder, E , Laums, K , and Evola, S. V (1996) Transgemc maize for the control of European corn borer and other maize insect pests. Engineering plants for commercial products and applications Ann NY Acad Scl 792, 164-l 7 1 46 Sims, S R., Pershing, J. C., and Reich, B. J. (1996) Field evaluation of transgemc corn contammg a Bacdlus thuringlensls berlmer msectlcldal protein gene against Hellcoverpa zea (Lepldoptera Noctuldae). J Entomol Scz 31,340-346. 47 Stewart, C. N , Adang, M. J , All, J. N., Raymer, P L., Ramachandran, S , and Parrott, W. A. (1996) Insect control and dosage effects m transgenic canola containing a synthetrc Bacdlus thurzngrenszs CrylAC gene Plant Physlol. 112, 115-120 48. Roush, R T (1994) Managing pests and then resistance to Baczllus thurzngienszs Can transgemc crops be better than sprays? Biocontrol Scl Technol 4,50 l-5 16. 49. Snow, A A. and Palma, P. M. (1997) Commerclalizatlon of transgenic plants: potential ecological risks. BzoScrence 47, 86-96. 50 Chapple, A C and Bateman, R. P. (1997) Application systems for microbial pesticides* necessity not novelty, m Mxroblal Insecticides Novelty or Necesszty7 (Evans, H. F., ed ), British Crop Protection Council, Farnham, UK, pp 18 l-l 90
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51. Van Frankenhuyzen, K and Payne, N J. (1993) Theoretical optlmlzatlon of Baczllus thurzngzenszs Berliner for control of the eastern spruce budworm, Chorzstoneura fumijkrana Clem--(Lepidoptera: Tortricldae)-Estimates of lethal and sublethal dose requirements, product potency, and effective droplet sizes. Can Entomol
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Strategies for Resistance Management Richard T. Roush
1. Introduction: Potential for Resistance Resistance to pesticides has evolved in more than 500 species of insect pests and more than 70 species of weeds (1,2). It was once believed by some that resistance would be unlikely for blopestmides because they were natural, already exposed to eons of evolution, and of short persistence However, because of the pervasiveness of resistance to other pesticides, few entomologists have ever agreed with that view. In the case of Bacillus thurwzgzenszs (Bt), the most commercially important biopesticrde currently, the myth of mvincrbility was challenged in 1985 with the relatively easy selectron in the laboratory of resistance m the Indian meal moth (Plodla interpunctella, a pest of stored gram) (3) and was truly demolished startmg in 1990 by the appearance of resistance m the diamondback moth (Plutella xylostella, a pest of cabbage and other cole crops) in Hawaii, Asia, the continental United States,and Central America from the use of Bt sprays +8j. Subsequent laboratory experiments have selected resistance in several other species (7). Resistance has also been selected to Baczllus subtilu, a blocontrol agent of a fungal disease of plants (9). 1.1. Specificity of Mode of Action Will other biopestrcides be any less likely to suffer from resistance? Key mdicators of the potential for resistance are specificity of mode of action and past history of resistance m the targeted pests. Prior to the introduction of modern synthetic insecticides, reststancewas a rare event, wrth no more than about a dozen cases prior to 1945. Resistance emerged as a common problem for insects and mites only after the introduction of DDT and subsequent msectitides that acted on particular sites in the nervous system (20). Srmllarly, resisFrom
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tance to herbicides was uncommon until the mtroduction of triazmes (attacking photosystem II), and first emerged as a problem for fungicides with benomyl (disrupts beta-tubulm). In all of these cases,reststance could be conferred by single gene changes that either altered the target site or increased the degradation and excretion of the pesticide (II). Old morgamc pestrcides, such as lead arsenate and Bordeaux mixture (and even some more modern protectant fungtctdes), apparently have multiple modes of action and are difficult to overcome with single gene changes. In effect, there was little usable genetic variation for resistance to inorganic pesttctdes, but relatively abundant genetic variation for resistance to synthetic pesticides. Although increased specificity was also probably generally associated with increased efficacy and therefore increased selection pressure (ZO), specificity of mode action 1sclearly a major predictor of resistance risk. In the case of Bt toxms, at least one route to resistance appears to be a single major gene that confers resistance to a limited group of Bt toxins (Cry 1A and Cry 1F) through reduced binding at a target site m the insect mid-gut (7,12-16) Thus, we might expect that any biopesticide with a specific mode of action would be at risk. At least some biofungtcides and mycoherbicides probably achieve selectivtty by attacking particular physiological target sites. Resistance has already been found to insect viruses (17). Of particular note is the apparent resistance to Heliothis nuclear polyhedrosis vu-us in Heliothzs subjlexa, an insect so closely related to the tobacco budworm (Ffelzothis virescens, a major pest of cotton) that it was possible to use crosses with the budworm to demonstrate that resistance seemed to be under control of a single major gene (28). Depending on the stage at which resistance occurs (e.g., preventing replication), resistance may render irrelevant any other genetic mampulattons to the vn-us (such as the mcorporatton of venoms that attack the Insect nervous system); any manipulation that improves potency might nomtally even increase the risk for resistance by increasing efficacy and therefore use and selection pressure. It is even possrble that insectscould evolve resistance to the venom toxins themselves by a mutation at the target site m the insect. 7.2. History of Resistance in Targeted Pests In addition to genetic variatton, selection pressure 1srequired for resistance to evolve. Selectton pressure is a function of the mtensity (especially frequency) of pesticide use, the proportion of the population that is treated each generation, and other features of pest biology. Absolute numbers of pests exposed each generation may also play a major role at least at the local level because this may increase the likelihood that resistance genes can be present at any given trme, as appears to be the case for herbicide resistance m annual ryegrass (2). Perhaps the most readily available mdicator of the potential for
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selectlon pressure m any given species and envlronmental circumstance is its past hlstory of resistance. For example, major insect and mite pests of glasshouses routmely evolve resistance very rapidly. Because of the high value of the crops, they are sprayed frequently m a largely futile attempt to maintain zero Infestation levels. Further, the pest populations are often isolated, with little dilution of resistance from unselected mdividuals. Even where not strictly contained within glasshouses, the pests are usually concentrated on suitable host plants in and around the glasshouse complex (19,20). In many comparisons of similar or closely related pests(even with the same speciesin different habitats), resistanceevolves quickly where a high proportion of the population is exposed each generation (21,22), i.e., when there are only small refuges of untreated mdlviduals. Beyond the obvious prediction that species and circumstances that have suffered resistance clearly have the requisite ecological characteristics for reslstance and are likely to evolve resistance again, such examples also help to predict problems in novel circumstances. For example, the cattle horn fly, Huematobia irritans, had not suffered serious resistance problems until the introduction of pesticide impregnated ear tags, a slow release device (23). Because the ear tags controlled flies so effectively, they prevented the dilution of resistance on tagged animals even where there were refuges of flies on nontagged cattle (24). Thus, it should not have been a surprise that resistance evolved. This example also illustrates the importance of persistent formulations on the evolution of resistance, a feature that will be discussed m more detail in Subheading 2.2. 7.3. Registration Requirements for Resistance Management Governmental regulatory agencies have shown increasing mterest m reslstance and resistance management as a consideration m the registration of new products. Within the European Union, a very non-bureaucratic proposal for resistance risk assessmentis being developed within the European and Medlterranean Plant Protection Organization for possible adoption as early as 1998. The evaluation system relies on expert opmion for answers to a maximum of ten questions that focus on selection pressure (25). Resistance management IS also a major regulatory issue for Bt-transgenic crops, with at least the US EPA and Australian National Registration Authority placing restrictions for resistance management purposes on the sale and use of transgemc crops. The initial frequency of resistance alleles prior to the first use of a pestlclde IS rarely known, but population genetics theory and some experimental work suggest that the frequencies range from 1Oe3to 1Oe9depending on resistance mechanism (2,10,26,27). Resistance will, of course, evolve more quickly if the frequency of resistance alleles is higher rather than lower, so this Includes
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one element of resistance risk. Although it would be impracttcal to try to estimate the frequencies of resistance alleles that are extremely rare, it is feasible to test whether reststance alleles are present at hrgh frequencies, as has been attempted for Bt (27) and fungicides (28). In sum, resistance management should be a major concern for most tf not all biopesticides, not only m terms of tradmonal commercial consideratrons, but also potentially as a regulatory issue,espectally whenever the pestictde can be considered important to the public good. Resistancerisk assessmentwill ltkely remam an Inexact science,but still useful and inexpensive compared to pesticide resistance. 2. Tactics for Resistance Management Resistance management plans have been characterized as proactive and reacttve. Proactive plans anticipate the potential for resistance and attempt to delay it before resistance IS ever detected. Reactive plans respond to a resistance crisis that has already occurred in the field, often with such tactics as pestictde mixtures and higher rates that desperately aim only to control the resistant pests. Because the frequency of resistance is already high, these tactics have httle likelihood of actually slowmg the evolutton of resistance, as will be outlined later in this chapter. The focus of this chapter will be on proactive resistance management. It IS commonly argued that resistance managers rarely recommend more than reducmg the use of a particular pesticide, that is, to simply apply good integrated pest management (IPM). Reducing the overall number and area of applications through good IPM is critically important, but there are also other key resistance management tactics that are not obvious from general prmctples of IPM. For example, as discussed m Subheading 2.7., rotational use of pestrtides across generations 1ssuperior to mosaics or shorter term rotations of pesticide use. This is true even rf the same amount of each of the pesticides 1s applied. Because many pests (such as the cotton bollworm Hellcoverpa zea) affect several crops (e.g., cotton, corn, tomatoes, soybeans), Integrated management of pests and then resistance often requires a unified cropping system approach rather than focusing on specific crops. Given the diversity of potential biopesticides, rt would be impossible to describe m any detail a complete resistance management strategy for all products and circumstances, but I will attempt to describe as specifically as possrble which tactics seem most appropriate for particular kinds of pesticides. In particular, the tactics that are most appropriate for transgenic crops are often very different than those for sprays The tactics to be considered here include: refuges (reduced numbers of apphcatrons and areas treated, taking advantage of alternate controls), low persistence formulations, high doses, low doses, targetmg most sensitrve life stages,improved
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spray coverage, pesticide rotations, pesticide mixtures, and selective vs broad spectrum products. 2.1. Refuges: Reduce Number and Area of Applications As noted above, one of the most obvious and consistentinfluences on the rate at which evolution evolves IS the proportion of the population that escapespesticide exposure each generation m “refuges.” The refuge may include, for example, noncrop plants or crop plants that are not treated. Refuges may also include plant parts in which insectsare protected from exposure (say a codlmg moth larva m an apple), but it is critically tmportant to realize that not all susceptible insects that survive treatment are necessarilyin a refuge. In many cases,the insectsthat survive failed to receive a lethal exposure rather than were totally unexposed. Peststhat most often evolve resistanceare generally concentrated on high value crops or, in the caseof medical or veterinary pests,are closely associatedwith humans or hvestock. Refuges have been legally mandated as part of the resistancemanagement strategy for Bt-transgenic crops m the United Statesand in Australia (29). One can gain some quantttattve insight into the potential impacts of refuges through the use of simulation models. Many readers wtll be correctly skeptical about the predictive power of models, but the ones used here are sample,make few assumptions, and aim to highlight which influences are most likely to be most important for resistance.The models just quantify In more detail some basic arithmetic. For example, if 90% of the population is exposed to selection that kills all susceptible (SS) individuals but none of the heterozygotes (RS), we would expect that resistance would increase by 1O-fold each generation. If there were 10 resistant heterozygotes in a population of 10,000 eggs, 100% mortality of the 90% of the larvae exposed to selection would leave only 1000 larvae, where 10 were still resistant heterozygotes, and a lo-fold increase m the frequency of the reststance allele. Two more generations of such selection would push resistance to a frequency approaching 50% (each heterozygote has one R and one S allele) with control failures imminent. When the simulation calculates this more precisely (accounting for the resistant homozygotes), the actual value is a frequency for the resistance allele of 34% after three generations of selection, and 56% after four generations; four is the value actually graphed m Fig. 1 (10% refuge at 0% heterozygous mortality). Even where the initial resistance frequency is fairly high (1Oe3),a large refuge causes a srgmficant delay of resistance (Fig. 1). In the field, control failures typically occur within a few generations (before or after) of when the resistance allele frequency exceeds 50%, depending on population growth rates and what constitutes acceptable levels of control m the field. All other things being equal, resistance evolves slower for models that assume there is more than one gene involved in resistance.
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0.00
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Fig 1 Effect of mortality of RS heterozygotes and refuges on the evolution of resistance, as measured when the frequency of the resistance allele [R] exceeds 50% Results of a simulation model assuming a single locus, random mating, no selective mortality of reslstant homozygous larvae, that some fraction of the population escapes exposure (refuges of 5, 10,20, or SO%), and mltial resistance allele frequency @) of 10e3. Data pomts Include 0,50, 75,90,95,96,97,98,99,99.5, and 100% mortality For most pests that regularly evolve resistance, the only way to preserve refuges 1s usually to reduce the frequency or dlstnbutlon of sprays. These pests are generally already heavily concentrated on valuable crops or are otherwise closely associated with humans. In other words, for pests that are at high risk for resistance, we can only afford to use pesticides when they are absolutely required to control the pests, I.e., when the pests exceed economic (or action) threshold densities It 1sarguable that the most important contribution to resistance management has been the development of improved thresholds, samplmg schemes (including the use of “presence/absence”
techniqueslike insect pheromone traps), and predictive models. There are many examples control pests without treating refuge. For example, early (Leptinotarsa decemlzneata)
in which “spot treatment” is often sufficient to the entire population and thereby increasing the season infestations of Colorado potato beetle and spider mites (Tetranychus species) are often
concentrated along the edges of fields or orchards. Weeds are often patchy within
fields and can be controlled
by post-emergent
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Spot treat-
ments only where the pest densities have exceeded the threshold means that the rest of the crop contributes to the refuge (e.g., 30). In such cases, spraying the entire field or orchard will not generate economic returns in the short term and wtll only worsen resistance.
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For at least most insects, so many factors can control pest populations that allowmg some to survive this generation will not necessarily mean that their offspring will be damaging in the near future. For weeds and fungal diseases, there is perhaps an even greater need to integrate biopesticides with other control tactics, such competltlve or resistant cultlvars, crop rotation, and mechamcal controls. Such tactics have resulted in a significant delay of resistance in some of the most recalcitrant insect pests, such as the use of crop rotation for the Colorado potato beetle (31). 2.2, Low Persistence
Formulations
The persistence of a pesticide 1s a two-edged sword. Users want enough persistence to control the pest, but excessive persistence can continue to select for resistance long after the pest has been suppressed below damaging numbers. A persistent pesticide can have the effect of regular prophylactic treatments: rapid resistance.Thus, the advice to avoid persistentpesticidesor formulations has been among the oldest and most widely accepted in resistancemanagement (32), and is well documented by experiment (e.g., 33) and theory (34). Most blopestlcldes probably will have short persistence. Perhaps the most notable exceptions are insect-resistant transgemc crops, including those using Bt but also those using other toxms (e.g., 35). In this case, persistence is required as a matter of necessity m some crops; without expression m the plants, the toxins are simply not sufficiently effective to be economically competitive m cotton or potato crops. Further, for some of the targeted pests, the expression of these plants 1smaintained at such a high level (more than 10 times the dose needed to kill all susceptible insects) throughout the growmg season (36) that they may actually manage resistance more effectively than if the same toxms were intensively used as sprays (37), as discussed in the next section. In contrast to transgemc crops, most pesticides cannot be consistently and economltally maintained at such high residue levels. Nonetheless, because of the persistence of exposure, resistance management for transgenic plants requires the use of neighboring refuges of nontransgemc host plants (36-39), as has been mandated for Bt-cotton (291, High levels of persistence of biopesticides are probably not desirable outside transgemc crops, and even then, transgenic technology 1s not always appropriate. Especially where pests exceed damaging densities only occaslonally, such as for soybeans m the United States, it is probably be much more sensible to use Bt sprays (where they are effective) or other technologies (e.g., baculoviruses) for control. Although it is now techmcally feasible to express Bt toxins in such organisms as algae for control of mosquitoes and other medically important pests, it must be questionable whether such delivery systems will be counterproductive by accelerating resistance.
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2.3. High Doses Contrary to popular myth, there 1s no general advantage to applymg high doses of pesticides, and indeed high doses may even inhibit the biological control component of integrated management programs for insects and mrtes. Experiments with fungicides have consistently failed to show an advantage to high application rates and have often showed that lower rates selected for resistance more slowly (28). For msecticides, acaricides, and herbicides, there are fewer experiments, but neither theory or experiments support the necessary use of high rates in the field (3#,40,41). To explore this more fully, I will focus on the general case for msecttcides, where the arguments are very similar to those for other pesticides. When selected m the field, resistance to insecticides is typically caused by a smgle major gene (10,26), whrch provides a convenient but not essential assumption for the discussion that follows. Whether resistance is generally simply mherrted for herbicides and fungicides IS less clear, but it is well establtshed that single major genes can also confer high levels of resistance to both of these groups (2,11,28). For any gene locus with one resistance allele, there would be three genotypes: SS susceptible homozygotes, RS heterozygotes (which may be either resistant or susceptible depending on the intrmstc charactertstics of the mechanism and the dose applied), and RR resistant homozygotes Resistance is often described as dominant (heterozygous individuals show senstttvtty that is most like that of the resistant homozygotes) or recessive (heterozygotes tending to be susceptible), The expected frequencies of the various genotypes is a simple binomial probabmty function (first developed independently by Hardy and Wemberg). wherep represents the frequency of the resistance allele, and q the frequency of the susceptible allele, the frequencies of RR, RS, and SS are. p*, 2pq, and q2, respecttvely. While resistance is still rare (as when a pesticide is first introduced), the most common carriers of a resistance allele should be the heterozygotes. For example, if the frequency of resistance is 10m3(which IS only modestly rare), the frequency of heterozygotes will be approx 2 x 10-3, whereas the frequency of resistant homozygotes ~111be I 04, about 2000-fold less common. The high-dose strategy 1sbased fundamentally on the twm assumptions that essentially all heterozygotes will be killed at the doses of pesticide used and resistance alleles are stall so uncommon that resistant homozygotes will be greatly outnumbered by and will mate only with susceptible homozygotes immigratmg from refuges (3437-40). As a practical matter, these assumptions can be rarely met for pesticides that must be sprayed or drenched on a crop or pest breeding site. To achieve a significant delay of resistance, the mortality of the heterozygotes must exceed 90% unless refuge sizes are very large, i.e.,
583
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A 40 E s 3o z = 20 ii .E IO ti
Resistance
Recessive
Resistance Dominant , I 1 0.85 0.90 0.95 Mortality of SS Homozygotes
1.0 0
Fig 2 Effects of low to hrgh doses on selectton for reststance in terms of mortaltties of heterozygotes. The imttal resistance gene frequencres were lOA and 20% of the populatron was assumed to escape exposure each generation. “Reststance Recessive” assumes that resistance 1svery similar in expression and inherttance to Bt resistance m the diamondback moth, that IS, the heterozygotes are almost as sensitive as the susceptible homozygotes (16). “Resistance Dominant” assumes that heterozygotes are never killed by the toxtn within the ranges of doses used. When resrstance IS semrdominant (“Semldom”), mortality of heterozygotes reaches 70% at doses that kill 100% of the susceptible homozygotes
>20% (37-39, see Fig. 1) Even doses that kill 100% of a susceptible population will confer no benefit if resistance ts somewhat dominant, that is, the heterozygotes largely survive (Fig. 2). Given that many tf not most reststance mechanisms confer at least lo-fold resistance to heterozygotes, doses needed to achieve sufficiently high mortality would have to be at least 10 times higher than are needed to control the initially susceptible pest populatron, whtch ts generally unacceptable environmentally or economtcally. Two other factors hmtt potential for consistently high mortality of heterozygotes: Most apphcatton methods fat1 to provide uniform coverage of the crop (thereby allowing some mmimally treated heterozygotes to survtve) and sprays generally expose a range of lifestages, some of which will be less susceptible to the toxrcant (e.g., 42). The high dose strategy also falls to delay resistance significantly once the resistance allele frequency exceeds 10e2 (37) unless the refuge stze 1s very large (20% or greater). Thus, the use of higher doses 1sespecially mappropriate once resistance has been found m the field (40), which 1sgenerally difficult to do before the resistanceallele frequency exceeds1% (as discussedm Subhead-
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ing 3.). The high dose strategy also assumesthat the nnmtgration of susceptible migrants from refuges and then matmg with resistant survtvors will not be affected by the pesticide, an assumption that is usually not met by chemical sprays (34,37,40), The level of expression of Bt toxins found in transgemc cultivars 1s often high enough to constitute a high dose for some pests when they feed as recently hatched larvae (27,37,43), but this may be one of the few places where the high dose strategy can be successfully applied. 2.4. Low Doses As noted above, experiments with fungicides show that at least occasionally, lower concentrations of pesticides select for resistance more slowly than full label rates. Fewer experiments have been run for herbicides or msectictdes, but simulation models suggest that low doses that allow up to 20% of susceptible Individuals to survive will at least slightly slow the evolution of resistance (Fig. 2). Of course, the resulting poorer short-term control may also cause greater pest damage, and would probably be unacceptable m the absence of alternative control tactics. 2.5. Targeting Most Sensitive Life Stages In many cases,even resistant pests can be ktlled when they are most sensitive, generally when they are young (e.g., 42) Thus, we often try to target appltcations to the most sensitive life stages and to avoid exposure of the less sensitive ones for which resistance genes are more likely to provide a selective advantage. In the case of Bt transgemc crops, this leads to a recommendation against seed mixes of transgenic and nontransgenic plants as a refuge strategy (37), and even against the umntentional impurity of lines. The problem is that heterozygous larvae can grow on nontransgenic plants until they are no longer very susceptible to the Bt toxin, then move to transgenic plants and survive even when then susceptible siblings are still killed, resultmg in a sigmticant fitness advantage to resistance. 2.6. hproved Spray Coverage To the author’s knowledge, the impact of spray coverage on resistance evolution has not been thoroughly investigated m either experiments or simulation modeling. However, simple models suggest that doses causing a range of mortality from 80-100% of susceptible individuals have little effect on the rate of selection for resistance unless resistance is recessive (Fig. 2). One might expect that very sloppy coverage would allow more susceptible individuals to survive any given apphcation, thereby slowing the rate of resistance selection, whereas neither thorough or sloppy coverage would be likely to kill a high proportion of resistant mdtviduals. As described m Subheading 2.3., poor coverage of the
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crop is but one reason that an insufficient proportion of heterozygotes can be controlled to make a high dose strategy effecttve. However, poor coverage can also mcrease the need for repeated applications, which seems likely to mdirectly increase overall selection pressure, not to mention control costs. Thus, improved spray coverage seemsa sensible goal for both pest control and reststance management.
2.7. Pesficide Rotations Rotatmg the use of pestictdes over an entire area m a so-called “window strategy” tied to the calendar has proven to be a very effective resistance management tactic both m terms of both adoption and efficacy (3444). The use of different compounds at roughly the same time in netghbormg fields creates a mosaic of treatment patterns and should be avoided. Mosatcs are stmply the worst way to deploy a set of pesticides (34). Similarly, the rotation of pestttides within a generation IS not desirable. The problem for both is that you have simultaneous selection with several pesticides, resultmg in much lower pesticrde durability (3445). Consider a case m which selectton for resistance is so strong that you get resistance m a single generation. If you have two pesticides and select resistance to the first pesticide, you at least have the second pesticide to fall back on, for a total of two generattons of control. If instead you splat the population in half, depending on what assumptions you make about the dominance of resistance, roughly half of the populatton will be resistant to each of the pesticides in the next generation, which is essentially a failure after one generation. Make a more elaborate model (34), or do the experiment (49, and you find that rotation across generations 1sroughly twice as good as field-to-field mosaics or rotation within a generation when two or three pesttcides of differing crossresistance (i.e., do not share a common resistance mechamsm) are available. When there are overlapping generattons, one should aim for a cycle longer than the mean generation time. Most pesticides differ in efficacy within a season and in effects on beneticial species. This provides a rational basis for allocatmg pestictdes during a year to specific windows to optimize their use for both pest and pestictde resistance management (e.g., 27). For example, Bt products often have lower efficacy than other insecttcides, and may therefore be more appropriate to use early in the cropping cycle, when the crop can withstand higher denstties of larvae and preservatton of benetictals is especially important. In the case of insecticides, each new mode of action might be allotted a 1-3 mo period depending on local condttions (e.g., duration of the cropping season, which months had the fastest generations). This system has proved to be extremely successful for cotton m Australia and Zimbabwe (34,41,44).
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The advantages are not specifically dependent on fitness costs to resistance. Such fitness costs improve the durability of a pesticide and the effectiveness of any resistance management program (381, but the genetic conditions that favor rotations over other tactrcs on the basts of fitness costs appear to be rare (3446) 2.8. Pesticide Mixtures Contrary to another popular myth, it is not necessarily true that mixtures of pesticrdes will delay resistance. It has long been clear that mixtures of msectitides do not necessarily delay resistance compared to the rotational use or sequential mtroduction of the same msecticides. Experimental studtes have failed to consistently find any advantage to mixtures (47,48), and theoretical models showed that mixtures will significantly delay resistance only when several condttions are met (34,38,39,49). Even in the case of fungicide mixtures, whtch are widely considered to have been effective m delaymg resistance, the effective mixtures have used combmations of protectant fungicides to which resistance apparently rarely evolves (presumably because of multiple sites of action) with systemic fungicides of more specific modes of action (28). To be most effective, mixtures require low mitral frequencies of the resistance genes, refuges (as with the high dose strategy, such that resrstant genotypes are rare and can be diluted), high mortal&y from each of the pesticides when used alone, a high spatial correlation of residues (not just equal decay rates), and a lack of crossresistance between the toxins. In sum, the key is that almost all individuals resistant and exposed to one pesticide must be killed by the other for mixtures to be highly effective (34,38,39) These conditions, especially a high spatial correlation of residues, are probably rarely met for sprays. For example, experiments with mixtures of Bt serotypes, applied at doses that did not provide high levels of control when used Individually, failed to delay resistance in Indianmeal moth (50). Not only is this experiment a good model for the field (where control with Bt sprays probably rarely exceeds go”/,), the results are just as would be predicted from the models outlined above, On the other hand, significant delays of resistance might be achieved with transgemc crops, where highly effective concentrations of toxin might be maintained (37-39). As an example of the problems that can result from mixtures of toxins, Bt sprays often include a mixture of specific toxins that appear to attack different bmdmg sites within the insect gut. The resistance of the diamondback moth to Bt has resulted from the use of B thuringiensis subspecieskurstukl (Btk) (4,6-$), which produces CrylA and Cry2 toxins (51). Resistanceappearsto be caused by reduced binding of the Cry 1A (and Cry1 F) toxins to the insect’s mid-gut membrane, with relatively ltttle crossresistance to toxins from other families, especially CrylC (7,23-15). Subsequent to widespread resistance to Btk, B
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thuringlenszs subspecies aizawai (Bta) was marketed. Bta produces Cry1 A, Cry lC, and Cry 1D proteins (.51), where CrylC is apparently the toxm with sufficient activity to control resistant larvae. In at least some diamondback moth populatrons, resistance to Btk appears to dechne m the absence of continuing sprays (7,16). However, given that Bta Includes CrylA toxins, it seems likely that use of Bta would maintain enough exposure to CrylA toxins to retard the decline m resistance to Btk To mvestrgate this, Btk-resistant diamondback moth larvae from Florida were divided mto four treatment groups and selected with (1) Btk, (2) Bta, (3) purified Cry1 C toxm, or (4) left unselected. When tested with 100 pg/mL CrylA(b) m leafdip assaysafter four generations of selection, the unselectedand Cry 1C selectedcolonies showed 58-70% mortality, but the Btk and Bta colonies both showed only 4% mortality. Thus, there was enough CrylA toxin in the Bta product to mamtam resistancefor Cry1 A-resistance gene(s) (52). In the field, this would eliminate the possibihty of even occasional reuse of Btk products relying on Cry IA. Mycogen Corporatron has recently developed a Cry 1C-specific product from transformed Pseudomonas, which seems to be the desirable alternative to Bta for resistance management. In general, products with shared toxins, especially for those to which resistance 1salready widespread m the targeted pests, should be avoided. 2.9. Specific vs Broad Spectrum Products All other things being equal, selective products are probably less likely than broad spectrum insecticides to select for resistance, for two ecological reasons. First, a pesticide that is so broad m spectrum that it eliminates the natural enemies or competitors of a pest will probably be sprayed more often, simply because the natural enemies are less able to suppress the pest. Second, when there are multiple pest targets for the same pesticide, applications against either pest will select for resistance to both pests simultaneously. For a hypothetical example, consider a pesticide that is effective against the Colorado potato beetle and the European corn borer in potatoes. Applications against corn borers could select for resistance in the Colorado potato beetle even when it was at such low densities that control was not required. Resistancewould be selectedm potato beetles even when there was no economic benefit to their control.
3. Resistance Monitoring Resistance monitoring can be very important for determining tf a resistance management strategy is failing and whether improvements are required. Unfortunately, resistancemonitoring efforts in the past have often failed to go beyond documenting failures and have rarely predicted failures before they occurred; momtoring will be uselessif there is not also some follow-on management!
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However, a key problem for routine momtormg efforts (m contrast to determining background frequencies, as discussed m Subheading 1.3.) for some species is the large sample sizesneeded. Hundreds or thousands of mdividuals must be tested to detect resistance at a 0.1-l% frequency at any given location before a crisis, especially where bioassays are difficult and do not neatly distinguish between susceptible and resistant genotypes (53). Given the dtfficulties of btoassays with biopesticides, and the limited knowledge of their modes of action, it seemsmost prudent to invest in highly proactive resistant management plans designed to delay resistance before it is ever detected. 4. Example of a Resistance Management Strategy: Diamondback Moth As noted before, it would be impossible to outline a general resistance management strategy for all pests and biopesticides, even Just for those described m this book. However, it seemsworthwhile for illustrative purposes to outline a strategy for just one pest, The diamondback moth is a useful example because it was the first pest to evolve resistance to a btopesticide in the field, contmues to be economically important, is widely resistant to other pesticides, and seems hkely to continue to be a target of biopesticides. Perhapsthe single most important feature of any insecticideresistancemanagement effort is a samplmg scheme that eliminates unnecessarysprays,and targets spraysonly to thoseareaswhere spraysare truly needed.To do this Mollywill require the development of alternate controls. One tactic that has been used effecttvely m Mexico (A. Shelton, personal commumcatton) and Australia is a break in crucifer crop production during oneseasonof the year, which starvesthis host specific insect. In addition, the available msecticidesm Australia have been assigned to one of two 6 mo long annual windows on the basrsof presumed patternsof crossreststance and modes of action (R. Roush, P. Buerger and S. Jones, unpublished). Bt sprays can be used m either window, but arerecommended only agamstsmall larvae early in the growth of the crop. If suitable products become available m the future, Cry I A-specific products will be used in one window and Cry IC products m the other. Growers are being urged to use insecticides that are “soft” on beneficials early m the growth of the crop, with broader spectrum pesticides toward harvest. To mmimtze the effects of persistent residues, growers are urged to destroy the crop immediately after harvest to prevent pest population growth and exposure on regrowing plants. Mixtures and high dosesare to be avoided, with growers encouraged to use application rates at the low end of those on the pesticide label. 5. Implementation Identifying an appropriate resistance management strategy is relatively easy compared to gaining adoption of the strategy, and indeed, this has been the
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most hmitmg factor to the success of resistance management efforts. Ultimately, any resistance management strategy wtll be most effective if it has the support of the private sector. The pesticide industry has established the Fungicide, Insecticide, and Herbicide Resistance Action Committees (FRAC, IRAC, and HRAC, respectively) to assist in this process. However, contrary to popular myth, it is the pesticide users, not the pestttide manufacturers, who have the most to lose when resistance evolves in those caseswhere it is such a problem that we must really be concerned with managing it. In these cases,generally only one or two pesticide options are generally available at any given time (e.g., 28). If the pesticide does not more than pay for its purchase cost in terms of improved price for the crop, the grower would be foolish to use it. On the other hand, this cost far exceeds the actual profit to a company. Thus, on a per unit basis, the cost of a lost pesticide to a grower, especially when there are few, if any, alternative pesticides, must considerably exceed the revenue lost to a pesticide company if the pesticide fails. In the case of the Colorado potato beetle, for example, resistance to all of the existmg pesticides can easily cost more than $750 per hectare (30) in the northeastern United Statesand Canada; a recently registered insecticide that provides effectively complete control is sold for less than $200 per hectare, of which probably much less than half is profit to the company. Because government scientists in some measure represent the interests of the general public and growers, the public sector thus has an obligation to address resistance issues, Both the pesticide companies and pesttcide users have strong economic incentives to manage resistance, yet resistance is still generally poorly managed. Ultimately, a stronger partnership is required between the public and prtvate sectors to assure that the promise of reststance management is fulfilled. 6. Conclusions Although resistance management is often perceived as a complex problem, the list of potential tactics 1sgenerally so short that choosing which would be useful is not difficult. Most of these tactics are also complementary and are most effective when adopted before selection commences. Thus, even though reststance management can always be improved with additional data, one should also aim to adopt a resistance management plan at the first introductton of the product. References 1. Georghiou, G. P. and Lagunes-Tejeda,A. (1991) The Occurrence of Remtance to Pesticides m Arthropods. FAO, Rome, Italy. 2. Jasienuik,M., Brule-Babel, A. L., and Morrison, I. N. (1996) The evolution and geneticsof resistancein weeds. Weed Science 44, 176-l 93.
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3. McGaughey, W. H. (1985) Insect resistance to the biological Insecticide Baczllus thurzngzensu. Science 229, 193,194 4. Tabashnik, B. E., Cushmg, N. L , Fmson, N., and Johnson, M. W (1990) Field development of resistance to Bacillus thurzngzenszs in diamondback moth (Lepidoptera: Plutelhdae) Jr Econ Entomol 83, 1671-1676 5. Hama, H., Suzuki, K., and Tanaka, H. (1992) Inheritance and stability of resistance to Bactllus thunngzensts formulations in the diamondback moth, PlutelEa xylostella (Lmnaeus) (Leprdoptera Yponomeutidae). Appl Entomol Zoo1 27,355-362 6. Shelton, A. M., Robertson, J. L , Tang, J. D , Perez, C , Ergenbrode, S D , Preisler, H K., Wtlsey, W. T., and Cooley, R J (1993) Resistance of dramondback moth (Leprdoptera. Plutelhdae) to Bactllus thurzngzenszs subspecies in the field. J Econ Entomol 86,697-705 7. Tabashnik, B E. (1994). Evolution of resistance to Bactllus thurzngzenszs. Annu Rev Entomol 39,47-79 8. Perez, C. P. and Shelton, A. M (1997) Resistance of Plutella xylostella to Bactllus thurzngtenszs Berlmer in Central America. J Econ Entomol. 90, 87-93. 9 LI, H and Lerfert, C. (1994) Development of resistance in Bottyottnta fuckelzana (de Bary) Whetzel against the brological control agent Bacillus subtzlzs CL27. Ztetschnftfur Pflanzenkrankheiten und Pflanzenschutz 101,4 14-418 10. Roush, R. T. and Daly, J. C (1990) The role ofpopulatton genetics tn resistance research and management, m Pesttcrde Reststance m Arthropods (Roush, R. T and Tabashmk, B E , eds.), Chapman and Hall, New York, pp. 97-l 52 11 Natronal Research Council, ed (1986) Pesticide resistance. strategies and tacttcs for management Natronal Academy Press, Washington, DC 12. Van Rie, J., McGaughey, W H , Johnson, D E , Barnett, B. D , and van Malaert, H. (1990) Mechanism of insect resistance to the microbial msectrctde Baczllus thurtngtensu. Science 247, 72-74 13 Fe&, J , Real, M D., Van Rie, J., Jansens, S., and Peferoen, M (1991) Resistance to the Bactllus thurtngiensts biomsectictde m a field population ofPlutella xylostella IS due to a change m a midgut membrane receptor Proc Nat1 Acad Scz USA 88,5119-5123 14 Tang, J D , Shelton, A M , Van Rie, J., De Roeck, S , Moar, W J., Roush, R T , and Peferoen, M. (1996) Toxlcrty of Baczllus thurzngzenszs spore and crystal protein to the resistant diamondback moth (Plutella xylsotella). Appl Envtron. Mtcrobrol. 62,564-569. 15. Tabashnrk, B. E., Lm, Y.-B., Fmson, N., Masson, L , and Heckel, D G. (1997) One gene m diamondback moth confers resistance to four Bactllus thurtngtensrs toxins Proc Nat1 Acad Sci. USA 94, 1640-644. 16. Tang, J. D., Grlboa, S., Roush, R T., and Shelton, A. M (1997) Inheritance, stability, and fitness of resistance to Bactllus thurzngtensu in a field colony of Plutella xylostella (L.) (Lepidoptera. Plutelhdae) from Florida. J Econ Entomol 90,732-741 17 Briese, D T. (198 1) Resistance of insect species to mtcrobial pathogens, m Pathogenesis of Invertebrate Mtcrobtal Diseases (Davidson, E. W., ed.), AllanheldOsmun, Totowa, NJ, pp 5 1 l-545
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18 Ignoffo, C M., Huettel, M. D., McIntosh, A. H., Garcia, C , and Wtlkenmg, P (1985) Genetics of resistance of Helzothzs subfexa (Lepidoptera. Noctuidae) to Baculovwus hellothis. Ann. Entomol Sot. Amer 78,468-473 19 Helle, W (1965) Resistance in the Acarina: mites. Adv Acarol. 2, 71-93. 20. Sanderson, J. P. and Roush, R. T (1995) Management of insecticide resistance m the greenhouse, m Proceedmgs of the I1 th Conference on Insect and Disease Management on Ornamentals (Bishop, A., Hausbeck, M , and Lmdqurst, R , eds.), Society of American Florists, Alexandria, VA, pp. 23-36. 21 Tabashmk, B E. and Croft, B. A. (1985) Evolutron of pesticide resistance in apple pests and their natural enemies. Entomophaga 30,37-49 22 Roush, R. T and Croft, B A. (1986) Experimental population genetics and ecological studres of pestictde resistance m msects and mites, in Pestrclde Reswtance Strategies and Tactics for Management (National Research Council, ed.), National Academy Press, Washington, DC, pp 257-270 23 McDonald, P T., Schmidt, C. D., Fisher, W. F , and Knuz, S. E. (1987) Survival of permethrin susceptible, resistant and Fl hybrid strains of Haematobia rrrltans (Diptera* Muscidae) on ear-tagged steers J Econ Entomol 80, 1218-1222. 24 Roush, R. T , Combs, R L , Randolph, T C., MacDonald, J , and Hawkms, J A (1986) Inheritance and effective dominance of pyrethroid resistance m the horn fly (Diptera: Muscidae) J Econ Entomol 79, 1178-l 182. 25. Rotteveel, T. J. W., de GoeiJ, J W F. M , and van Gemerden, A F. (1997) Towards the construction of a resistance risk evaluation scheme Pestzc Scz 51,407-411. 26 Roush, R. T. and McKenzie, J A (1987) Ecological genetics of insecticide and acaricide resistance Ann Rev Entomol 32,361-380. 27 Gould, F , Anderson, A., Jones, A, Sumerford, D., Heckel, D. G., Lopez, J , Micmski, S , Leonard, R , and Laster, M (1997) Initial frequency of alleles for resistance to Bacillus thuruzgzenszs toxins in field populations of Helzothzs vu-escens. Proc Natl Acad. Sci USA 94,3519-3523. 28. Brent, K. J. (1995) Fungicide Resistance in Crop Pathogens How Can It Be Managed7 Fungicide Resistance Action Commitee Monograph No 1, GIFAP (International Group of National Associations of Manufacturers of Agrochemical Products), Brussels 29. Tabashmk, B E (1997) Seeking the root of insect resistance to transgenic plants. Proc Nat1 Acad Sci USA 94,3488-3490. 30 Roush, R T. and Tingey, W. M. (1992) Evolution and management of resistance in the Colorado potato beetle, Leptmotarsa decemllneata, m Resistance ‘91 Achievements and Developments in Combating Pestzczde Resutance (Denholm, I., Devonshire, A. L , and Holloman, D. W , eds.), Elsevier Applied Science, Essex, UK, pp. 61-74 31 Roush, R T., Hoy, C W , Ferro, D. N., and Tingey, W. M (1990) Insectrcide resistance m the Colorado potato beetle (Coleoptera. Chrysomebdae). Influence of crop rotation and insecticide use. J Econ Entomol 83,3 15-3 19.
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32 Brown, A W A. (1967) Insectrctde resrstance-genetrc implicattons and apphcatrans. World Rev Pest Control 6, 104-I 14. 33 Denholm, I , Farnham, A W , O’Dell, K , and Sawicki, R. M. (1983) Factors affecting resistance to msecttcrdes m house-fhes, Musca domestzca L (Dtptera Musctdae) I. Long-term control wrth bioresmethrm of fltes with strong pyrethrotd-resrstance potential. Bull. Entomol Res. 73,48 l-489. 34 Roush, R T. (1989) Destgnmg resistance management programs* How can you choose? Pesttc Scz 26,423441. 35 Schroeder, H. E , Gollasch, S., Moore, A., Tabe, L M , Cratg, S , Hardte, D C , Chrrspeels, M. J., Spencer, D., and Hrggms, T J V (1995) Bean alpha-amylase mhtbttor confers resistance to the pea weevil (Bruchus puorum) m transgenic peas (Ptsum sativum L ) Plant Physiology 107, 1233-1239 36 Gould, F (1998) Sustamabtlrty of transgemc msectictdal culttvars. mtegratmg pest genettcs and ecology. Annu Rev Entomol 43,701-726 37 Roush, R, T (1994) Managmg pests and their resistance to Baczllus thunngzensu Can transgemc crops be better than sprays? Bzocontrol Set Technol 4,501-5 16 38 Roush, R. T. (1997) Managing resistance to transgemc crops, m Advances zn Insect Control The Role of Transgentc Plants (Carozzi, N , and Koziel, M , eds ), Taylor and Francis, London, pp. 271-294. 39 Roush, R T (1997) Bt-transgemc crops: Just another pretty msectrctde or a chance for a new start in resistance management7 Pesttc Set 51, 328-334 40 Tabashmk, B E and Croft, B A. (1982) Managing pesttctde resistance in croparthropod complexes Interactions between brologtcal and operatronal factors Envrron Entomol 11, 1137-l 144. 41 Denholm, I. and Rowland, M W. (1992) Tactics for managing pesttcrde reststance m arthropods. theory and practice Ann Rev. Entomol 37,91-l 12 42 Daly, J., Fisk, J. H., and Forrester, N W. (1988) Selective mortality m field trials between strams of Helzothzs armzgera (Lepidoptera. Noctuidae) resistant and susceptible to pyrethroids functronal dominance of resistance and age class J Econ Entomol. 81, 1000-1007. 43 Metz, T. D , Roush, R T , Tang, J D , Shelton, A M., and Earle, E D (1995) Transgemc broccoli expressing a Bacillus thurzngtenszs msecticrdal crystal protein. tmplrcattons for pest reststance management strategies. Molecular Breeding 1,309-3 17. 44 Forrester, N W., Cahrll, M , Bird, L. J., and Layland, J. K. (1993) Management of pyrethroid and endosulfan resistance in Heltcoverpa armtgera (Leprdoptera. Noctutdae) m Austraha. Bull Entomol Res Suppl 1. 45 Roush, R T (1993) Occurrence, genetics and management of msectrcide reststance. Parasttology Today 9, 174-179. 46. Curtts, C. F (1987) Genetic aspects of selection for resistance, in Combatrng Resistance to Xenobzotzcs (Ford, M G , Holloman, D W., Khambay, B P S , and Sawtcki, R. M , eds.), Elhs Hot-wood, Chichester, UK, pp 15 1-16 I 47 Tabashmk, B. E (1989) Managmg resistance wrth multtple pestrctde tactrcs theory, evidence, and recommendations. J Econ Entomol 82, 1263-1269
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48 Immaraju, J A., Morse, J G., and Hobza, R. F. (1990) Fteld evaluatton of msectrcide rotatton and mixtures as strategies for citrus thrlps (Thysanoptera Thrtptdae) resistance management in California. J Econ Entomol 83,306-3 14 49. Gould, F (1986) Srmulatton models for predtcting durabilny of Insect-resrstant germplasm a determnustrc drplotd, two locus model. Envu-on Entomol. 15, l-10 50. McGaughey, W. H. and Johnson, D. E. (1987) Toxtctty of different serotypes and toxins of Bacillus thurlngzensrs to resistant and susceptible Indtanmeal moth (Leptdoptera: Pyrahdae). J Econ Entomol 80, 1122-1126. 51 Kozrel, M G , Carozzr, N B., Currier, T. C , Warren, G. W , and Evola, S V (1993) The msectictdal crystal protein of Bacillus thunngzensx past, present, and future uses. Bzotechnol Genet Eng Rev 11, 171-228. 52. Tang, J D , Shelton, A M., Roush, R. T., and Moar, W. J. (1995) Consequences of shared toxins m strains of Bacillus thurzngiensu for resistance m dtamondback moth Pestlclde Resistance Management Newsletter 7(l), 5-7 (also on World Wide Web at http.//www msstate.edu/Entomology/vln Us95rpm html#art03) 53 Roush, R. T. and Miller, G L (1986) Constderattons for destgn of msecttctde resistance momtoring programs J Econ Entomol 79, 293-298.
31 Field Management Delivery of New Technologies to Growers Mark E. Whalon and Deborah L. Norris 1. Introduction Since ancient times, man has recognized and utilized biological agents for pest control (I). Modern agriculture has built on this foundation of indigenous knowledge to explore and advance the use of novel methods of biological control of insect pests. In the past 30 yr, biotechnological innovation, including natural product chemistry, fermentation, and genetic engineering, has led to the development of many revolutionary products that have fundamentally changed the way humans manage pest-control agents. The use of chemicals in arthropod control can now be divided into two categories: conventional chemical insecticides and bioinsecticides. Furthermore, the definition of bioinsecticides has expanded to include the use of genes and gene products, microbes or products derived from microbes, plants, and other biological entities. The development of recombinant DNA technology and other factors, e.g., concerns over the environmental and health risks of conventional chemicals, the development of resistance to existing chemicals, and a growing interest in IPM has accelerated research interest in biopesticides as chemical-pesticide alternatives. Growers today find ever-increasing bioinsecticide products available to them, from conventional spray deployment of Bacillus thuringiensis (Bt) to insect-specific viruses, sprayable pheromones, and transgenic plants with insecticidal genes incorporated into plant tissue. However, biopesticide development and utilization has many challenges today (2). The US Environmental Protection Agency (EPA) has officially defined a biopesticide as belonging to one of three groups: biochemical pesticides, microbial pesticides, or transgenic plant pesticides (3). Biochemical pesticides From: Methods in Biotechnology, vol. 5: Biopesticides: Use and Delivery Edited by: F. Ft. Hall and J. J. Menn 0 Humana Press Inc., Totowa, NJ
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include pheromones, hormones, natural Insect- and plant-growth regulators, repellents, and enzymes as active ingredients. Microbial pesticides include microorgamsms (bacteria, fungi, and viruses) and then products, usually proteins, as active ingredient (4). Becauseof growing consumer food-safety awareness and demands for less-toxic substitutes for conventional chemical pesticides, there has been a commitment on the part of the EPA to facilitate registration and bring these new products to market. By redefining biopesttctdes as a separate class of control agents, the EPA has been able to revise the registration requirements for these compounds, most of which now have fewer data requirements for registration than conventional broad-spectrum chemical pesticides. By promotmg a more rapid path to market, the EPA has helped encourage the agrochemical and biotechnology industries to spend more time and resources m the development of new btomsecticides and related technologies. Implementation of these new technologies will require an mterdtsciplmary approach to pest management and Increased grower access to information on use and deployment. The goal of this chapter is to discuss some of the challenges to the ecologically sound implementation and adoption of biopesticides, challenges that the authors believe can only be overcome through changes m the structural and phrlosophical aspects of agrrcultural production, mcludmg the consideration of the mtrmsic value of our natural and ecological resources, when making pest-management decisions. 2. Why Have Growers Been Slow to Adopt Bioinsecticides? Despite the benefits of many new mnovattons, a considerable time lag is generally required before an innovation receives widespread acceptance (5). Cultural and social values sometimes play a role m grower dectsion-making, and consumer fears of microbial agents can also be a barrier to the acceptance of new technologies, especially those related to food products (6) More importantly, economic feasibihty and product performance play a large role m the adoption of new technologies by growers. Btopesticides usually do not perform as effecttvely and/or as quickly as synthetic chemical pesttcides. In addtnon, many requtre a higher level of management skill and knowledge than do conventional chemicals (7,s). These and other factors, such as target-pest spectrum, crop value, and production and operational challenges, can affect the adoptton and field management of btomsecticide technologies. In addition, tt is not likely that biopesticides will replace conventional pesticides in the nearterm, but they are already being broadly accepted in IPM programs. 2.1. The Case of Transgenic Plants For the past decade, the development and commercialization of msect-resistant transgenic plants has focused almost exclusively on transferring toxin
he/d Management genes from Bt to crop plants (9). Bt 1s a common so11 bacteria that produces many different crystal toxins that are selective against specific pest species. Bt sprays, which have been used commercially in the United States since 1958 (IO), have several advantages over synthetic insecticides, including httle or no Impact on nontarget and beneficial organisms, low environmental persistence because of rapid degradation, and little or no known toxic effects against humans and other animals. From the growers’ perspective, however, some of these benefits actually make Bt less attractrve as an alternative control tactic. For example, insect specificity makes Bt less competrtive with many broad-spectrum synthetics, and rapid degradation increases grower input requirements m the form of repeated applications and greater management of timmg and location of sprays to achieve comparable results. These drawbacks are rllustrattve of the potential problems with most bropesticides, which exhibtt selective rather than broadspectrum activity. Transgenic Bt technology aims to overcome some of these delivery barriers by engineering crop plants to express high levels of Bt toxin(s) within plant tissues continuously throughout the growing season, thus eliminating the burden of spatial and temporal management of apphcatrons.
3. Feasibility of Biopesticide Acceptance The economic feasibility of bropesticide acceptance IS determined by many factors, all of which can contribute to the eventual adoption or rejection of new technologies by growers. As summanzed by Reichelderfer (II), these factors include. 1. Economic incentive: The net gain from the use of a bropesticide must equal or exceed the gain that the grower would recerve from conventronal pest-control tactrcs (chemicals) 2 Efficacy: Given equal costs, broinsecticldes must be as effective as the chemrcal they would replace. As efficacy of bioinsecticides increases, economrc feasibllrty wrll increase. 3. Pest spectrum: Pest specificity can be an advantage of bioinsecticrdes in smglespecres outbreaks, but, m many cases, growers are faced with the challenge of elrmmatmg several pests at once When a srmultaneous outbreak of several pests occurs, there IS little justrficatron m using a species-specific broinsectrcrde, If several broad-spectrum chemical alternatives are avarlable Therefore, the development of some broad-spectrum biomsectrctdes or mrxtures, to compete with then synthetic chemical predecessors, can increase the economic feaslbrlity of those products. 4. Crop price As crop value increases, there is greater interest m using rapid, rehable, and effective pest-control measures. This is achieved most frequently through the use of chemical treatments that are already familiar to the grower Growers are less hkely to use a more expensive and more specific bioinsecticide, unless its performance IS better than Its conventional chemical counterpart or
Whalon and Norris
598
other incentives of reduced residues, pest resistance, consumer acceptance, or loss of conventional-control chemicals 5 Price of blopestlclde. The lower the market price of a blopestlclde, the more economically feasible it IS to the user However, if a blopestlclde product offers other relative advantages, such as low human and environmental toxlclty, and consumer or regulatory pressures like the passage of the 1996 US Food Quahty Protection Act (FQPA) make its use more attractive, then a htgher price may be more readily accepted by growers 6 Varlabllity of performance. Users prefer consistency and rehablllty m the pestcontrol methods they choose, therefore, economic feaslblllty will increase as blomsecticldes become more consistent m their field performance 7. User costs Growers factor m costs other than the market price of a product when they are making pest-management choices The costs associated with time, labor, and management, when usmg a new technique or product, can increase the overall cost to the user and make the product less economically feasible Many growers ~111 continue to use conventional chemical tools if they beheve that the additional costs associated with using a bioinsectlcide, Including transgemc seed license fees, scouting, timing, multiple apphcatlons, and so on, will outwelgh the potential benefits.
4. Implementation 4.1. Biopesticides
Issues vs Conventional
Systems
Biopestlclde products function within a narrow host-target range, which, although advantageous for preserving the ecological balance of nontarget and beneficial insects, is nonetheless disadvantageous to the grower during multlple-pest outbreaks. Conventional systems usually provide greater broad-range control, but, as a result, have more negative effects on nontarget and beneficial populations. In addition, conventional systems often preclude an understandmg of other factors m pest management, espectally pest biology, insect behavior, agroecology, and mode of action, because of their broad-spectrum activity and multiple mechanisms of toxlclty (fumigant, contact, systemic, and per OS) With the exception of a few contact bloinsectlcldes like Beauveria basszana, the use of species-specific, noncontact, ingestible blomsecticldes has created a need for greater understandmg of the complete pest complex, includmg mul-
tiple insect mteractlons and behavior. To illustrate this point, consider the mtroductlon of tebufenozlde, an insect-growth regulator (IGR) for lepidoptera control in apples This product has not performed as well as expected in mldwest apple pest control, even though it utilizes a novel mode of actlon and
may cn-cumvent organophosphate msectlclde resistance m target leafrollers. In the case of organophosphate, carbamate, and synthetic pyrethrold products, failure in the field has often been associated with application
problems,
timing,
or resistance in the target population. In the case of this narrow-spectrum TGR,
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599
leafroller biology, ecology, and behavior are more tmportant contrtbutmg factors to field failure. For example, behavioral avoidance, whereby early-season larvae move their feedmg to newly emerging leaves, avoiding mgestion of the IGR, has led to recent product failures. Since the effectiveness of many IGRs require mgestion of a treated plant part, a behavioral characteristic, such as feedmg preference for new-growth plant tissues or product detectton, may result in an effective avotdance to exposure. Thus, the use of this product challenges pest managers to rethmk then approach to management by mcluding better momtormg, more knowledge of pest behavior and host-plant mteractions, preservation of beneticials, as well as a change m the acceptable damage thresholds and treatment frequency. Tables 1 and 2 compare some of the fielduse considerations for several types of conventional pesticides and biopestictdes.
4.2. Will an Era of Biopesticides Replace the Age of Synthetic Pesticides? Since the mtroduction of DDT and the advent of the chemical age m agrtculture in the 194Os,pest control has been primarily dependent on insect neurotoxins that are broad-spectrum, fast-acting, active by contact, and persistent (Table 1). These characteristics, along with low cost and relative ease of apphcation, have provided positive economic feedback through effective, simple control. Meanwhile, however, a second system of negative feedback has been moving m the opposite direction to counteract the positive effects of conventional insecticide use (Fig. 1). Negative feedback (externalities) has developed relatively unchecked, in part because of the necessary lag time between the mtroduction of an innovation (i e., chemical pesticides) and the development or evidence of these negative impacts. The fact that optimal use of insect neurotoxins has traditionally been assessedin purely economic (production) terms has further hindered the ability to detect long-term, noneconomtc, negative feedbacks. The cycle of negative feedbacks includes environmental impacts, ecological impacts, lack of sustainability, pest resistance, human health impacts, trade issues, regulatory burdens, and consumer concerns (Fig. 1). Many of these factors are often ignored m traditional cost-benefit analyses, because of difficulties in quanttfying or assessingtheir value (12). In the United States, under FQPA codificatton, many conventtonal pesticides, nerve toxms, and B-l and B-Z carcinogens will dramatically decrease, especially on minor crops (fruits, nuts, vegetables, and ornamentals). A pestmanagement system dependent on biopesticides is likely to evolve in the very near future, especially m these minor crops. These systems will have to be supported with better monitoring, as with apple leafroller control with tebufenozide. Newly developed pest- and natural enemy mteraction thresholds (I.?), similar to those developed for predaceous mites m deciduous fruits (14),
Low Moderate
Low
Chlormated hydrocarbons Synthettc pyrethrotds
011
Low
Low
(OPs)
Attentton to application
Precision and timing requnement
Chemical
Low-moderate
Low Low-moderate
Low-moderate
Low-moderate
for Conventional
Carbamates
Organophosphates
Compound
Table 1 Field Use Considerations
Usually not
No No
Usually not
Usually not
Thresholds necessary?
Insecticides
Vanable low-htgh
Little Little
Some
Some
Phytotoxictty
Wash off, volatrhty Wash off, volatihty Less than OPs Temperature inversion Wash off
Weather effects
High; short- to medium-term Hugh; long-term High; short- to long-term High
High, short-term
Environmental and ecologtcal tmpact
2
High Moderate-htgh Refugta
High Low-moderate Moderatehtgh High
Compound
Pheromone Bt sprays Transgemcs
Spinosad Nicotmyl compounds Avermectm Tebufenozide Fenoxycarb
High Low-moderate Moderate Htgh
Low-moderate High None
Prectsion and timing requirement
for Biopesticides
Attention to application
Table 2 Field Use Considerations
Sometimes Sometrmes Somettmes Yes
No Usually No
Thresholds necessary7
None Non+low None None-low
None Low None
Phytotoxicity
Moderate Moderate Low-moderate Htgh
Hrgh Hrgh Some
Weather effects
None+? Some Moderatehigh (gene transfer, resistance) Some Some Some Some
Envnonmental and ecological impact
602
Whalon and Norris
Envtronmental impacts EcologIcal impacts Non-renewable use of resources Resistance Human health Impacts Consumer concerns
Broad-range control Persistence Multiple modes of
Greater management requlrementslcosts Greater technical expertise needed lnitlally Reassessment of acceptable damage levels Resistance If mismanaged Loss of susceptible genes if mismanaged
resources Less Impact on beneficlals Less envlronmental
Renewable Potentially
Fig 1. Integrated production
system low cost
feedback mechanisms
will be very useful. In addition,
for conventional
and blomtenslve
better weather forecastmg, and even microcli-
mate monitormg, will significantly improve reapphcation decisions where washoff and heat-moisture weathering are problematic to blopestlclde performance. A pest-management approach dependent primarily on blopesticides 1s likely to involve
a new set of negative externahtles,
but these are likely
to be longer-
term and of lower intensity than conventional chemical pesticides The eco-
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603
logical, environmental, and human health advantages Inherent m biopesticide systems will eventually be challenged by these negative feedback factors, some of which we cannot yet fully predict or identify (Table 2). In the short term, the most important factors are likely to be the technical, educational, and cost barriers that could adversely affect a grower’s choice to implement brologically intensive IPM, but under FQPA most minor-use producers will not have a choice. These barriers mclude the challenge of balancing kill rates and damage levels with fluctuations in pest populations, the knowledge requirements for understanding the biological and ecological mteracttons of the insect-crop complex, and the technical and managerial expertise needed to run the system effectively, These factors affect economic feasibihty and net dollar returns that ultimately dictate the extent to which the grower IS willmg or economically able to adopt a new control paradigm, especially a more biologically intensive program. 4.3. Avoiding
the New Biopesticide
In conventional
chemical
Treadmill
systems, producers
catastrophically
eliminated
many species,greatly simplifying biological diversity and interactions (2627). These simplified systems often undergo crisis when a new pest is mtroduced, because resistance occurs or secondary pests rebound. Biopesticide pest-management systems may also be at risk of failure because of then- increased reltante on system mteractions, and ultimately on the systems’ total genetic resources (plant genes, pest genes, beneficial insect genes, bacterial and virus genes, and so on). Of great concern is the potential for resistance and loss of genes that confer susceptibility
in pest populations
Figure
1 illustrates
the
potential complexity of the biointensive pest-management feedback systems. A short-sighted approach to biopestrcide use could easily disrupt the finer balance necessary for this system’s ecological stability, and the ensumg economic consequences will be Just as significant as with conventional pestmanagement systems. The study reported by Trumble et al. (28) IS an example of a biopesticide pest-management system m a minor crop. It compared the economic and environmental
impact of a Bt-based IPM program with the current standard chemi-
cal program m California celery production. The program utilized scoutmg of both pests and natural enemies (parasites) to implement
a system of threshold-
driven msecticide applications, which reduced Inputs and provided protection of the natural parasites. The IPM materials (Bt and abamectin) were chosen based on thetr control potential of the target pests (mainly Spodoptera exigua), balanced with minimal disruption of natural parasites. Both the conventional and btopesticide program was evaluated for yield, crop value, and cost of control. Although
the economic
evaluation
did not take mto account hidden costs
604
Whalon and Norris
and externalities, such as ecological and environmental effects, the researchers did separately evaluate the potential for air pollution of both programs, to compare the environmental benefits of biopesticide vs the conventional chemical standard. Their results indicated that the biopesticide program achieved a net profit of $4 1O-l 485/ha greater than the standard conventional program m three trials over 3 yr. These researchers recognized that the benefits of the biopesticide program went far beyond net monetary profit, and included decreased negative human health effects, decreased environmental impacts, and the primary advantage of decreased pest resistance in the short-term. As a single strategy in a one-crop system, thts IPM approach adheres to many of the prmciples of a more durable production paradigm (28). The system utihzes multidisciplmary information to select which compounds to apply, and when to apply them, taking mto consideration both pest and nonpest toxtctties, population dynamics, envnonmental concerns, and newly developed damage thresholds. Thrs approach is proactive and preventive (e.g., scoutmg and allowing natural enemies to control the pest before resorting to treatment), rather than based on a standardized treatment regime. The described program is also likely to preserve genetic resources (susceptible genes, nontarget organisms), and reduce risks to humans and other mammals. It should be noted, however, that the use of a smgle bioinsecticide with scoutmg is insufficient for long-term prevention of pest outbreaks. Trumble et al. (17) suggest that alternative strategies could be equally viable. Crop rotation, ground-cover management (for orchards), and strip cropping are key strategies m this process. 5. Agricultural Research and Field Management: Role in IPM We have mentioned some of the drivmg forces m the transition to renewable production practices This transition will require a more information- and education-intensive commitment on behalf of industry, regulatory agencies, landgrant umversmes, and producers. The implementation of a truly integrated, durable system will demand an interdisciplinary approach, with more elastic and targeted field research that will probably require more producer input. Government agricultural and environmental agencies could help direct thts shift by priorittzing funding for appropriate science, i.e., problem-driven research that addresses basic agricultural and ecological problems associated with btomtenstve productron. Although prevention-oriented pest management may not be the marketing strategy of most biomsectictde companies, some companies do take an active role m educating growers and the public on the use of their products and new technologies. Amertcan Cyanamid (Parsippany, NJ) has created citizens’ advisory panels, composed of local cttizens, environmental groups, university extension personnel, growers, and other stakeholders, in areas where they are
Field Management running field trials on biopesttcides, e.g., on recombinant baculoviruses for insect control. These panels of approx 1540 people observe and assessthe trial programs, and then have opportunities to ask questions and discuss concerns with company representatives. The company also has a targeted technology public relations program that works with some environmental groups to educate, inform, and create public dialog on its recombinant baculovnus technologies. Even in the face of sometimes violent opposition to biotechnology products, their open, consumer-Informed education and labelmg programs have been successful. These types of industry-academic-citizen-group partnerships help foster a more open and dynamic envn-onment for creating change and tmplementmg new biotechnologies, especially technologies that may engender fear m the public. 5.1. Role of Industry, Government, and Academia in Bringing New Biotechnologies to the Field Because proper use of biopesticrdes often requires different kmds of mformation and actions that are new to the grower, performance expectations may not be met, and many growers will return to the use of quick-acting pesticides, if available. Manufacturers and/or registrants of biopesticides and the university extension service, therefore, must educate growers on the proper use of btopesticides in order to bring expectations in line with reality. Informatton and trainmg on timmg and placement is critical, since these factors are paramount m achieving high-efficacy biopesticide performance. In general, companies need to provide more technical support for bioinsecticrdes than conventional synthetics-a necessaryinvestment if they hope to maintain longterm grower interest m then products (18). Benbrook et al. (19) proposed a framework for accelerating progress toward implementation of a biomtenstve IPM programs, which requires a structural foundation in ecology. These control programs would exploit natural and augmentattve biological control and build on an emerging cadre of private sector biological control companies. The first step in achieving this 1sto develop rigorous methodologies for measuring pesticide use and risks for individual crops, both regionally and nationally. Without the establishment of an initial usage baseline, specific changes in pesticide use cannot be effectively measured. Additionally, comparative data is lacking on the performance and cost-effectiveness of biointenstve IPM systemsvs conventional systems.Documentation and monitoring of biointensive programs that currently exist could help in setting future goals for the transition to IPM and use of biologically based cropprotection tools. Quality control, standardization, and an industry-based enforcement mechanism for btological control supply houses are also critical in this transition.
606
Whalon and Norris
Changes in government mfrastructure are also needed, such as re-evaluation of agricultural policies and public funding priorities that promote reliance on conventional chemicals. Currently, the USDA spends approx I2 7% of its total pest-management funding support on btointenstve IPM research (20). A shift m fundmg priorities and an emphasis on researchmg plant-Insect mteractions, ecology, plant transduction and signaling, biopesticide/natural enemy thresholds, and btodiversity are necessary changes m the public-sector research agenda. Likewise, umversities must reprioritize their research agendas to promote more on-farm, producer-assisted research, and increase access to mformatton via databases of pest and pesticide-alternative mformation, field diagnosttc tools, and internet resources. This approach to date has been largely ineffectual, because deciston-support systems,databases,and electronic mformation networks have failed to reach the producers, or address theu needs A good example of the use of a database that helped define research priorities is the PesticidesAt Risk (PAR) program at Mtchigan State University. The database is designed to identify and assessthe risk of loss of various pesticides because of industry withdrawal, reregulation, environmental and consumer concerns, and the 1996 FQPA, and to identify the crops that will be affected if these pesticides are removed from the market. The loss risk ratmg assigned to the pesticides has been used to direct agricultural research funding priorities. Thus, m the United States,the loss of key conventional pesticides used for specialty crops is driving the research agenda in the directton of alternative pest-management techniques that can replace these pesticides when they are removed from the market. The PAR process is illustrative of how new regulations can create a force for transition toward more biointensive IPM research and practices. Other mformation-based delivery systemsare uttlizmg data transfer networks that producers can subscribe to, or real-time weather and biological interface software systemsthat provide on-site predictions of pest development and progress. 6. Conclusion In the past, products that exhibited less-than-optimal performance, poor product support packages, and lack of economic mcentives, compared to conventional chemical pesticides, have limited the adoption of new biopesticides by growers. Advances in biopesticide technology are now increasing the availability of more efficacious and reliable biologically based insecticides In the United States, the EPA has implemented policy changes for bioinsectmides that have facilitated and streamlined registration. With biopesticides, pest managers now have the emerging tools to allow current agricultural production tools to be more environmentally friendly and establish potentially durable pest-control systems. The challenge involved m transition from conventional synthetic pesticides is twofold. Changes are
Field Management
607
required m the structure and function of agricultural researchand Implementation at the local, private, and public levels, both nationally and mternatlonally; and subsequentadoption of a more biologlcally mtenslve understanding of agriculture production by producers is necessary.The structural changes should involve, m part, refocusing public institutional researchandimplementation priorities to target longterm integration of biologically intensive pest-suppreswonstrategtesand resistance management.The biologically Intensive changesinvolve a commitment to the prmclples of ecological management and more durable production systems,i.e., creating an agricultural production system that utilizes a comprehensive blologlcal systemsapproach to problem-solving in production, pest management, and marketing; emphasizesecologically sound and equitable infrastructures; and places an appropriate economic valuation on the agroecosystem’snatural capital, including predators, parasites,pest-damageinduced-nnmunity, diseasehypersensltlvlty, and so on. More research m the field of ecological economics would also help assess and define the intrinsic value of natural resourcesand dependenceon the underlymg genesthat confer susceptiblegenesm target-pest populations. This will lead to amore thorough and enhghtened economic analysesof agricultural production and better use of biopestlcldes. Somecomparative studiesof blologlcally intensive IPM programs vs standard chemical production have already demonstrated the transaction level economic advantagesin utilizing blopestlcides, yet the intrinsic ecologlcal advantages of these systemshave not yet been addressed. Ultimately, the transition to blologlcally intensive field management, including biopesticides, will be market-driven, with industry, academia, government, growers, environmentalists, and consumers sharing m the process. Growers and biotechnology-based companies will have more incentives to switch to biological products and approaches, as consumer demands and the regulatory environment dictate The US FQPA of 1996 has already been a catalyst for transition in the Umted States. Policymakers and government regulatory agencies can facilitate this process by relaxing market quality standards that currently dictate chemically intensive production. Several private sector companies, including many start-up biotechnology companies, find it more economically feasible to pursue the development of biopestlcides, rather than deal with the regulatory resistance and consumer burdens on registration of conventlonal chemicals Finally, the development of better timing tools (electronic, biologically tlmed, Information delivery systems), critical agroecosystem-based treatment thresholds, and on-farm evaluations are likely to accelerate and facilitate adoption of these tools. References 1. Jacobson,M. (1988) Botanical pesticidespast,present,andfuture, m Znsectmdes ofPlant Orzgzn (Amason,J. T., Philgkne,B J R., and Morand, P , eds.),Amencan Chemistry SocietySymposiumSeries387, pp. I-10
2 Gaugler, R. (1997) AlternatIve paradigms for commerclahzmg biopestlcldes Phytoparasztzca 25, 3. 3 Code of US Federal Register 40 parts 152, 174, and Plant Pesticides Supplemental Notlce 180 4 McClmtock, J. T , Kough, J L , and SJoblad, R D. (1994) Regulatory oversIght of biochemical pestlcldes by the U. S. EnvIronmental Protection Agency health effects conslderatlons. Regul Tox Pharmacol 19, 115-124 5 Rogers, E M (1962) Dzfiszon ofhznovatzons Colher-Macmillan, Toronto, Canada. 6 Remecke, P. (1990) Biological control products. demands of industry for successful development, m Pestzczdes and Alternatzves Innovatzve Chemzcal and Bzologzcal Approaches to Pest Control (Caslda, J. E , ed.), Elsevler, New York, pp 99-108 7 Carlson, G A (1988) Economics of biological control of pests. Am J Alternatzve Agrzc 3, 110-116 8 Hollander, A K., Wood, H A , and Evans, F (1991) Blopestlcldes (workshop report), m Bzotechnology and Sustaznable Agriculture Polzcy Alternatzves National Agriculture Biotechnology Center Report 1 (MacDonald, J F., ed ), National Agriculture Biotechnology Center, Ithaca, NY, pp. 14-20. 9 James, C and Krattiger, A. F. (1996) Global review of the field testing and commercializatlon of transgenic plants, 1986-1995. the first decade of crop blotechnology ISAAA Brzefi No 1, Ithaca, NY. 10 Andrews, R E , Faust, R M , Wablko, H , Raymond, K. C., and Bulla, L A. (1987) The biotechnology of Baczllus thurzngzenszs.CRC Crzt Rev. Bzotechnol 6, 163-232, 11 Relchelderfer, K H ( 1989) Economic aspects of biopestlcldes, m Bzotechnology and Sustaznable Agrzculture Polzcy Alternatives. National Agriculture Blotechnology Center Report 1 (MacDonald, J. F., ed.), Natlonal Agriculture Blotechnology Center, Ithaca, NY, pp. 82-89. 12 Bowles, R. G. and Webster, J. P. G. (1995) Some problems associated with the analysis of the costs and benefits of pesticides. Crop Protect. 14, 593-600 13. Brown, G. C (1997) Simple models of natural enemy action and economic thrcsholds Am Entomol. 43, 117-124. 14 Croft, B. A. (1975) Integrated control of apple mites Mlchlgan State Umverslty Cooperative Extension Services Extension Bulletin E-825 15. Stnckler, K., Cushmg, N , Whalon, M , and Croft, B A (1987) Mite (Acan) species composltlon m Mlchlgan apple orchards. Envzron Entomol 16, 30-36 16. Stickler, K and Whalon, M (1985) Microlepidoptera species composltlon In Mlchlgan apple orchards Environ Entomol 14,486-495 17 Trumble, J. T., Carson, W. G., and Kund, G. S (1997) Economics and envlronmental impact of a sustainable integrated pest management program m celery J Econ. Entomol. 90, 139-146 18 Dahlberg, K A (1993) Government polictes that encourage pestlclde use m the United States, in The Pesticzde Question Envzronment, Economzcs, and Ethics (Pimentel, D. and Lehman, H , eds.), Chapman and Hall, New York, pp 28 l-306 19 Knmsky, S and Wrubel, R P. (1996) Agrzcultural Bzotechnology and the Environment Sczence,Polzcy, and SoczaZIssues Unlverslty of Illmols Press, Urbana and Chlcago. 20 Benbrook, C M., Groth, E , Halloran, J M., Hansen, M K., and Marquardt, S (1996) Pest Management at the Crossroads. Consumers Umon, Yonkers, NY
Index A
Anticarsia gemmatalis, 5 Anticarsia gemmatalis NPV, 3 16 Antifeedant bioassays, 143, 144 Aphids, 32, 165 Apic, 159 Apochemia cineraius, 223 Application equipment biopesticide product development, 515-517 AQlO, 2, 3,97 disease incidence, 86-89 spray applications, 92-95 AQ 10 development, 82-95 field trials, 83-91 assessment, 85-91 Arizona Cotton Research and Protection Council pink bollworm, 39 1 Army worm, 164 Arthropod viruses, 34 1 Article 130 A Europe registration requirements biopesticides, 454,455 ASPIRE, 96 A-terthienyl, 147 Augmentative biocontrol, 37 1 Australia, 159, 160, 218 Autographa californica nucleopolyhedroviruses, 40, 3 16, 322-336 Avermectins, 3 Azadirachta indica, 156 Azadirachtin, 146, 155 adjuvants, 163-l 66 formulation effects, 161-163
A. quisqualis, 82, 83 Abamectin, 3 AcJHE.KK, 347 AcMNPV, 3 16 recombinant lethal times, 342, 342t AcNPV, 40,3 16,322-336 ACRPC pink bollworm, 391 Acyrthosiphon pissum, 162 Adjuvants, 163-l 66 Aedes aegypti, 150 Aedes vexans, 39 A83543 factors, 172 Africa, 52 Agaricus Bosporus, 284 AgNPV, 3 16 Agree, 198 Agriculture alternative production practices, 64 chemical regulations, 6 l-63 research IPM role, 604-606 scouting, 64 threshold use, 64 Agrobacterium radiobacter, 30, 104 Agrobacterium tumefaciens, 30, 2 13 Agrotis ipsilon, 17, 289 Align, 148 Annexes EU directive 91/414EEC, 457t, 458f, 4592 Antibiosis microbial antagonism, 122-123 609
610 mode of action, 160, 161 origin, 156, 157 regulation, 158 Azadirachtin-based insecticides development, 159, 160 Azadirachtin-based pesticides commercialization history, 157-l 59 Azatin, 148, 158, 162 B B. bassiana, 238-245 B. sphaetkus, 35 Bacillus papillae, 14 Bacillus subtilis, 3 1, 104 Bacillus thwit~gietuis, 1, 189-204. See also Bt agricultural applications, 57 analysis, 543-546 crystal proteins, 189, 190 development, 190, 19 1 discovery, 13 efficacy, 193 genetically modified strains, 198, 199 genetic manipulation, 193-198 improving, 19 l-l 93 market, 24 recombinant strains, 199-201 sales, 189 Bacterial biofungicide disease control and yield enhancement, 492 Bacterial biofungicide formulations, 492 Bacterial bioherbicides formulation, 491,492,493t target weed and biocontrol agent, 493t trade name and manufacturers, 493t Bacterial bioinsectjcide formulations, 4921194 Bacterial biopesticide formulations, 488494
Index development, 489-49 1 requirements, 488, 489 storage time, 488 Bacterial insecticides field performance, 35-39 Bactimos, 38, 19 1 Baculoviridae genera, 32 1 Baculoviruses, 5 augmentative control agents, 307-309 cost effectiveness, 302 developing countries, 3 16, 3 17 genetically modified interactions, 346349 insect control agents, 305, 306 example, 306 insect pest control, 30 l-3 18 integrated pest management system, 342 Lepidoptera examples, 32 1 new developments, 39-41 other control agents joint actions, 341-35 1 performance expectations, 303, 304 pest control advantages, 34 1 recombinant, 32 l-336 registered insect pest control, 3 1Ot synthetic jnsecticides interactions, 343-346 types and properties, 304, 305 viral insecticides, 309-3 16 efficacy, 312, 313 vs chemical insecticides cost comparison, 303, 304 Baculovirus field test US EPA approval, 547 Bassi, Aogostino, 13 BCA, 25,26 formulation and application, 5 12-5 14 inactivation, 26
Index
611
induced systemic resistance, 123, 124 microbial antagonism, 120-123 single strain, 129 ultraviolet (UV) radiation, 26 Beauveria bassiana, 4, 5, 27, 32-34
China, 147 discovery, 13 Beauveria brongniartii,
32-34
Beet army worm, 3 14 Beneficial insects Neemix, 166, 167 Beneficial organisms, 58, 59 Betel, 34 Billbugs, 288,289 Bioassay methods Bt preparations, 546 Biochemical active ingredients, 426t428t Biochemical agents analysis and instrumentation, 532 classes, 532 Biochemical pesticides description, 4 16 list, 595, 596 US EPA registration process active ingredient classification, 424,425 classification guidance, 425-429 data requirements, 424-434 FIFRA exemptions, 429,430 indentitylanalysis, 430,43 1 mammalian toxicology, 43 l-433 nontarget organism testing, 433, 434 Biocontrol agents classes, 53 1 Biocontrol products delivery methods plant treatment, 501 seed treatment, 499 soil treatment, 500, 501 formulation technology future needs, 502
Biofungicide development bioassay development, 60 current status and future prospects, 95-97 demonstration program, 8 1, 82 fermentation process selection, 60 field-testing, 8 1 formulation development, 80, 8 1 microorganism screening, 79, 80 protocol design, 82 registration package, 8 1 Biofungicides, 2, 3 biopesticide formulations, 487-502 commercial development, 77-97 criteria, 78, 79 Bioherbicides, 5,6, 359-378 biopesticide formulations, 487-502 hunting and gathering, 361, 362 Bioinsecticides, 3-5 biopesticide formulations, 487-502 dose acquisition cost benefit analysis, 566 delivery vs target, 562-569 tield dosage determination, 563568 future needs, 569 historical perspectives, 544, 545 host biology, 558-561 host susceptibility, 555-558 microbial agent, 561, 562 mortality relationships, 555-557 parameter and constraints, 568t principles, 553-569 relationship formula, 564 replication, 557, 558 target, 555-561 growers, 596, 597 insect target and pathotype, 494t trade name and manufacturers, 494t Biological control areas, 371 microbial associations, 124, 125 prospects and constraints, 126, 127
612 Biological control agents, 23 formulation and application, 5 12-5 14 inactivation, 26 induced systemic resistance, 123, 124 microbial antagonism, 12&l 23 single strain, 129 ultraviolet (UV) radiation, 26 Biological herbicides synergized, 377 Biological insecticides field performance, 32-35 IPM, 32-35 Biological macromolecules analysis, 535-537 Biological pesticides categories, 4 15,416 developmental incentives, 439 Biological weed control, 5, 6 plant pathogens formulation and application, 37 l-378 Bioneem, 158, 160 Biopesticide acceptance factors, 597, 598 Biopesticide analysis sequencing, 537 Biopesticide companies competitiveness, 70, 7 1 Biopesticide conversion, 14 Biopesticide delivery system field trials, 5 19-523 mortality guideline assessment, 523 prefield trials, 5 17-5 19 techniques, 5 12 ULV drift spraying, 520-522 variables, 5 19, 520 vs chemical delivery system, 5 12,5 13 Biopesticide development phases, 5 11f regulation, 65-67 successful conditions, 509, 5 10 Biopesticide efficacy, 546, 547 Biopesticide market future needs, 450,45 1
Index Biopesticide product commercialization industries view future needs, 482,483 Biopesticide product development application equipment, 5 15-5 17 spray parameters, 5 15-5 17 step by step approach, 5 14-523 Biopesticide production developing countries, 47 Biopesticide products advantages, 598 disadvantages, 598 implementation issues, 5988604 Biopesticide registration, 4 15-483 Biopesticide regulation, 67 Biopesticides, l-8 analysis, 529-548 categories, 4 15, 4 16 conventional systems, 598, 599 definition, 473, 5 12 development, 45,46 dose acquisition, 7 EPA definition, 63 EU directive 9 l/4 14EEC active ingredients, 46 1 harmonization, 469-47 1 principles, 46 1, 465 product requirements, 46 I European market, 24 Europe registration requirements, 453-471 field use considerations, 60 1t formulations, 487-502 deployment compatibility, 487,488 principles, 5 17, 5 18 government commodity and conservation programs, 60,6 1 growth rate, 1,2, 15 management protocols, 7 market, 53, 54, 70 market acceptance, 15 market potential, 23 monitoring, 529-548
Index opportumttes, 2 product development Industry’s progress, 476-479 production, 47 protocol and delivery systems, 509-524 registration requirements, 49, 50 regulation, 2 regulatory tmplicattons, 529-548 relatrve factor prtces, 60 shelf ltfe, 7 US EPA definitron, 595 groups, 595 regtstratlon process, 6, 4 16-440 use advantages and disadvantages, 477 Biopesticides Pollution and Prevention Dtvision EPA, 6,63 Btopestictde technology pestictde pohcy, 55-7 1 Blopestrcrde use policres, 63, 64 Bioratronals defimtron, 512 Bioratlonal technologies, 385-404 B~osys, 158, 159 BIO Systems, 32 Blotechnologies future needs, 605, 606 Black cutworms, 17,289 Black vine weevil, 34,284,286 Bluegrass btllbug, 288 Bollgard cotton, 2 17 Botamcal msecticides commercialization barriers, 141 Botamc pesttctdes, 45 BPPD, 6 EPA, 63 Breedmg programs, 59, 60 Brown rot, 30, 3 1 Bt, 35
673
Bt Bt Bt Bt
analysts, 543-546 exotoxm presence, 545, 546 prmciple toxms, 543 regulatory methods, 543-545 Berliner safety evaluations, 53 1 corn, 18, 59 cotton, 18 cost, 60 H- 14 productton guidelines World Health Orgamzatron, 52
Btl larvmde,
39
Btk, 37 Bt kurstakl,
51
Bt preparations quantttation methods, 546 Bt production China, 48,49 quahty control, 49 Bts, 4 Bt subspp rsraelensis (Bti), 37, 38 Bt toxins plant expresston, 16 transgenic plants, 2 1 l-225 transgemc technology, 2 1 l-2 14 Bt transgenic crops EPA registration and reststance management, 224,225 future, 225 Burkholderza cepacla, 104, 105 brological control, 105 ecology, 104 mode of actton, 105 productton and appltcatton, 107, 108 C Cages disadvantages, 5 19 Candtda sake, 30 Capillary zone electrophoresrs polypeptide analysrs, 536 Carbon competltlon microbial antagomsm, 12 1, 122 CASST, 495
index
614 Cat flea, 289 CDA techmques, 5 15, 5 16 Cell-u-wet, 164 Chemrcal mrcrobtal mteracttons statrstrcal methods, 349 Chemtcal apphcatton techmques, 5 13,5 14 Chemtcal delrvery system vs btopesttcrde dellvery system, 5 12,5 13 Chemical herbtctdes integration, 377 Chemrcal msectrcrdes field use constderatrons, 600t Chemical pestrcides, 45 lust, 415 Chemical regulatrons agrrcultural, 61-63 Chemical screenmg, 14 Chma, 238 Beauverla
basslana,
147
Bt productron, 48,49 fungal pathogens, 250 opportunrttes, 53 regtstratron requrrements, 49 Chrnaberry tree, 149 Chmch bug, 13 Chlamydospores, 366 Chorzstoneura
fumtferana,
19 1
Classical brocontrol, 37 I Codlmg moth, 3 15 case study, 393-401 Cold fogging equrpment, 5 17 Coleoptera, 17 Collego, 495 Colletotrtcum orblculare, 123 Colorado beetle, 532 Colorado potato beetle, 147, 22 1 COM (89) 34 plant protectron products Europe, 455,456 Commumty pohcy Europe regtstratron requirements, 455,456
Condor, I98 Conidla, 25, 237-245 Consumer acceptance nematode products, 279 Consumer concern, 59,60 Controlled droplet appbcatron techniques, 5 15, 5 16 Corn Insect control, 16 transgemc, 16 Cotton, 150 case study, 389-393 insect control, 16 Cotton bollworm, 532 Cotton leaves recombinant baculovnus, 326t Councrl directive plant protection products Europe, 455,456 CpGV, 3 15 Crop pests natural enemies, 58, 59 Crop rotatton, 64 Crops planted outlook, 68 Cry3A protem, 198, 199 Cry genes, 193, 194 CryIa Bt toxms, 16 CRYMAX, 15, 199,200 Cryphonectrza parasztlca, 12 1 Cry protems, 190 Cryptic pests entomopathogemc fungr, 245-247 Ctenocephalldes
fells fells, 289
Cucumber, 123 Culex pzplens, 39
Culture techmques microorgarusm recogmtron, 539, 540 Cutlass, 198 Cydla pomonella GV, 3 15 CZE polypeptrde analysrs, 536
lncfex D
DDT, 13, 17 Dehvery system bropesticides, 509-524 chemical vs bropestlclde, 5 12, 5 13 definition, 5 10 Deny, 109 Design, 198 Developmg countrtes, 45-53 baculovrruses, 3 16, 3 17 biopestrcrde productron, 47 opportunitres, 53 DeVme, 494,495 Drabrotica, 16 Dramondback moth example resrstance management, 588 Dipel ESNT, 25 Drptera, 532 Directrve 9 l/4 14EEC Europe regrstratron reqmrements basrcsldescriptron, 456-461 blopestrcrdes, 454, 455 specrfied procedures, 456461 Diseases bropestrcide formulatrons, 487-502 Dormant propagules, 489 Dose acquismon broinsectrctdes fundamental aspects, 553 prmcrples, 553-569 Dose-response analyses bropestrctde product development, 514,515 Doses resrstance management, 582-584 Douglas fir tussock moth, 302, 307-309 Dow Agrochemrcals, 532 DowElanco, 532 Droplet stze spectra measurmg and mterpretmg, 5 16, S17 E
Ecogen, 15 Ecologrcally based management systems, 68, 69
67.5 Ecologrcal restramts weed control, 363, 364 E 1-D Parries, 159 Elcar, 5,3 13,3 14 ELISA, Bt preparations and, 546 Emamectm benzoate, 3,4 Emergency use permit, 6 Emulsifiable concentrate formulatrons, I46 Entomopathogemc fungr, 4, 5 cryptic pests, 245-247 development, 234-237 product stabrlizatron, 237-240 submerged culture, 235 Entomopathogenic nematodes, 5,27 1-29 1 Enzymes, 532 EPA, U S See U.S. EPA EPA approved CellCap products, 478 EPA Pestrcrde Testing Gmdelmes, 109 Eptcoccum mgrum, 30 Eplzootrcs, 544, 545 EU directrve 9 l/4 14EEC bropestrcrdes, 454, 455 US EPA registration process comparison, 470t EUP, 6 Europe formulatron and dehvery, 24-27 future prospects, 41,42 insectrcides, 32-35 mrcrobtal biopestrcides, 23-42 new developments, 29-4 1 plant pathogen control, 27-32 European cockchafers, 252 European corn borer, 34,219,246 European pme sawfly, 3 15 European spruce sawfly nuclear polyhldrosrs vn-us (NPV), 302,306 Europe registration reqmrements bropestrcrdes, 453-471 dtrectrve 91/414EEC, 454,455 US EPA registration process comparison, 470t commumty and pestrcrde pohcy, 455,456
616 F FAIR Act, 68 Fax Act and Food Qualrty Protectron Act, 2 bropestrcrdes, 529, 530 Fall army worm, 201 Federal Food, Drug and Cosmetic Act, 61 biopesttcide registration, 4 15-440 Federal Insectnxde, Fungrcrde, and Rodentictde Act, 61, 65 bropesticide regrstratron, 415-440 Fermentation-derived insect control agents, 17 I-1 85 dtscovery, 17 1 FFDCA, 61 bropestrcrde regrstratton, 4 15-440 Freld crop pests spray, 20-257 Field efficacy recombinant baculovrrus, 329, 330 Field management history, 595 IPM role, 604-606 new technologres, 595-607 Freld trials bropestrcrde delivery system, 5 19523 FIFRA bropesttcrde regrstration, 415-440 bropestrcrdes, 529-530 Fmal Rule for Mrcrobral Pestrctdes, 480 Flea Halt, 289 Floral lures/attractants/repellents target pest, 427t, 428t Florida IPM, 18 Foil, 198 Follar application weed control, 375-377 Fohar fungal brocontrol agents invert emulsions, 495 Fomes annosus, 3 1
Index Food Quality Protection Act, 6 1, 62 Food Quahty Protection Act 1996 pesticrde minor use definitron, 445 Foray 48B, 36 Forest tent caterpillars, 162, 223 Formulatron biologtcal agents, 5 12-5 14 weed control, 373-375 plant pathogens, 37 l-378 FQPA, 2 bropestrcrdes, 529, 530 France mosquito control, 38 Frankluuella occrdentalrs, 34 Frmt, pome case study, 393-401 Fungal btofungrcrdes brocontrol agent, 497t delivery, 497t formulatrons, 496,497t trade name and manufacturers, 497t Fungal broherbrcides formulation, 493t target weed and brocontrol agent, 493t trade name and manufacturers, 493t Fungal bromsecttcide formulatrons, 496-498 Fungal bropesticrde formulatron, 494498 Fungal pathogens granular formulations, 245-247 inoculative augmentation, 252 oil formulations, 240-245 Fungi entomopathogemc, 4, 5 Fungrcrdes target pest, 428t Fungus formulatron, 240-245 Fungus gnats, 286 Fusarwm oxysporum, 30, 3 1, 124, 125 Fusarlum prollforatum,
96
index Fusarmm welts suppressive soils, 118-l 20 G Gas chromatography biopesticide analysis, 53 1 Genetically modtfied baculoviruses interactions, 346-349 Genetic engineering, 15 Genetic techniques microorganism recognition, 54 l-543 Germany mosquito control, 38, 39 Gmkgohdes, 147 Ghocladium, 30 Ghocladmm virens, 105-107 apphcation, 107-l 09 biological control, 107 ecology, 105, 106 formulation development, 108 mode of action, 106 production, 107, 108 registratton, 109, 110 GhoMix, 30 Ghotoxm, 106 Globus etunicatum, 127 Government commodity and conservation programs btopesttcides, 60, 6 1 Granular formulattons fungal pathogens, 245-247 Granuloviruses, 32 1 Grapeleaf skeletonizer, 302, 307-309 Grasshoppers, 247-250 Gray mold, 96 Greenhouse assays recombinant baculovnus, 328, 329 Greenhouse whitefly, 164 Green products consumer demand, 69-7 1 Growers biomsecticldes, 596, 597 transgemc plants, 596, 597
617 Gusano, 3 16 Gypcheck, 3 14,3 15 Gypsy moth, 37, 191, 223, 3 14, 3 15 H H vzrescens, 17, 178, 182 Hellcoverpa armlgera, 39 Helxoverpa zea, 5 Hellothls armrgera, 5 1, 2 18
Heliothts NPV, 3 13, 3 14 Hekothzs vwescens,
4
Herbicides synergy mycoherbicides, 365 Heterorhabditis, 27 l-276 High doses resistance management, 582-584 High pressure liquid chromatography biopesticide analysis, 53 1 Honduras, IPM, 18 Hoplochelus
marglnalw,
34
Hormones, 532 Host-plant resistance, 5, 60 Host range genetic manipulatton mycoherbmtdes, 365, 366 HPLC biopesticlde analysts, 53 1 Hydraultc sprayers vs rotary atomizers, 5 16 Hydraulic spraying disadvantages, 5 15 Hydroponics, 129 Hyphomycetes solid substrate culture, 235 submerged culture, 236 HzNPV, 313,314 I IACR-Rothamsted, ICAMA, 49,50 ICIPE, 52 IGR, 160, 161
35
618 Immunological methods microorgamsm recogmtion, 540, 541 India, 50, 5 1, 156 azadirachtm-based Insectlades, 1.59, 160 Indonesia, 159, 160 Induced systemic resistance, 123, 124 Insect control pheromones, 385-404 case studies, 389-401 future needs, 401-404 Insectlclde production bloactlvlty screening, 143, 144 choice of plants, 140, 141 collection sites, 142 extraction, 144, 145 formulation, 146, 147 standardization, 145, 146 tissue harvested, 141, 142 Insecticides compatlblllty with IPM, 148 development, 140 Insect pest control baculovlruses, 30 l-3 18 reglstered baculovlrus, 3 1Ot Insect pests blopesticide formulations, 487-502 Insects bacterial pathogens, 13 Institute for the Control of Agrochemlcals, M1nW-y of Agriculture, 49, 50 Integrated pest management, 17,438, 439,578 See also IPM baculovirus, 342 International Center of Insect Physiology and Ecology, 52 International orgamzatlons, 52, 53 Interrupt, 289 Invert emulsions follar fungal blocontrol agents, 495 IPM, 17,438,439, 578 baculovlrus, 342 blologlcal insecticides, 32-35
Index Florida, 18 Honduras, 18 Mexico, 18 Nicaragua, 18 North America, 17, 18 tomatoes, 18 IPM approach one crop system, 604 IR-4 Blopestlclde Grants Program funded proposals, 44&448 IR-4 blopestlclde program admimstratlon, 443,444 food crop successes, 445t minor crops, 443-45 1 Iron competition, 122 J
Japanese beetle, 14 K
Koppert, 32 L
Laboratory assays blopestlclde product development, 514,515 recombinant baculovlrus, 325-328 Lawns, 158 LdMNPV Neem extract, 344 LdNPV, 314,315 Lepldoptera, 16, 147, 177, 217, 532 baculovlrus examples, 32 1 Lepldopteran pheromones isolation and ldentlficatlon, 535 regulations, 534 volatihzatlon, 534 Leptmotarsa decemllneata, 22 1 Life stage targeting resistance management, 584 Lilly Research Laboratories, 172 Llmmlods, 162, 163 Llmonin, 147, 150
Index Liquid fermentation, 108 Locusts Low doses resistance management, 584 Low persistence formulations resistance management, 58 1 LUBILOSA project, 5 12 Lupins, 150 Lymantrla dzspar, 5, 37, 191 Lyman tria dzspar NPV, 3 14-3 15 Lymantrla monacha, 36, 192 M
Macromolecules characterization, 536 Malacosoma dzsstrza, 162, 223 MALDI-TOF technique btologtcal macromolecule analysts, 536 Mamestra brasslcae NPV, 39 Mamestrin, 39 Mammalian toxicology data US EPA registration process btochemmal pestictdes, 43 It mtcrobtal pesticides, 4 19t Management protocols biopesticides, 487-607 MargoBiocontrols, 159 Margosan-0, 148, 157, 158 Marigolds, 150 Mass spectrometry biopesticide analysis, 53 1 Mating dtsruption products, 386t Matrix assisted, laser desorptton ionization time of flight btological macromolecule analysis, 536 Me&a volkensl, 150 Melolontha melolontha, 34 Metabolism microorganism recognitton, 540 Metarhzium anlsopllae, 13, 32, 34 Metarhlzrumflavovtrzde, 25, 34
619 Methomyl efficacy, 35Of Mexico IPM, 18 MFP, 15 Microbial chemical mteracttons statistical methods, 349 Mtcrobial antagomsm, 120-I 23 anttbtosis, 12, 123 btological control agents, 120-123 nutrtent competition, 12 1, 122 parasitism, 120, 12 1 Microbial assoctattons biological control, 124, 125 mtcrobtal product development, 128, 129 Microbial biomsecttctdes prmctpal features, 553 Microbial biopesttcides, 23-42 formulation and delivery, 2427 future prospects, 4 1, 42 msecttcides, 32-35 new developments, 294 1 plant pathogen control, 27-32 Mtcrobtal fermentation products, 533 Microbial msecttcides distribution, 27 Microbial Joint action, 117-l 30 btological control agents mode of action, 120-l 24 induced systemic resistance, 123, 124 mmrobtal antagomsm, 120-l 23 microbial associations, 124-l 26 biological control, 124, 125 plant growth promotion, 125, 126 microbtal product development, 128-130 microorganism compattbiltty, 127, 128 prospects and constraints, 126, 127 suppressive ~011s 118-l 20
620 Mtcrobtal pest control agents tier 1 toxicology requirements, 449t Microbtal pesticides descrtptlon, 4 16 ltst, 596 pheromones, 56, 57 US EPA registration process data requirements, 4 16-424 tdenttty/analysis, 4 17 manufacturmg process descriptton, 418 nontarget organism data requirements, 42 l-424 toxtctty testmg, 4 18-42 1 Microbial weed control htstory, 359-361 status, 359 Mtcrobtological pest control agents analysts, 53 1 MicroGermm, 32 Microorganism compattbility, 127, 128 Mtcroorgamsms, 538-543 detection methods, 539 genetically engmeered, 538 monitoring methodologies, 538, 539 Minor crops IR-4 biopesttctde program, 44345 1 Mint flea beetle, 287 Mint root borer, 287 Mole crickets, 288 Monhua fructicola, 3 1 Mondinia laxa, 30, 3 1 Momtormg btopesttcides, 529-548 Monsanto transgemc plant regulations, 530, 53 1 Mosquito control Europe, 38, 39 MPCAs analysis, 53 1 M-PEde, 165 M-Trak, 15 Mycogen, 15
index Mycoherbtcides, 359-367 barriers, 363, 364 containment, 366 ecologmal restraints, 363, 364 efficacy improvement, 365,366 enhancement, 364-366 formulations, 494-496 genettc mampulation virulence and host range, 365, 366 registered, 362, 363 synergy herbicides, 365 Mycomsectictdes, 4, 5, 223-259 agrochemlcal mtegration, 256, 257 commerctahzatton, 257 development, 234-240 field performance, 32-35 fungus formulation, 240-245 future, 258 inundattve applmations, 252, 253 product stability, 253 spray apphcatton, 253-256 use and delivery, 245-247 UVL spray applications, 247-250 Mycorrhizas, 125, 126 Mycorrhization helper bacteria, 126 Mycostop, 492 Mycotrol, 252-257 agrochemtcal integration, 256, 257 commerctahzation, 257 product stabtlity, 253 spray application, 253-256 N N tabacum, 214
National Agricultural Science and Technology Institute (NASTI), 5 1 Nattonal Organic Standards Board, 70 National Research Council, 69 Natural baculovtruses insect pest control, 301-3 18 Natural insect regulators target pest, 428t
Index Natural plant protection, 34 Natural plant regulators, 532 Naturalyte, 532 Neem extracts, 533 LdMNPV, 344 Neem, 139-151 applications, 147 bioactivlty screening, 143, 144 collection sues, 142 commercral experience, 155-I 68 compatibility with IPM, 148 extraction, 144, 145 formulation, 146, 147 future trends, 150, 15 1 materials, 140-142 methods, 143-148 productton, 156 recent products, 140-148 seeds, 141, 156 standardtzatton, 145, 146 trees, 156 Neemazad, 158, 160 Neemazal, 148, 159 Neem-based insectrcides regulatron, 158 Neemix, 160, 162, 164 beneficial insects, 166, 167 Neemix 4.5, 148, 158 Nematicides target pest, 428t Nematode products consumer acceptance, 279 Nematodes applicatron, 28 l-284 biology, 27 l-276 bulk storage, 257 emus, 287 entomopathogenic, 5 field efficacy, 284-289 foliar application, 283 formulation, 257-259 future, 290, 291
621 glasshouse crops, 286 host range, 274 Insect traps, 284 inundate biological control, 28 I, 282
mass production, 276, 277 mmt and berries, 287, 288 mushrooms, 284-286 parasitic cycle, 27 1, 272 pet/vet, 289 plan propagation application, 283 product quality, 279-28 1 soil application, 282, 283 strain discovery, 274 trap crop applicatron, 283 turf, 288-289 Neodiprlon sertrfer NPV, 3 15 Newleaf, 22 1 Nicaragua IPM, 18 Nicottana gosset, 149 Nitrogen-9nO-fixing bacteria, 126 Noctuid moths, 3 13, 3 14 Nonproteinaceous pesticides, 436 Nontarget organism data requirements US EPA registration process biochemmal pesticides, 433,434 microbial pesticides, 422t transgemc plant pesticides, 435t North America biopestrcrde converston, 14, 15 future, 19-20 genetic engineering, 15 historical trends, 13, 14 IPM implementation, 17, 18 toxin expression, 16, 17 NsNPV, 3 15 Nuclear polyhedrosls virus, 39, 321 See also NPV European spruce sawfly, 302, 306 Nun moth, 36, 37, 191 Nutrient competition microbial antagonism, 12 1, 122
622
Index
0 Office of Pesticide Program, 4 16 011 drlutents, 242, 243 Oil formulattons fungal pathogens, 240-245 OPP, 416 Orgamc Foods Productton Act, 70 Oryza satwa, 2 13 Ostrlnla furnacalrs, 219 Ostnnla nubdulls, 34, 2 19 Otlorhynchus sulcatus, 34
P Paecdomycesfumosooseus,
32
Pakistan, 5 1 Parasittsm, 120, 12 1 Parker Valley Program pmk bollworm, 39 l-393 Pathogen biology weed control, 372, 373 Pathogen marking mycoherbtctdes, 364 Pawpaw tree, 149 Pea aphid, 162 Penicillium
oxalicum, 30
Pepper weevtl, 164 Pesttctdal active ingredients categortes, 436 Pesttcrde analysis objectives, 529 classes, 4 15 defimtton, 4 15 minor use defimtton, 445 mixtures resistance management, 586, 587 rotation resistance management, 585, 586 safety, 19 Pesticide pohcy btopestictde technology, 55-7 1 Europe regtstratton requirements, 455,456
Pheromones, 6 analysts, 533-535 history, 385-389 msect control, 385404 case studtes, 389-40 1 future needs, 401-404 mlcroblal pesttcldes, 56, 57 purposes, 533,534 target pest, 426t428t USEPA regtstered, 386t Phlebtopsts glgantea, 3 1 Phthormmaea operculella Zeller, 22 1 Pmk bollworm Arizona Cotton Research and Protectton Counctl, 39 1 case study, 389-393 Parker Valley Program, 39 l-393 Plant btology weed control, 372 Plant expresston Bt toxm, 16 Plant growth promotton mtcrobtal assocratlons, 125, 126 Plant growth regulators target pest, 426t-128t Planthoppers, 147 Plant-parasmc nematodes suppresston, 289,290 Plant pathogemc fungt blologtcal control, 27-32 Plant pathogens blologtcal weed control formulation and apphcatton, 37 l378
weed control research needs, 377, 378 Plant protectton products Europe proposal, 455,456 Plutella xylostella,
PMD, 82-95 Poland softwood, 36
39, 52
Index Polypepttde analysts CZE, 536 Pome frurt case study, 393-40 1 Population growth, 19 Potato tuber moth, 22 1 Prefield trials btopesttcide delivery system, 5 17519 Proactrve plans resistance management, 578 Proteinaceous pesttctdes, 436 Protein method Bt preparatrons, 546 Pseudomonasfluorescens, 30, 127, 129 Pyrethrum, 147
Q Qualny control Bt production China, 49
R Rangeland pests UVL spray, 247-250 Raven Biomsecticide, 199 Reactive plans resistance management, 578 Recombinant AcMNPV lethal times, 342, 342t Recombinant baculovnus, 32 l-336 biological selectivity, 330-332 deployment strategtes, 334-336 envnonmental fate, 332-334 gene deletron, 322 gene insertron, 323-325 genetic fitness, 332 msectrcldal actrvny, 325-330 molecular desrgn, 334336 safety, 330-332 vs wild-type, 332 Reduced-Risk Pesticide Imtrattve, 62 Reduced-risk pestlctdes US EPA, 438
623 Reduced-risk program purpose US EPA, 438,439 Refuges resistance management, 579-58 1 Regtonal Network on Pesticides for Asia and the Pacific, 50 Registered baculovuus insect pest control, 3 1Ot Regrstratron reqmrements, 49, 50 resistance management, 577, 578 Regulations agrmultural chemical, 6 l-63 biopesticide, 67 Regulatory rmplrcatrons biopesticides, 529-548 Relatrve factor prices biopesticides, 60 RENPAP, 50 Research needs plant pathogens weed control, 377, 378 Reststance management diamondback moth example, 588 tmplementatton, 588, 589 mode of actron, 567-576 regrstration requnements, 577, 578 resistance momtormg, 587, 588 strategies, 575-589 tactics, 578-587 targeted pests, 576, 577 Resrstance morutormg reststance management, 587, 588 RH-9999, 162 Rice, 213 Rice leaffolder, 222 Rotary atomrzers bropestrcrde product development, 515,516 advantages, 5 16 vs hydraulic sprayers, 5 16 Rotenone, 147
624
Index
S S carpocapsae, 289 S glaserz, 276 Saccharopolyspora spznosa, 172 Scaptertscus borelltt, 288 Scaptertscus rtobravts, 288 Scapteriscus vzctnus, 288
Sclartd flies, 284 Seedling disease brocontrol agents application, 109 compattbtltty with chemical pesticides, 110 current status and future prospects, 111 formulatron development, 108, 109 hqutd fermentation, 108 registration, 109, 110 brologtcal control, 103-l 11 Burkholderta cepacta, 104, 105 Gtlocladtum wrens, 105-107 Semtochemtcals, 532 analysis, 533-535 defimtion, 533 SeMNPV efficacy, 350f SeNPV, 3 14 Stlkworm infectious disease, 13 Site-specific recombmatton system, 194, 195 Skeetal, 19 1 Slow acting pesttctdes mortality gutdelme assessment, 523 Softwood, m Poland, 36 SotlGard, 109 Soursop frmt, 149 South Korea, 5 1, 52 Sphenophorus
parvulus,
Spmosads, 4, 532 Spinosyns, 4 chemistry, 173-177 discovery, 172
288
envtronmental and toxicological profile, 181, 182 insect spectrum, 177-180 mode of action, 180, 181 resistance, 182-l 84 Spinosyn structure-activity relattonshtps, 178-l 80 Spodex, 3 14 Spodoptera extgua NPV, 3 14 Spodoptera frugtperda, 20 1 Spodoptera ltttoralu, 2 18 Spodoptera lttura, 143 Sportdesmrum sclerottvorum,
12 1
Spray field crop pests, 250-257 parameters btopesttctde product development, 515-517 Spray coverage improvement reststance management, 584, 585 Spray Drift Task Force, 5 16 Spruce budworm, 19 1 Steinernema, 27 l-276 Step by step approach biopestictde product development, 514-523 Streptomyces grrseovtrtdts, 104 Striped stem borer, 222 Stylet 011, 165 Sugar cane white grub, 34 Suppressive soils mtcrobtal Joint action, 118-l 20 Surfactants, 495 Synthettc msecttctdes weld-type baculovirus interactions, 343-346 Synthetic pesticides history, 599 T
TalaromycesJavus, 110 Target pest pheromones and plant growth regulators, 426t-428t
Index Teknar, 19 1 Termmites, 532 Tetranychus urtlcae, 180 Thailand, 50, 5 I Thermal fogging equipment, 5 17 ThermoTrilogy, 159 Tier 1 toxtcology reqmrements microbial pest control agents, 449t Tobacco budworm, 177, 178,215,532 Tobacco cutworm, 143 Tobacco hornworm, 2 14 Tomatoes, IPM and, 18 Tomato wilt, 3 1 Totipotency, 2 11 Toxicology requirements, tier 1 microbial pest control agents, 449t Transgenic corn, 2 19-22 1 future, 220, 22 1 history, 2 19 registration and commercialization, 219,220 Transgenic cotton, 2 14-2 19 field tests, 2 15, 2 16 future, 218, 219 history, 2 14, 2 15 registration and commercialrzatton, 216218 Transgemc eggplant, 22 1, 222 Transgenic plant pesticides definition, 434 description, 4 16 US EPA registration process, 434438 active ingredients, 436 characterization data/mformatton, 436,437 nontarget organism data requirements, 435t Transgemc plants Baczllus thurwg?enszs (Bt) toxins, 2 1 l-225 dose acquisition, 569 growers, 596,597 regulations, 530, 53 1
625 Transgenic Transgemc Transgemc Transgenic Transgenic
potato, 22 1, 222 rice, 222 soybeans, 222,223 tomato, 222 trees, 223 Trlaleurodes vaporarlorum, 164 Trichoderma harzianum, 30, 127 Twhoderma
vwzde, 30
Trtchodex, 96, 97 Turfplex, 158 Two-spotted spider mites, 180
U ULV application hydraulic sprayers, 5 15, 5 16 UNIDO, 52-54 US EPA biopesttcrde reglstratton, 4 15-440 blopesttctdes, 529, 530 US EPA registration process biopesticides, 4 15-440 Europe registration requirements comparison, 470t mdustries view on EPA role, 479, 480 industry view and approach, 473-
483 EU directive 91/414EEC comparison, 470t USDA industries view on role biopesttcides, 48 1,482 USDA Forest Service, 69 UVL spray rangeland pests, 247-250
V VA-mycorrhiza, 126 VA mycorrhizal fungi, 127 Vectobac, 38, 191 Vector MC, 288 Velvetbean caterptllar, 5, 3 16 Verticilltum
Vietnam, 52
lecanu, 32
626 Vtp msecttctdal proteins, 225 Vu-al msectlctdes baculovuus, 309-3 16 drsadvantages, 349-35 1 Vtrulence btopestnxdes defimtion, 5 12 genetic mampulatton mycoherbtctdes, 365, 366 Virulence range recombmant baculovirus, 33 1,332 Vnus chemical mteracttons commercial potential, 349-351 Virus formulation, 498, 499 development, 498,499 requirements, 498 W Weed control barriers, 363, 364 btologtcal, 5, 6
Index btologtcal vs chemtcal, 363 history, 359-361 plant pathogens formulanon and apphcatron, 371-378 research needs, 377,378 Weeds btopesttctde formulatrons, 487-502 Weevrls, 287, 288 Western flower thrtps, 34 Whnefbes, 32 Whole cell analysts mtcroorgamsm recognition, 540 Wild-type baculovnuses dtsadvantages, 40 synthetic msecttctdes mteracttons, 343-346 World Health Orgamzatton Bt H- 14 productron gutdelmes, 52 Y Yellow fever mosquito, 150