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Food Science and Technology Bulletin Functional Foods Volume 3 CHIEF EDITOR Professor Glenn R Gibson University of Reading Reading,UK EDITORIAL ADVISORY BOARD Dr Eric Decker University of Massachusetts Amherst,USA Dr Edward Farnworth Food Research and Development Centre St.Hyacinthe,Canada Dr Clare Hasler Robert Mondavi Institute for Wine and Food Science University of California,Davis,USA Dr David P Richardson dprnutrition Croydon,UK Dr Colette Shortt McNeil Nutritionals London,UK Dr Tiina Mattila-Sandholm Valio Ltd,Finland Food Science and Technology Bulletin: Functional Foods comprises a minimum of eight minireviews per year. It is published as an annual review journal by IFIS Publishing, Lane End House, Shinfield Road, Shinfield, Reading RG2 9BB, UK. Tel. +44 118 988 3895. Fax +44 118 988 5065. Email [email protected]. Web: www.foodsciencecentral.com. Charity registration no. 1068176. ISSN 1476-2137 ISBN 978-0-86014-172-3 Copyright © 2007 IFIS Publishing. All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, without the prior permission of the copyright owner. The information contained herein, including any expression of opinion and any projection or forecast, has been obtained from or is based upon sources believed by IFIS Publishing to be reliable, but is not guaranteed as to accuracy or completeness. The information is supplied without obligation and on the understanding that any person who acts upon it or otherwise changes his/her position in reliance thereon does so entirely at his/her own risk. 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Volume 3 Contents 1 Nutrigenomics – new frontiers in antioxidant research 1 Jan Frank, Sonia de Pascual Teresa and Gerald Rimbach 2 Dietary fat composition and cardiovascular disease 13 Anne M. Minihane 3 Phytochemicals – a future in functional foods? 23 Toni E. Steer 4 Inulin: a prebiotic functional food ingredient 31 Duncan T. Brown and Kieran M. Tuohy 5 SPECIAL PAPER 47 Probiotics – the consumer perspective Liisa Lähteenmäki and Aat M. Ledeboer 6 Assessment of the efficacy of probiotics, prebiotics and synbiotics in swine nutrition: 51 a review Konstantinos C. Mountzouris 7 Lactitol, an emerging prebiotic: functional properties with a focus on digestive health 73 Alexandra Drakoularakou, Oliver Hasselwander, Melanie Edinburgh and Arthur C. Ouwehand 8 Guidelines for an evidence-based review system for the scientific justification of diet and 83 health relationships under Article 13 of the new European legislation on nutrition and health claims David P. Richardson, Nino M. Binns and Penelope Viner Nutrigenomics – new frontiers in antioxidant research Jan Frank1, Sonia de Pascual Teresa2 and Gerald Rimbach1* 1Christian-Albrechts-University, Institute of Human Nutrition and Food Science, Hermann-Rodewald-Str. 6, 24118 Kiel, Germany. Tel. þ49 (0)431-880 2583. Fax þ49 (0)431-880 2628. E-mail [email protected] 2Department of Plant Food Science and Technology, Instituto del Frı´o (CSIC), Jose Antonio Novais, 10, 28040 Madrid, Spain. *Corresponding author Abstract The field of nutrition research evolved over the last two and a half centuries from studying the basics of nutritional physiology(e.g.nutrient digestion) toa highlyadvanceddisciplineemploying state-of-the-art tech- niques to elucidate the role of dietary compounds in the maintenance of health and prevention of disease. In this context, nutrigenomics is a rapidly growing field making use of molecular biology methodologies, such as microarray technology, to study how specific nutrients or diets affect gene expression. The mode of opera- tionofDNAmicroarraytechnologyand itsapplicationsinantioxidantresearchare discussed,andrecentpub- lications reporting the use of DNA microarrays to investigate various aspects of the biological activities of oxidants andantioxidants are reviewed. Keywords: antioxidants, ascorbic acid, gene array, genomics, metabolomics, nutrigenetics, nutrigenomics, oxidants,oxidative stress, proteomics, tocopherol,transcriptomics 1. Introduction in 2001 (McPherson et al. 2001; Venter et al. 2001) fol- lowed shortly afterwards by the sequencing of the mouse The dawn of the discipline of nutrition research falls (Okazaki et al. 2002; Waterston et al. 2002) and rat geno- around the time of the ‘chemical revolution’ at the end of mes (Gibbs et al. 2004). Now, at the advent of the post- the 18th century. Pioneering work was performed with the genomic era, nutrition research has been given powerful simple scientific tools available at that time to describe tools to study the complex interplay of diet and/or specific macronutrients, energy production and respiration. In the nutrients with the genetic makeup and health of indivi- course of the 19th century the connections between poor duals, as well as entire populations. nutrition and certain disorders, such as scurvy and goitre, started to become apparent, but remained, nevertheless, a matter of dispute among the members of the medical 2. Defining the ‘-omics’ society (Carpenter 2003a). Shortly after the turn of the Rapid advancement in the development of high-through- 20th century the ‘golden age of nutrition’ commenced, and put, molecular biology techniques and their frequent appli- this lasted well into the 1940s. During this period most cation in system-wide experimental approaches have led essential nutrients (and almost all vitamins) were discover- to a noticeable propagation of the so-called ‘-omics’ (e.g. ed andnutritionists focused on studying diseases associated genomics,transcriptomics,proteomics,metabolomics,etc.). with the deficiency of a single nutrient (Carpenter 2003b). Nutritionists are now making increasing use of these state- During the following decades the focus of nutrition re- of-the-art technologies in order to study the molecular search shifted from nutritional deficiency to over-nutrition, basis of the health effects of specific components of the and scientists started to unravel the complex relationships diet. The term ‘nutrigenomics’ – short for nutritional between diet and the development of multi-factorial genomics–referstothestudyoftheimpactofspecificnutri- chronic diseases (Carpenter 2003c). Subsequently, the entsordietsongeneexpression.Itisnottobeconfusedwith revolutionary progress in recombinant DNA technology ‘nutrigenetics’, which investigates how genetic variability culminated in the sequencing of the entire human genome influences the body’s response to a nutrient or diet. Hence, nutrigenomics and nutrigenetics are closely related dis- FoodScienceandTechnologyBulletin:FunctionalFoods3(1)1–12 ciplines but approach the interplay of diet and genes DOI:10.1616/1476-2137.14276.Published27February2006 ISSN1476-2137#IFISPublishing2006.AllRightsReserved from opposing starting points. Nutrigenomics is an up and 2 Nutrigenomics–newfrontiersinantioxidantresearchJ.Franketal. coming discipline that makes use of high-throughput, 3. The eukaryotic gene transcription machinery molecular biology techniques such as transcriptomics, pro- The genome of eukaryotic organisms is packaged in the teomicsand metabolomics (Figure 1). The term ‘genomics’ cell nucleus where it is arranged in chromosomes, which, refers to the study of all nucleotide sequences in the chro- in turn, are built from a single DNA macromolecule. The mosomes – the ‘genome’ – of an organism. It can be genetic information stored in the chromosomes serves as a divided further into ‘structural genomics’ (DNA sequence ‘construction plan’ for important biomolecules, more pre- analysis and mapping of the genome of an organism) and cisely, polypeptides and proteins. The amino acid sequence ‘functional genomics’ (system-wide experimental appro- of a given protein is encoded in the sequence of nucleo- aches to study gene function). The term ‘transcriptomics’ tides on the DNA of the gene coding for that protein. is used to describe methods that measure the relative Each of the 20 proteinogenic amino acids is coded for by amounts of messenger RNA (mRNA) in order to deter- a sequence of 3 nucleotides, a phenomenon that is highly mine patterns and levels of gene expression, and their reg- conserved among species (i.e. the same sequence of 3 ulation. ‘Proteomics’ is the study of the expression of the nucleotides codes for the identical amino acid in almost complete set of proteins expressed in a cell, tissue, or all species) and is referred to as the (universal) ‘genetic organism and, accordingly, ‘metabolomics’ investigates code’. Since the genetic information is stored in the cell the profile and functions of all metabolites generated in a nucleus while proteins are synthesized on ribosomes in the simple (e.g. cell) or complex (e.g. entire-organ or organ- cytoplasm, this information needs to be transferred to ism) system. Some scientists distinguish between these 2 smaller molecules (messenger RNA; mRNA) that serve as approaches and refer to the study of metabolite formation templates for the synthesis of proteins. The process of in a simple system as ‘metabolomics’ and in a complex synthesis of single-stranded RNA from the double- system as ‘metabonomics’. The vast amount of data gener- stranded DNA macromolecule is called ‘transcription’ and ated with such system-wide approaches requires the appli- is facilitated by specific enzymes, namely RNA polymer- cation of advanced bioinformatics tools in order to manage ases. Following export from the nucleus mRNA becomes comprehensive data handling. associated with ribosomes – supramolecular enzyme com- The first book about nutrigenomics has recently been plexes that catalyse the assembly of polypeptides – within published, covering a wide variety of aspects relating to the cytoplasm. The process of protein synthesis from an the effects of oxidants and antioxidants on gene expression mRNA template is called ‘translation’. Following synth- and their role in health and disease. For further informa- esis, proteins undergo a range of post-translational modifi- tion on nutrigenomics the interested reader is referred to cations in order to become fully functional proteins. Such this comprehensive book (Rimbach et al. 2005) and the modifications may include one or more of the following: excellent reviews that have been published on this subject cutting of the polypeptide by specific enzymes, addition of (e.g. Elliott and Ong 2002; van Ommen and Stierum functionalgroups(e.g.phosphate,methyl,oracetategroups), 2002; Ordovas and Mooser 2004; Muller and Kersten formation of disulfide bridges, etc. Thus, the flow of 2003). genetic information goes from DNA via RNA to protein (see biochemistry textbooks for details, e.g. Stryer 1995). 4. Methods and applications of nutrigenomics For a long time, the expression of individual genes has been determined by quantification of RNA with Northern blotting. This classical approach has been replaced by more sensitive techniques such as real-time reverse tran- scription PCR (real-time RT-PCR). Both techniques, how- ever, can only analyse gene expression for a limited num- ber of candidate genes at a time. The development of DNA microarray technology has rendered it possible to determine the expression of thousands of genes, or even entire genomes, simultaneously. The operating principle of DNA microarrays relies on the base pairing of oligonu- cleotides within a sample with known immobilized oligo- nucleotides, on a support material (e.g. glass slides). The use of representative oligonucleotides rather than the entire Figure 1. Transcriptomics, proteomics, and metabolomics nucleotide sequence of a given gene allows for a higher as analytical tools in nutrition research. density (larger number) of probes and a smaller overall Nutrigenomics–newfrontiersinantioxidantresearchJ.Franketal. 3 size of the microarray. A typical DNA microarray experi- tion of these 2 approaches guarantees microarrays that ment follows a characteristic series of steps: produce data of very high quality. Since it is beyond the scope of this paper to describe in (cid:2) RNA extraction from a sample detail all the available variants of microarray technology, (cid:2) Reverse transcription of the RNA in order to obtain the interested reader is referred to the comprehensive book complementary DNA (cDNA) followed by: edited by Schena (1999), who has been a pioneer in the * Labelling of the cDNA with specific dye(s) development of DNA microarray technology, and to the (usuallyfluorophores,suchasCyanine3and5),or excellent reviews of Elliott et al. (2004), Liu-Stratton * Reverse transcription of the cDNA in order to et al. (2004), and Spielbauer and Stahl (2005) for a more obtain cRNA and labelling of the cRNA detailed description of microarray technology and its (cid:2) Hybridization of the labelled cDNA or cRNA onto numerous applications in nutrition and food research. the microarray under defined conditions (e.g. time, A single microarray experiment results in an enormous temperature, etc.) amount of gene expression data, which should be scruti- (cid:2) Washing of the slides to remove non-hybridized nized for evidently flawed results. The remaining data labelled oligonucleotides points need to be normalized (e.g. for background signal, (cid:2) Signal detection (e.g. using an appropriate scanning dye intensity, array-to-array variations, etc.) before com- device) parative analyses of the obtained data can be accom- (cid:2) Data analysis (Figure 2). plished. The huge number of data points generated during microarray experiments also requires careful selection and Modifications of this general approach were adopted by 1 application of mathematical and statistical procedures in Affymetrix during the development of their GeneChip 1 order to detect changes in gene expression. Indeed, data arrays. On Affymetrix GeneChip arrays, several different processing with sophisticated bioinformatics tools and the oligonucleotideprobesarephotolitographicallyspottedonto identification of (truly and not arbitrarily) differentially quartz wafers for each gene. Furthermore, for each nucleo- expressed genes in response to a specific nutrient or diet tide sequence (probe) designed to match a specific target certainly pose the greatest challenges in the application of sequence, a second, almost identical probe is synthesized, microarray technology in the field of nutrigenomics. which differs in only one base in the centre of the nucleo- Because of the complexity of the data generated and the tide sequence. This allows the quantification and subtrac- plethora of factors that may affect the outcome of micro- tion of non-specific cross-hybridization, and the combina- array experiments (such as differences in experimental design (e.g. treatment), RNA extraction protocols, hybridi- zation conditions, or normalization procedures, to name a few) a grass-rootsmovement, the Microarray Gene Expres- sion Database Society (MGED), has established itself in an attempt to develop standards for data handling (Brazma et al. 2001). An additional problem with microarray experiments that makes the comparison of gene expression data generated in different laboratories difficult, is the out- put of the data in a number of different formats and units. DNA microarrays are a comparatively new tool for the quantification of gene expression. Hence, there has been a lackofstandardstofollowforobtainingmeaningfulpresen- tationofdata.Suchstandardizationwouldallowmicroarray data to be easily interpreted, experiments to be reproduced, and would assist in the establishment of gene expression databases.Inanefforttocreatesuchguidelines,theMGED group has formulated the ‘minimum information about a microarray experiment (MIAME)’ that should be recorded and reported when referring to microarray data (Brazma etal.2001).TheMGEDconsortiumidentified6crucialparts ofamicroarrayexperimentthatshouldbecarefullydescribed usingcontrolledvocabularies: Figure 2. Schematic representation of the analytical steps (cid:2) Experimental design involved in a gene chip experiment. (cid:2) Array design 4 Nutrigenomics–newfrontiersinantioxidantresearchJ.Franketal. Minimum information about a microarray experiment Part 1: Experimental design. Description of the experiment, contact details of the author/submitter, title. Information given in this section should enable the user to reconstruct the experimental design. Part 2: Array design. Systematic description of all arrays used in the experiment, includingthephysicaldesignandthegenesrepresented.Detailedspecificationof(1)array as a whole (e.g. support material); (2) each type of element or spot (e.g. synthesized oligonucleotides); and (3) properties of each element (e.g. DNA sequence). Part3:Samples.Descriptionofthelabellednucleicacidsusedforhybridization.Detailed information on source of sample (such as organism or cell type), treatment(s) applied, as well as extraction and labelling of the nucleic acids. Part 4: Hybridization. Description of hybridization procedure (hybridization solution, blocking agent, washing procedure, quantity of labelled target used, hybridization time, volume, temperature, apparatus). Part 5: Measurements. Descriptionoftheexperimentalresultsbyprovidingimagesof theoriginalarrayscans,thequantificationmatricesbasedonimageanalysis,andthefinal geneexpressionmatrixafternormalization.Thereportedinformationshouldfacilitatethe comprehension of the image analysis performed and the underlying methodology (e.g. calculations). Part 6: Normalization controls. Specification of normalization strategy (e.g. housekeepinggenes),normalizationandqualitycontrolalgorithms,identitiesandlocation of the array elements used as controls, and hybridization extract preparation. Source: Brazma et al. 2001 (cid:2) Samples 2 different forms (natural and synthetic) of vitamin E that (cid:2) Hybridization are frequently employed as ingredients in vitamin E and (cid:2) Measurements multi-vitamin supplements. As a model system, HepG2 (cid:2) Normalization controls (see Textbox; Brazma et al. cells were used and supplemented with increasing concen- 2001). trations (0–300 mM) of natural-source RRR-a-tocopherol and synthetic all rac-a-tocopherol for 7 days. Genes that The innovative tools of nutrigenomics, especially gene were dose-dependently up- or down-regulated were identi- arraytechnology,maybeusedtodevelopnovelapproaches fied by global gene expression profiling. Analysis of the for the study of the biological functions of oxidants and microarray data revealed that both forms of the vitamin antioxidants. DNA microarrays, for example, allow the induced or repressed an identical set of 215 genes. The genome-wide scanning for effects of nutrients without the authors recorded the concentrations of RRR- and all necessity to limit one’s attention to one or more specific rac-a-tocopherol in the cell media that were necessary to target gene(s), thus reducingthe risk of failure to recognize produce a 50% induction (EC ) or 50% inhibition (IC ) 50 50 a biological effect. Therefore, nutrigenomics may help in of gene expression. They then calculated a biopotency clarifying the molecular functions of oxidants and antioxi- ratio for each of the 215 genes by dividing the EC and 50 dants. Nutrigenomics may also serve to characterize the IC values for RRR-a-tocopherol by those for all rac-a- 50 toxicity of dietary compounds or to identify and establish tocopherol.Themeanvalueobtainedforall215biopotency new biomarkers. One example could be the development ratios was 1.05, which led the authors to conclude that of reliable biomarkers for oxidative stress, which is an as there appears to be no difference in the gene-regulatory yet unresolved task. Another novel application of microar- activity of natural-source RRR-a-tocopherol and that of its ray technology could be the study of the bioavailability syntheticanalogueallrac-a-tocopherol(Mulleretal.2005). and/or bioactivity/biopotency of nutrients. In this context, This study shows that gene microarray technology can be Muller and co-workers (2005) have recently reported successfully employed to determine and compare the bio- 1 the use of Affymetrix GeneChip technology to assess logical activities and potencies of antioxidants and other the biopotency, based on their gene-regulatory activity, of nutrients. As can be derived from the above, the potential Nutrigenomics–newfrontiersinantioxidantresearchJ.Franketal. 5 applications of nutrigenomics and particularly transcrip- tomics in the field of antioxidant and free radical research are manifold. 5. How do oxidants and antioxidants affect gene expression? The application of molecular and cell biology in nutrition research has enhanced our understanding of how antioxi- dants exert their biological functions. By altering the activity of transcription factors, oxidants and antioxidants may markedly alter mRNA and protein concentrations. Another mechanism by which they may affect gene ex- pression is by binding to cell receptors (e.g. isoflavones (phyto-oestrogens) bind to oestrogen receptors alpha and beta) and altering the activity of key enzymes such as Figure 3. Cell receptors, cellular key enzymes, and tran- phosphatases and kinases (Figure 3). scription factors as molecular targets of oxidants and anti- Vitamin E, the major lipophilic antioxidant in the body oxidants. (Burton et al. 1982), is a good example of an antioxidant whose role in gene expression is currently being unra- velled. Vitamin E is a generic term for 8 structurally was also shown to modulate the gene expression of seve- related compounds, namely a-, b-, g-, and d-tocopherols ral proteins at the transcriptional level. For example, the and -tocotrienols, consisting of a chroman head substituted mRNA levels of the following proteins were shown to be with a saturated (tocopherols) or unsaturated (tocotrienols) up-regulated by vitamin E: a-tocopherol transfer protein 16-carbon side-chain (Kamal-Eldin and Appelqvist 1996). (Fechner et al. 1998), protein kinase C (Azzi et al. 1998), Vitamin E was initially recognized as an essential nutrient a-tropomyosin (Aratri et al. 1999), cytochrome P 3A4 450 for successful reproduction of rats (Evans and Bishop and3A5(Landesetal.2003),andconnectivetissuegrowth 1922). Some decades later its antioxidant properties were factor (Villacorta et al. 2003). Conversely, the mRNA discovered (Dam 1952) and, for a long time, thought to be levels for interleukin-1 (Akeson et al. 1991), collagenase the prime function of the vitamin. In 1991, however, Bos- (Chojkier et al. 1998), and scavenger receptor-A (Teupser coboinik and co-workers were the first to report biological et al. 1999) were down-regulated. Recently, a vitamin E- activitiesofa-tocopherolthatwerenotrelatedtoitsantiox- dependent transcription factor, tocopherol associated pro- idant capacity. In particular, they described the inhibition tein (TAP), has been described which specifically binds of protein kinase C in smooth muscle cells by a-tocopherol a-tocopherol but not the other vitamin E isoforms. Upon as the first evidence of a role for vitamin E in cellular sig- binding of a-tocopherol, TAP, which is also known under nalling (Boscoboinik et al. 1991). Subsequently, vitamin E the name of ‘supernatant protein factor’, translocates from Table 1. Studies on the effects of oxidative stressors on differential gene expression in cultured cells, laboratory animals and humans Oxidant Cell/Tissue Species Number ofgenes Reference monitored Cigarette smoke Swiss3T3 Mouse 513 (Bosioetal.2002) Hydrogenperoxide Breast cancer cells Human 17000 (Chuang etal.2002) Menadione t-Butylhydroperoxide Hydrogenperoxide Retinal pigmentepithelium cells Human 1176 (Weigel etal.2003) 4-Hydroxynonenal t-Butylhydroperoxide Oxidized LDL Aortic smoothmuscle cells Human 35932 (Sukhanov etal.2003) Oxidized LDL Endothelial cells Human 588 (Virgilietal.2003) Ozone Lung Mouse 4000 (Gohil etal. 2003) UVB radiation Keratinocytes Human 6000 (Sesto etal.2002) 6 Nutrigenomics–newfrontiersinantioxidantresearchJ.Franketal. Table 2. Studies on the effects of antioxidants on differential gene expression in cultured cells, laboratory animals and humans Antioxidant Cell/Tissue Species Numberof genes Reference monitored Ascorbicacid Keratinocytes Human 588 (Catani etal. 2002) Ascorbicacid Monocytes Human 256 (Majewicz etal. 2005) CoenzymeQ10 Skeletal muscle Human 12000 (Linnane etal. 2002) Copper Macrophages Human 6800 (Svensson etal. 2003) Epigallocatechin-3-gallate Cervical cancer cells Human 384 (Ahn etal.2003) Epigallocatechin-3-gallate Lungcancer cells Human 588 (Fujiki etal. 2001) Epigallocatechin-3-gallate Lungcancer cells Human 588 (Okabe etal. 2001) Epigallocatechin-3-gallate Prostatecarcinoma cells Human 250 (Wang andMukhtar 2002) Epigallocatechin-3-gallate Neuroblastoma cells Human 25 (Weinreb etal. 2003) Melatonin Ginkgobiloba Brain Rat 8000 (Li etal.2003a) Ginkgobiloba Brain Mouse 7000 (Watanabe etal.2001) Genistein Prostatecancer cells Human 557 (Suzuki etal.2002) Indole-3-carbinol Prostatecancer cells Human 22215 (Li etal.2003c) Lycopene Prostate Rat 7000 (Siler etal.2004) VitaminE Melatonin Retina Rat 24000 (Wiechmann 2002) Methylseleninic acid Premalignantbreast cells Human 316 (Dong etal. 2002) Proanthocyanidin extract Endothelial cells Human 2400 (Bagchi etal.2002) from grapeseed Procyanidins frompine bark Keratinocytes Human 588 (Rihn etal. 2001) Resveratrol Prostatecancer cells Human 2400 (Narayanan etal. 2003) Selenium Mammaryepithelial organoids Rat 588 (Dong etal. 2001) Selenium Intestine Mouse 6347 (Rao etal. 2001) Sulphoraphane Smallintestine Mouse 6000 (Thimmulappa etal. 2002) VitaminA Airway tissues Human 30000 (Soref etal. 2001) VitaminA andEand selenium Skeletal muscle Rat 800 (Sreekumar etal. 2002) VitaminD3 Osteosarcoma cells Rat 5000 (Farach-Carson and Xu2002) VitaminD3 Prostatecancer cells Human 20000 (Krishnan etal.2003) VitaminD3 Kidney Mouse 12422 (Li etal.2003b) VitaminE Liver Rat 7000 (Barella etal. 2004) VitaminE Aortic smoothmuclecells Human 10000 (Villacorta etal.2003) VitaminE(tocotrienol) Foetal brains Rat 8000 (Roy etal. 2002) VitaminE(RRR- and HepG2 hepatocarcinoma cells Human 14500 (Muller etal. 2005) all rac-a-tocopherol) VitaminEand selenium Liver Rat 465 (Fischer etal. 2001) Zinc Mucosacells ofsmall intestine Rat 1185 (Blanchard etal. 2001) Zinc Liver Rat 2500 (tom Dieck etal.2003) the cytosol to the nucleus where it activates gene expres- to concentrations of other well-known signalling molecules sion (Yamauchi et al. 2001). A non-antioxidant derivative suchasinositolphosphate,itseemsimplausiblethata-toco- of a-tocopherol, a-tocopheryl-phosphate, has been reported pheryl-phosphate serves as a storage form of vitamin E to be a more potent inhibitor of both mRNA and total (Gianelloetal.2005;Negisetal.2005).Instead,ithasbeen protein expression for the scavenger receptor CD36 in proposed that a-tocopheryl-phosphate may act as a signal- humanand rat cell lines, compared tothe parent compound lingmolecule(Negisetal.2005).Inorderfora-tocopheryl- a-tocopherol (Munteanu et al. 2004). Since a-tocopheryl- phosphate to be an effective part of a signalling cascade, phosphate is present in tissues at minute concentrations however, its synthesis and decomposition need to be under (100–250 ng/g tissue) which are much lower than those of the control of suitable kinases and phosphatases. Although a-tocopherol (approximately 10 g/g tissue) but comparable preliminary evidence for the existence of such kinase and Nutrigenomics–newfrontiersinantioxidantresearchJ.Franketal. 7 targets in gene expression (Sen and Packer 1996). NF-kB regulates the expression of genes that are involved in inflammation and cell proliferation. Again, supplemental vitamin E has been shown to inhibit NF-kB in vitro, for example in Kupffer cells (Fox et al. 1997), as well as in vivo in Sprague-Dawley rats (Calfee-Mason et al. 2002). Thus, evidence is accumulating that antioxidants (e.g. vitamin E, carotenoids, ascorbic acid (vitamin C), lipoic acid, flavonoids, and extracts of ginkgo biloba, as well as trace elements like zinc and selenium) and oxidative stress (induced by e.g. ozone, cigarette smoke, UV radiation, or oxidized low-density lipoprotein (LDL)) markedly affect gene expression in cultured cells, animals, and humans (Table 1, Table 2). Most experiments to study the effects Figure 4. Antioxidants as free radical scavengers, metal of antioxidants on gene expression have been performed chelators, and redox signalling molecules. Prevention of in cell culture or model animals. However, the impact of oxidativedamagetowardslipids,proteinsandDNA,aswell antioxidantsupplementtreatmentondifferentialgeneexpres- as redox signalling contribute to their potential beneficial sion has recently been investigated in human volunteers effectswithregardtodegenerativedisorders. with a heterozygous apolipoprotein E4 (apoE4) genotype by use of cDNA array technology (Majewicz et al. 2005). phosphatase activities has been published (Gianello et al. Supplementation with 60 mg/d ascorbic acid for 4 weeks 2005; Negis et al. 2005), the actual existence of enzymes increased circulating plasma vitamin C concentrations by thatspecificallyphosphorylatetocopherolsanddephosphor- 43% in smokers, but had no effect in non-smokers. How- ylate tocopheryl-phosphates needs to be verified, and their ever, baseline concentrations of vitamin C were signifi- regulationandactivitiesneedtobecharacterized. cantly lower in smokers compared to non-smokers and did In cell culture experiments, it has been demonstrated not entirely reach the levels observed in non-smokers, that vitamin E inhibits inflammation, cell adhesion, plate- even after supplementation. Corresponding to the observed let aggregation, and smooth muscle cell proliferation, and alterations in plasma levels of the vitamin, ascorbic acid that many of these cellular functions are independent of treatment down-regulated the expression of genes related the antioxidant properties of the vitamin (Rimbach et al. toinflammatoryresponse(tumournecrosisfactorb,tumour 2002). However, the intracellular balance of oxidants and necrosis factor receptor, neurotropin-3 growth factor antioxidants, and hence the reduction-oxidation (redox) receptor, and monocyte chemoattractant) in monocytes of state within the cell, has also been proven to be a key fac- apoE4 smokers but not in non-smokers. Thus, the authors tor in the regulation of the expression of certain genes. identified vitamin C responsive genes which appear to be The transcription factors nuclear factor-kB (NF-kB) and centrally involved in processes leading to inflammation activator protein-1 are 2 examples of such redox-sensitive and atherogenesis, and which may explain, on a molecular Table 3. Proteomics studies on the effects of oxidative stressors in cultured cells, laboratory animals and humans Oxidant Cell/Tissue Species Reference Benzo[a]pyrene Amnionepithelial cells Human (Gao etal.2004) Cigarette smoke Aortic endothelialcells Human (Raveendran etal.2005) Hydrogenperoxide Cardiac myocytes Human (Brennan etal.2004) HepG2 hepato-carcinoma cells Human (Cesaratto etal.2005) Peripheral bloodmononuclear cells Human (Fratelli etal.2002) Fibroblastcells Hamster (Keightley etal.2004) Epithelial lenscells Human (Paronet al.2004) Leukaemia cells Human (Seong etal. 2002) Heart membrane Rabbit (Sethuraman etal.2004) Ionizing radiation Liver Mice (An etal.2004) Oxidized LDL Monoblastic leukaemiacells Human (Yu etal.2003) Promyelomonocytic cells Human (Fach etal.2004) Endothelial cells Human (Fuchs etal. 2005a,2005b) Ozone Airway epithelium Rat (Wheelock etal.2005)

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