Food & Function, Vol 02, No 02, February 2011

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Food & Function

EICC-1: First EuCheMS Inorganic Chemistry Conference

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11 - 14 April 2011 University of Manchester, UK

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The Dalton Division of the RSC is joining together with the EuCheMS Inorganic Division (EID) to host the first edition in a new European conference series in Inorganic Chemistry.

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Volume 2 | Number 2 | February 2011 | Pages 93–144

Inorganic Chemistry is a buoyant subject area with major developments being seen in all branches of the subject and common themes emerging; this timely conference arranged across parallel sessions brings all these themes together.

Themes and Plenary Speakers Supramolecular and co-ordination chemistry Paul Beer University of Oxford, UK Organometallic and catalysis Sylviane Sabo-Etienne Laboratoire de Chimie de Coordination du CNRS, Toulouse, France Reaction mechanisms Pablo Espinet University of Valladolid, Spain Inorganic materials Reshef Tenne Weizmann Institute of Science, Israel

Energy and photochemistry Leif Hammarström Uppsala University, Sweden Bioinorganic and metallic enzymes Claudio Luchinat University of Florence, Italy Main group Markku Räsänen University of Helsinki, Finland Solid state chemistry Martin Jansen Max Planck Institute for Solid State Research, Germany

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COVER ARTICLE Vincenzo Fogliano and Francisco J. Morales Estimation of dietary intake of melanoidins from coffee and bread

2042-6496(2011)2:2;1-A

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COVER ARTICLE Joshua D. Lambert et al. (−)-Epigallocatechin-3-gallate increases the expression of genes related to fat oxidation in the skeletal muscle of high fat-fed mice

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IN THIS ISSUE

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ISSN 2042-6496 CODEN FFOUAI 2(2) 93–144 (2011) Cover See Vincenzo Fogliano and Francisco J. Morales, pp. 117–123. Image reproduced by permission of Laura Gennaro from Food Funct., 2011, 2, 117.

Inside cover See Sudathip Sae-tan, Kimberly A. Grove, Mary J. Kennett and Joshua D. Lambert, pp. 111–116. Image reproduced by permission of Joshua D. Lambert from Food Funct., 2011, 2, 111.

REVIEW 101 Multistage carcinogenesis process as molecular targets in cancer chemoprevention by epicatechin-3-gallate Min-Hsiung Pan,* Yi-Siou Chiou, Yin-Jen Wang, Chi-Tang Ho and Jen-Kun Lin* ECG may block multiple stages carcinogenesis via regulating intracellular signaling transduction pathways.

PAPERS 111 ( )-Epigallocatechin-3-gallate increases the expression of genes related to fat oxidation in the skeletal muscle of high fat-fed mice Sudathip Sae-tan, Kimberly A. Grove, Mary J. Kennett and Joshua D. Lambert* ( )-Epigallocatechin-3-gallate (EGCG) enhances skeletal muscle expression of genes related to b-oxidation in high fat-fed mice.

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Food Funct., 2011, 2, 95–100 | 95

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EDITORIAL STAFF Editor Sarah Ruthven Deputy editor Kathleen Too

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Senior publishing editor Gisela Scott

Food & Function provides a dedicated venue for research relating to the chemical and physical properties of food components and their nutritional and health benefits in humans.

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Food & Function

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EDITORIAL BOARD Editor-in-Chief Professor Gary Williamson, University of Leeds, UK Associate Editors Cesar Fraga, University of Buenos Aires, Argentina & University of California, Davis, USA Steven Feng Chen, The University of Hong Kong, China

For pre-submission queries please contact Sarah Ruthven, Editor. E-mail [email protected] Food & Function (print: ISSN 2042-6496; electronic: ISSN 2042-650X) is published 12 times a year by the Royal Society of Chemistry, Thomas Graham House, Science Park, Milton Road, Cambridge, UK CB4 0WF. All orders, with cheques made payable to the Royal Society of Chemistry, should be sent to RSC Distribution Services, c/o Portland Customer Services, Commerce Way, Colchester, Essex, UK CO2 8HP. Tel +44 (0)1206 226050; E-mail [email protected] 2011 Annual (print + electronic) subscription price: £1260; US$2344. 2011 Annual (electronic) subscription price: £1134; US$2108. Customers in Canada will be subject to a surcharge to cover GST. Customers in the EU subscribing to the electronic version only will be charged VAT. If you take an institutional subscription to any RSC journal you are entitled to free, site-wide web access to that journal. You can arrange access via Internet Protocol (IP) address at www.rsc.org/ip. Customers should make payments by cheque in sterling payable on a UK clearing bank or in US dollars payable on a US clearing bank. Periodicals postage paid at Rahway, NJ, USA and at additional mailing offices. Airfreight and mailing in the USA by Mercury Airfreight International Ltd., 365 Blair Road, Avenel, NJ 07001, USA. US Postmaster: send address changes to Food & Function, c/o Mercury Airfreight International Ltd., 365 Blair Road, Avenel, NJ 07001. All despatches outside the UK by Consolidated Airfreight. Advertisement sales: Tel +44 (0) 1223 432246; Fax +44 (0) 1223 426017; E-mail [email protected] For marketing opportunities relating to this journal, contact [email protected]

Members Aedin Cassidy, University of East Anglia, UK Kevin Croft, University of Western Australia, Australia Eric Decker, University of Massachusetts, USA Alejandro Marangoni, University of Guelph, Canada

Reinhard Miller, Max Planck Institute of Colloids & Interfaces, Germany Paul Moughan, Riddet Institute, Massey University, New Zealand Johan Ubbink, The Mill, Food Concept & Physical Design, Switzerland Fons Voragen, Wageningen, The Netherlands

ADVISORY BOARD Hitoshi Ashida, Kobe University, Japan Junshi Chen, Chinese Centre of Disease Control & Prevention, China E. Allen Foegeding, North Carolina State University, USA Vincenzo Fogliano, University of Napoli Federico II, Italy Mike Gidley, University of Queensland, Australia Chi-Tang Ho, Rutgers University, USA Richard Hurrell, ETH Zurich, Switzerland Peter Lillford, University of York, UK Rui Hai Liu, Cornell University, USA

Julian McClements, University of Massachusetts, USA Clare Mills, Institute of Food Research, UK John A. Milner, National Cancer Institute, National Institutes of Health, USA Brent Murray, University of Leeds, UK Patricia Oteiza, University of California at Davis, USA Augustin Scalbert, INRA, France Helmut Sies, University of Dusseldorf, Germany Leif Skibsted, University of Copenhagen, Denmark

David Stuart, The Hershey Company, USA Arthur Tatham, University of Wales Institute, Cardiff, UK Junji Terao, University of Tokushima, Japan George van Aken, NIZO Food Research, The Netherlands Erik van der Linden, TI Food & Nutrition, The Netherlands Jose Vina, University of Valencia, Spain Peter Wood, Agriculture and Agri-Food Canada, Canada

INFORMATION FOR AUTHORS Full details on how to submit material for publication in Food & Function are given in the Instructions for Authors (available from http://www.rsc.org/authors). Submissions should be made via the journal’s homepage: http://www.rsc.org/foodfunction. Authors may reproduce/republish portions of their published contribution without seeking permission from the RSC, provided that any such republication is accompanied by an acknowledgement in the form: (Original Citation)–Reproduced by permission of The Royal Society of Chemistry. This journal is © The Royal Society of Chemistry 2011. Apart from fair dealing for the purposes of research or private study for non-commercial purposes, or criticism or review, as permitted under the Copyright, Designs and

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PAPERS 117 Estimation of dietary intake of melanoidins from coffee and bread Vincenzo Fogliano and Francisco J. Morales*

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Melanoidins are widely distributed in the human diet and daily intake was calculated from its main contributors (coffee and cereals).

124 Normalization genes for quantitative RT-PCR in differentiated Caco-2 cells used for food exposure studies Robert A. M. Vreeburg,* Shanna Bastiaan-Net and Jurriaan J. Mes A set of normalization genes for Caco-2 cells is validated, and is used to detect changes in gene expression upon exposure to apple, tomato, broccoli and mushroom.

130 Function of Plectranthus barbatus herbal tea as neuronal acetylcholinesterase inhibitor Pedro L. V. Fale, Paulo J. Amorim Madeira, M. Helena Flor^encio, Lia Ascensa˜o and Maria Luısa M. Serralheiro* Herbal tea containing rosmarinic acid and other phenolic acid derivatives can reach the brain and act as low acetylcholinesterase inhibitors.

137 Interaction of dietary flavonoids with gamma-globulin: molecular property-binding affinity relationship aspect Fan Yang, Yaru Zhao, Guoyin Kai and Jianbo Xiao* The quenching effects of flavonoids on gamma-globulin fluorescence depended on the structures of the flavonoids.

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Food Funct., 2011, 2, 95–100 | 97

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Food & Function Linking the chemistry and physics of food with health and nutrition Food science and nutrition is a highly multidisciplinary area. We know it can be difficult to keep abreast of each other’s work, especially when there is not enough time in the day and the pile of work keeps growing. Wouldn’t it be great if there was a journal which pulled together high impact chemical and physical research linking to human health and nutrition? Just one platform to find what you need in the field, and reach exactly the right audience when you publish your work. Food & Function provides a dedicated venue for physicists, chemists, biochemists, nutritionists and other health scientists focusing on work related to the interaction of food components with the human body.

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MC10 2011 Downloaded on 09 February 2011 Published on 09 February 2011 on http://pubs.rsc.org | doi:10.1039/C1FO90003J

Tenth International Conference on Materials Chemistry (MC10) | 4 - 7 July 2011 | Manchester, UK

Poster and early bird deadline – 6 May 2011 The ‘MC’ conference series has provided a showcase for materials chemistry for almost two decades, and is the flagship event of the RSC’s Materials Chemistry Division. Recent editions of the MC series have been very successful: MC7, held in Edinburgh in 2005, attracted over 450 delegates; and MC8 saw 500 scientists present their work and network in central London. In 2009, the RSC was proud to incorporate MC9 into the scientific programme of the 42nd IUPAC World Congress (IUPAC 2009). Comprising 16 symposia across 5 of the congress’ 17 parallel sessions, MC9 reached an audience of over 2000 delegates. The series returns in 2011 to its traditional format as a standalone conference over four days, beginning at lunchtime on Monday 4 July and ending at lunchtime on Thursday 7 July. MC10 will appeal to academic and industrial scientists working on the chemistry, physics and materials science of functional materials.

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•  Advanced technologies and nanomaterials

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Food & Function

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C

Dynamic Article Links
ECG

BEAS-2B cells; 2C5 cells; HL-60 cells, A427, RTE

0.0001–1 mM

35

EGCG ¼ ECG

H2O2-treated human bladder urothelial cells UVA-induced HaCaT keratinocyte

10–40 mg ml1

36

ECG > EGCG

1–100 mM

37

ECG > EGCG

t-BOOH-treated HepG2 cells

10–25 mM

39

EGCG > ECG

Colon mucosa and tumor from human

30 mg ml1

46

ECG > EGCG

H2O2–induced Passage-2 NHNE cells

100 mM

47

ECG

IL-6-stimulated HepG2 cells TPA-treated mouse ear IL-17A-stimulated HGF cells

25 mM 1 mmol 50 mg ml1

50 49 48

EGCG > ECG EGCG > ECG EGCG > ECG

HCT-116 cells A549 cells 30.7b Ras 12 cells B[a]P-induced lung carcinogenesis

50 mM IC50 ¼ 50 mM IC50 ¼ 15 mM 4 mg

64 65 79 62

EGCG > ECG EGCG > ECG EGCG > ECG EGCG ¼ ECG

BEL-7404/DOX; CHRC5 cells; KB-C2 cells SCC7 cells

50–100 mM

80–82

EGCG > ECG

50 mM

63

ECG > EGCG

A172 glioblastoma cells

50 mM

76

ECG S EGCG

MCF-7, C57BL/6 mice

1 mM

75

ECG S EGCG

Rat liver and rat-1A cells chicken liver FAS

IC50 ¼ 12 mM IC50 ¼ 42 mM

66 67,68

EGCG > ECG ECG > EGCG

NCI-H460 cells HSC-2 cells

125 mM

87 103

ECG > EGCG

HCT-116 cells

50 mM

100

EGCG ¼ ECG

HCT-116 cells

50 mM

93

ECG > EGCG

DU145 cells

100 mM

102

ECG > EGCG

KATO III cells

26–500 mM

104

ECG > EGCG

HT1080 cells Thrombin-induced VSMCs

100 mg ml1 30 mM

109 110

ECG > EGCG ECG > EGCG

This journal is ª The Royal Society of Chemistry 2011

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Table 1 (Contd. ) Experimental models Molecular targets

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YMMP-7 activity YYphosphorylation of Met, ERK and Akt YPhosphorylation of ERK and Akt YNDP kinase activity YAdhesion and/or spreading YRibonuclease A (RNase A) enzymatic activity YCollagenase activity

Studied type

Dose

Reference

f Outcomes

MCF10A cells

IC50 ¼ 0.47 mM 0.65 mM

132 116

ECG > EGCG EGCG > ECG

DU145 cells MDA-MB-435 cells 3LL or B16F10 cells Cu(II)-ECG complex

110 mM 3.5 log M

EGCG ¼ ECG EGCG > ECG

46.7 mM

117 118 122,123 119

Prokaryotic and eukaryotic cell

100 mg ml1

111

ECG > EGCG

proliferation and growth than ECG via decreasing the proliferative gene NUDT6 level in HCT116 cells. However, ECG showed more effective in inducing apoptosis of DU145 and KATO III cells than EGCG by increasing ROS formation and TNFa release, respectively. Besides, ECG seems to better inhibit cell growth by blocking b-catenin, PDGF-Rb, ERb and FAS activity in different experimental systems. In HCT116 cells, ECG showed stronger antitumorigenic activity than EGCG by activating transcription factors (e.g. Egr-1, ATF-3) mediated anti-cancer gene expression, including TSP-1 and NAG-1. Nevertheless, EGCG-induced NAG-1 expression is regulated by p53. Recently studies also indicate that ECG had the strongest anti-invasion activity by reducing MMP-2 and MMP-9 activity and their activation by a direct inhibition of MT1-MMP.

EGCG > ECG

These studies suggest that ECG may be biologically more active than EGCG, and EGCG was not always the most potent chemopreventive agent among green tea catechins. While EGCG has been well studied and is known to have chemopreventive property in several cancer cells, but molecular mechanisms of ECG have not been well investigated. Therefore, research on the function of ECG is important for understanding its anti-tumor effect. Previous studies found that ECG more effective than EGCG induced apoptosis and increased cell cycle arrest by inhibiting bcatenin signaling and cyclin D1 expression in SSC-7 cells.63 Interestingly, EGCG may affect anti-tumorigenic activity in a cyclin D1-independent manner.126 EGCG induced apoptosis through increasing H2O2 generation, but not found in ECGinduced apoptosis in HSC-2 cells.103 It has been found that

Fig. 3 Schematic representation of ECG mediated intracellular signaling transduction pathways on carcinogenesis processes. : Induction of signaling cascades by ECG-regulated; ; inhibition of signaling cascades by ECG-regulated.

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Food Funct., 2011, 2, 101–110 | 107

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treatment with EGCG caused G1 arrest and apoptosis in LoVo cells, whereas ECG triggers just the former process.127 Another study displayed that ECG induced apoptosis of HCT116 cells by mediating NAG-1 expression via ATF3 in a p53-independent manner, but EGCG is involved in p53-induced NAG-1 expression.93 These are suggested by resent results, ECG seems to better modulate cell apoptosis in p53 mutant tumor cells. Therefore, these results suggest that ECG and EGCG display differences in anti-tumor mechanisms.

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7. Conclusions In green tea extract, the percentages of the main catechins are EGCG 10–15%, EGC 6–10%, and ECG 2–3%.128 However, high ECG (537.14 mg mL1) occurs in some pu-erh tea129 and pu-erh green tea (EGCG 7.689% and ECG 9.890%, respectively).130 It is clear that ECG can interfere with multiple cell signaling pathways and has multiple targets within the cells, which are likely to interact together to reduce the risk of carcinogenesis (initiation, promotion and progression stages). These mechanisms include (a) inhibition of phase 1 CYP enzymes, (b) induction of phase II detoxification and antioxidant enzymes, (c) anti-inflammatory efficacy (d) arrest of cell cycle progression, (e) regulation of proapoptotic properties and (f) mediation of metastasis processes (Fig. 2 and 3). Many of the anti-carcinogenic affects of ECG may be due to its direct and/or indirect interaction with numerous molecular targets,131 such as NAG-1, AP-1, 5a-reductase and PDGF. Importantly, these growth inhibitions of ECG have been shown to sensitize cancer cells, but not in normal cells. Despite the regulation of intracellular signaling pathways, ECG may also inhibit RNase A and MMPs enzymatic activity via chelating copper and zinc metals, which are important cofactors for angiogenesis and metastasis. Furthermore, structure function analysis revealed that the gallate moiety of ECG is important for mediating these inhibitory effects which these acts may enhance chemoprevention ability.

Abbreviations AP-1 ATF3 BMDCs CAMs CDK CDKIs Chk COX-2 EC ECG EGCG EGC EGF EGFR EGR-1 ER ERK FAS FGF-2

Activator protein-1 Activating transcription factor 3 Bone marrow-derived cells Cell adhesion molecules Cyclin-dependent kinase Cdk inhibitors Check point kinases Cyclooxygenase-2 ()-Epicatechin Epicatechin-3-gallate ()-Epigallocatechin-3-gallate ()-Epigallocatechin Epidermal growth factor Epidermal growth factor receptor Early growth response gene-1 Estrogen receptor Extracellular-signal-regulated kinase Fatty acid synthase Fibroblast growth factor-2

108 | Food Funct., 2011, 2, 101–110

GSH-Px GST HGF hnRNPB1 HO-1 H2O2 IL iNOS JNK MAPK MCT MMP MT1-MMP NAG-1

Glutathione peroxidase Glutathione-S-transferase Hepatocyte growth factor Heterogeneous nuclear ribonucleoprotein B1 Heme oxygenase-1 Hydrogen peroxide Interleukin Inducible nitric oxide synthase Jun amino-terminal kinase Mitogen activated protein kinase Monocarboxylate transporter Matrix metalloproteinase Membrane-type matrix metalloproteinases-1 Non-steroidal anti-inflammatory drug (NSAID) activated gene-1 Nucleoside diphosphate kinase Nuclear factor-kB Nitric oxide NAD(P)H:quinone oxidoreductase 1 Nuclear factor erythroid 2 p45 (NF-E2)related factor 2 Nudix (nucleoside diphosphate linked moiety X)-type motif 6 Platelet-derived growth factor Phosphatidylinositol-3-kinase Prostaglandins P-Glycoprotein Poly(ADP-ribose) polymerase Phosphatase and tensin homolog Retinol binding protein Reactive oxygen species Reactive nitrogen species Ribonuclease A Superoxide dismutase Thiobarbituric acid reactive substances tert-Butylated hydroperoxide T-cell factor Transforming growth factor- b Tissue inhibitor of metalloproteinase Tumor necrosis factor- a 12-O-Tetradecanoyl-phorbol-acetate Transthyretin Vascular endothelial growth factor Vascular smooth muscle cells

NDPK-B NF-kB NO NQO1 Nrf2 NUDT6 PDGF PI3K PGs P-gp PARP PTEN RBP ROS RNS RNase A SOD TBARS t-BOOH TCF TGF-b TIMP TNF-a TPA TTR VEGF VSMCs

References 1 D. L. McKay and J. B. Blumberg, J. Am. Coll. Nutr., 2002, 21, 1. 2 J. Ju, G. Lu, J. D. Lambert and C. S. Yang, Semin. Cancer Biol., 2007, 17, 395. 3 C. Han and Y. Gong, Wei Sheng Yan Jiu, 1999, 28, 343. 4 M. H. Ravindranath, V. Ramasamy, S. Moon, C. Ruiz and S. Muthugounder, Evid. Based. Complement Alternat. Med., 2009, 6, 523. 5 T. Ohe, K. Marutani and S. Nakase, Mutat. Res., Genet. Toxicol. Environ. Mutagen., 2001, 496, 75. 6 K. M. Ku, J. Kim, H. J. Park, K. H. Liu and C. H. Lee, J. Agric. Food Chem., 2010, 58, 345. 7 T. D. Way, H. Y. Lin, D. H. Kuo, S. J. Tsai, J. C. Shieh, J. C. Wu, M. R. Lee and J. K. Lin, J. Agric. Food Chem., 2009, 57, 5257.

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