ORIGINAL ARTICLE

The role of nutrigenomics in obesity

Barbara Bobrowska-Korczak¹ , Dorota Skrajnowska¹ , Aleksandra Orzoł¹

1. Zakład Bromatologii, Warszawski Uniwersytet Medyczny,

Published: 2017-12-28

DOI: 10.5604/01.3001.0010.7602

GICID: 01.3001.0010.7602

Available language versions: en pl

Issue: Postepy Hig Med Dosw 2017; 71 : 1080-1088

Abstract

Obesity and overweight is an emerging health problem of growing importance, and much promise for the prevention and treatment of this disease is connected with nutrigenomics. Nutrigenomics corresponds to the use of biochemistry, physiology, bromatology, genomics, proteomics, metabolomics and epigenomics to seek and explain the existing reciprocal interactions between genes and nutrients at a molecular level. It is directed toward determining the effect of nutrients on the expression of genes and identifying the role of genetic variation and individual dietary response. This review describes the results of the current research into the significance of nutrigenomics in obesity.

References

1. Cominetti C., de Bortoli M.C., Purgatto E., Ong T.P., Moreno F.S, Garrido A.B.Jr., Cozzolino S.M.: Associtions between glutathione peroxidase-1 Pro198Leu polymorphism, selenium status, and DNA damage levels in obese women after consumtion of Brazil nuts. Nutrition, 2011; 27: 891-896
Google Scholar
2. Dembiński A., Warzecha Z.: Grelina – hormon żarłoczności? Kosmos, 2010; 59: 297-304
Google Scholar
3. Deram S., Villares S.M.: Genetic variants influencing effectiveness of weight loss strategies. Arq. Bras. Endocrinol. Metabol., 2009; 53: 129-138
Google Scholar
4. Dżygadło B., Łepecka-Klusek C., Pilewski B.: Wykorzystanie analizy impedancji bioelektrycznej w profilaktyce i leczeniu nadwagi i otyłości. Probl. Hig. Epidemiol., 2012; 93: 274-280
Google Scholar
5. Elliott R.M., Johson I.T.: Nutrigenomic approaches for obesity reserach. Obes. Rev., 2007; 8: 77-81
Google Scholar
6. Fench M., El-Sohemy A., Cahill L., Ferguson L.R., French T.A.C., Tai E.S., Milner J., Koh W.P., Xie L., Zucker M., Buckley M., Cosgrove L., Lockett T., Fung K.Y., Head R.: Nutrigenetics and nutrigenomics: viewpoints on the current status and applications in nutrition research and practice. J. Nutrigenet. Nutrigenomics, 2011; 4: 69-89
Google Scholar
7. Ferruzzi M, Coulston A.M., Boushey C.J.: Nutrition in the prevention and treatment of disease. Elsevier, 2013
Google Scholar
8. Fijałkowski F., Jarzyna R.: Rola podwzgórzowej kinazy białkowej aktywowanej przez AMP w kontroli pobierania pokarmu. Postępy Hig. Med. Dośw., 2010; 64: 231-243
Google Scholar
9. Fulgheri G., Sypniewska G.: Is there a link between asthma and obesity? Folia Medica Copernicana, 2013; 1: 1-4
Google Scholar
10. Gawęcki J., Roszkowski W.: Żywienie człowieka a zdrowie publiczne. Wydawnictwo Naukowe PWN, Warszawa 2009
Google Scholar
11. German J.B., Zivkovic A.M., Dallas D.C, Smilowitz J.T.: Nutrigenomics and personalized diets: what will they mean for food? Annu. Rev. Food Sci. Technol., 2011; 2: 97-123
Google Scholar
12. Gętek M., Czech N., Fizia K., Białek-Dratwa A., Muc-Wierzgoń M., Kokot T., Nowakowska-Zajdel E.: Nutrigenomika – bioaktywne składniki żywności. Postępy Hig. Med. Dośw., 2013; 67: 255-260
Google Scholar
13. Grove K.A., Lambert J.D.: Laboratory, epidemiological, and human intervention studies show that tea (Camellia sinensis) may be useful in the prevention of obesity. J. Nutr., 2010; 140: 446-453
Google Scholar
14. Gueorguiev M., Lecoeur C., Meyre D., Benzinou M., Mein C.A., Hinney A., Vatin V., Weill J., Heude B., Hebebrand J., Grossman A.B., Korbonits M., Froquel P.: Association studies on ghrelin and ghrelin receptor gene polymorphisms with obesity. Obesity, 2009; 17: 745-754
Google Scholar
15. Hasik J., Gawęcki J.: Żywienie człowieka zdrowego i chorego. Wydawnictwo Naukowe PWN, Warszawa 2004
Google Scholar
16. Hołysz M., Trzeciak W.H.: Hormonozależna lipaza/esteraza cholesterolowa z kory nadnerczy – struktura, regulacja i rola w syntezie hormonów steroidowych. Post. Bioch., 2015; 61: 138-146
Google Scholar
17. Instytut Żywności i Żywienia im. prof. dra med. Aleksandra Szczygła. www.izz.waw.pl (16.10.2017)
Google Scholar
18. Jakubowska-Burek L., Linke K., Dobrowolska-Zachwieja A.: Nutrigenetyka i nutrigenomika jako nowe opcje terapeutyczne w chorobach o podłożu żywieniowym. Gastroenterol. Pol., 2010; 17: 59-62
Google Scholar
19. Kallio P., Kolehmainen M., Laaksonen D.E., Kekäläinen J., Salopuro T., Sivenius K., Pulkkinen L., Mykkänen H.M., Niskanen L., Uusitupa M., Poutanen K.S.: Dietary carbohydrate modification induces alterations in gene expression in abdominal subcutaneous adipose tissue in persons with the metabolic syndrome: the FUNGENUT study. Am. J. Clin. Nutr., 2007; 85: 1417-1427
Google Scholar
20. Khalilitehrani A., Qorbani M., Hosseini S., Pishva H.: The association of MC4R rs17782313 polymorphism with dietary intake in Iranian adults. Gene, 2015; 563: 125-129
Google Scholar
21. Kieć-Wilk B., Dudek W., Dembińska-Kieć A.: Nutrigenomics, angiogenesis and obesity. Acta Angiol., 2006; 12: 141-148
Google Scholar
22. Kojima M., Hosoda H., Date Y., Nakazato M., Matsuo H., Kangawa K.: Ghrelin is a growth-hormone-releasing acylated peptide from stomach. Nature, 1999; 402: 656-660
Google Scholar
23. Loos R.J., Bouchard C.: FTO: the first gene contributing to common forms of human obesity. Obes. Rev., 2008; 9: 246-250
Google Scholar
24. Lu C., Zhu W., Shen C.L., Gao W.: Green tea poliphenols reduce body weight in rats by modulating obesity-related genes. PLoS One, 2012; 7: e38332
Google Scholar
25. Luong K., Hoàng Nguyễn L.T.: The benefical role of vitamin D in obesity: possible genetic and cell signaling mechanisms. Nutr. J., 2013; 12: 89
Google Scholar
26. Majorczyk M., Baran M., Jaworek J.: Rola witaminy D w rozwoju i przebiegu otyłości. Pielęg. Pol., 2016; 1: 91-97
Google Scholar
27. Mansego M.L., De Marco G., Ivorra C., Lopez-Izquierdo R., Morcillo S., Rojo-Martinez G., Gonzalez-Albert V., Martinez F., Soriguer F., Martin-Escudero J.C., Redon J., Chaves F.J.: The nutrigenetic influence of the interaction between dietary vitamin E and TXN and COMT gene polymorphisms on waist circumference: a case control study. J. Transl. Med., 2015; 13: 286
Google Scholar
28. Martinez J.A., Milagro F.I., Claycombe K.J., Schalinske K.L.: Epigenetics in adipose tissue, obesity, weight loss, and diabetes. Adv. Nutr., 2014; 5: 71-81
Google Scholar
29. McCabe-Sellers B.J., Chenard C.A., Lovera D., Champagne C.M., Bogle M.L., Kaput J.: Readiness of food composition databases and food component analysis systems for nutrigenomics. J. Food Compos. Anal., 2009; 22: S57-S62
Google Scholar
30. Męczekalski B., Czyżyk A., Warenik-Szymankiewicz A.: Rola genów w powstawaniu otyłości. Współczesne poglądy, patogeneza, aspekty kliniczne. Endokrynol. Otył. Zab. Przem. Mat., 2008; 4: 27-37
Google Scholar
31. Mozaffarian D.: Dietary and policy priorities for cardiovascular disease, diabetes, and obesity. A comprehensive review. Circulation, 2016; 133: 187-225
Google Scholar
32. Nigro E., Scudiero O., Monaco M.L., Palmieri A., Mazzarella G., Costagliola C., Bianco A., Daniele A.: New insight into adiponectin role in obesity and obesity-related diseases. Biomed. Res. Int., 2014; 2014: 658913
Google Scholar
33. O’Rahilly S., Farooqi I.S.: Genetics of obesity. Philos. Trans. R. Soc. Lond. B Biol. Sci., 2006; 361: 1095-1105
Google Scholar
34. Pacholczyk M., Ferenc T., Kowalski J.: Zespól metaboliczny. Część II: patogeneza zespołu metabolicznego i jego powikłań. Postępy Hig. Med. Dośw., 2008; 62: 543-558
Google Scholar
35. Palou A., Bonet L.M., Serra F., Picó C.: Genetics and nutrigenomics of obesity. W: Epidemiology of obesity in children and adolescents. Prevalence and etiology., red.: L.A. Moreno, I. Pigeot, W. Ahrens. Springer, London 2011
Google Scholar
36. Paracchini V., Pedotti P., Taioli E.: Genetics of leptin and obesity: a HuGE review. Am. J. Epidemiol., 2005; 162: 101-114
Google Scholar
37. Pawlak J., Derlacz R.A.: Mechanizmy powstawania oporności na insulinę w tkankach obwodowych. Post. Bioch., 2011; 57: 200-206
Google Scholar
38. Peters T., Ausmeier K., Rüther U.: Cloning of Fatso (Fto), a novel gene deleted by the Fused toes (Ft) mouse mutation. Mamm. Genome, 1999; 10: 983-986
Google Scholar
39. Phillips C.M., Goumidi L., Bertrais S., Field M.R., Ordovas J.M., Cupples L.A., Defoort C., Lovegrove J.A., Drevon C.A, Blaak E.E., Gibney M.J., Kiec-Wilk B., Karlstrom B., Lopez-Miranda J., McManus R. i wsp.: Leptin receptor polymorphisms interact with polyunsaturated fatty acids to augment risk of insulin resistance and metabolic syndrome in adults. J. Nutr., 2010: 140; 238-244
Google Scholar
40. Pokrywka M., Kieć-Wilk B., Polus A., Wybrańska I.: Metylacja DNA a otyłość prosta. Postępy Hig. Med. Dośw., 2014; 68: 1383-1391
Google Scholar
41. Polińska B., Matowicka-Karna J., Kemona H.: Rola greliny w organizmie. Postępy Hig. Med. Dośw., 2011; 65: 1-7
Google Scholar
42. Rankinen T., Zuberi A., Chagnon Y.C., Weisnagel S.J., Argyropoulos G., Walts B., Pérusse L., Bouchard C.: The human obesity gene map: the 2005 update. Obesity, 2006; 14: 529-644
Google Scholar
43. Sales N.M., Pelegrini P.B., Gaersch M.C.: Nutrigenomics: definitions and advances of this new science. J. Nutr. Metab., 2014; 2014: 202759
Google Scholar
44. Shen X.H., Tang Q.Y., Huang J., Cai W.: Vitamin E regulates adipocytokine expression in a rat model of dietary-induced obesity. Exp. Biol. Med., 2010; 235: 47-51
Google Scholar
45. Siriwardhana N., Kalupahana N.S., Cekanova M., LeMieux M., Greer B., Moustaid-Moussa N.: Modulation of adipose tissue inflammation by bioactive food compounds. J. Nutr. Biochem., 2013; 24: 63-623
Google Scholar
46. Stachowicz M., Janas-Kozik M., Olszanecka-Glinianowicz M., Chudek J.: Rola leptyny w zaburzeniach odżywiania się – współczesne poglądy. Psychiatr. Pol., 2013; 47: 897-907
Google Scholar
47. Szczepańska H., Kowalczyk Z., Sałagacka-Kubiak A., Balcerczak E.: Ocena zmian stężenia leptyny i greliny, parametrów antropometrycznych oraz laboratoryjnych przed i po implantacji balonu żołądkowego. Folia Med. Lodz, 2015; 42: 181-194
Google Scholar
48. Tartaglia L.A., Dembski M., Weng X., Deng N., Culpepper J., Devos R., Richards G.J., Campfield L.A., Clark F.T., Deeds J., Muir C., Sanker S., Moriarty A., Moore K.J., Smutko J.S. i wsp.: Identification and expression cloning of a leptin receptor, OB-R. Cell, 1995; 83: 1263-1271
Google Scholar
49. Ukkola O., Ravussin E., Jacobson P., Pérusse L., Rankinen T., Tschöp M., Heiman M.L., Leon A.S., Rao D.C., Skinner J.S., Wilmore J.H., Sjöström L., Bouchard C.: Role of ghrelin polymorphisms in obesity based on three different studies. Obes. Res., 2002; 10: 782-791
Google Scholar
50. Wolfram S., Raederstorff D., Wang Y., Teixeira S.R., Elste V., Weber P.: TEAVIGO (epigallocatechin gallate) supplementation prevents obesity in rodents by reducing adipose tissue mass. Ann. Nutr. Metab., 2005; 49: 54-63
Google Scholar
51. Yilmaz Z., Davis C., Loxton N.J., Kaplan A.S., Levitan R.D., Carter J.C., Kennedy J.L.: Association between MC4R rs17782313 polymorphism and overeating behaviors. Int. J. Obes., 2015; 39: 114-120
Google Scholar
52. Zhang H.M., Chen S.W., Zhang L.S., Feng X.F.: Effects of soy isoflavone on low-grade inflammation in obese rats. Zhong Nan Da Xue Xue Bao Yi Xue Ban, 2006; 31: 336-339
Google Scholar
53. Zhang Y., Proenca R., Maffei M., Barone M., Leopold L., Friedman J.M.: Positional cloning of the mouse obese gene and its human homologue. Nature, 1994; 372: 425-432
Google Scholar

Full text

PDF