食品与发酵工业 >

2024 , Vol. 50 >Issue 12: 404 - 410

DOI: https://doi.org/10.13995/j.cnki.11-1802/ts.036883

综述与专题评论

茶叶活性成分调节肠道菌群影响脂质代谢

  • 杨恺清 ,
  • 王凯博 ,
  • 陈思霖 ,
  • 赵碧 ,
  • 申时全
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  • (云南省农业科学院茶叶研究所,云南省茶学重点实验室,云南 昆明,650000)
第一作者:硕士,研究实习员(申时全研究员为通信作者,E-mail:shensq75@163.com)

收稿日期: 2023-07-25

  修回日期: 2023-08-24

  网络出版日期: 2024-07-11

基金资助

云南省重大科技专项计划(1202102AE090038);云南省基础研究计划项目(202301AU070129);云南省茶学重点实验室开放基金(2022YNCX004);云南省农业科学院应用基础预研专项(2023KYZX-03)

收起

Tea active ingredients affect lipid metabolism by regulating gut microbiota

  • YANG Kaiqing ,
  • WANG Kaibo ,
  • CHEN Silin ,
  • ZHAO Bi ,
  • SHEN Shiquan
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  • (Institute of Tea, Yunnan Academy of Agricultural Sciences, Yunnan Provincial Key Laboratory of Tea Science, Kunming 650000, China)

Received date: 2023-07-25

  Revised date: 2023-08-24

  Online published: 2024-07-11

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摘要

在人体脂质代谢过程中,脂类及其代谢产物的异常可增加患多种疾病的风险,因此维持正常的脂质代谢水平,有助于机体保持健康状态。茶是世界上消费最广泛的饮料之一,其丰富的内含物质及活性成分已被证实对减少人体脂肪和预防肥胖作用显著。在茶叶调节脂质代谢的途径中,其活性成分能与肠道菌群相互作用,可改善肠道菌群组成及稳态,有助于维护肠道屏障功能,调节脂肪的消耗和积累,是茶叶参与脂质代谢的重要组成部分。该文围绕茶叶活性成分,综述了近年来茶多酚、茶多糖、咖啡碱等成分,从菌属相对丰度、胆汁酸代谢及菌群与茶叶代谢产物相互作用等不同的方式来调节肠道微生态的生物学功能,从而影响脂质代谢,为相关研究提供最新的理论参考。

关键词: ; 活性成分; 肠道菌群; 脂质代谢; 肥胖

本文引用格式

杨恺清 , 王凯博 , 陈思霖 , 赵碧 , 申时全 . 茶叶活性成分调节肠道菌群影响脂质代谢[J]. 食品与发酵工业, 2024 , 50(12) : 404 -410 . DOI: 10.13995/j.cnki.11-1802/ts.036883

Abstract

In the process of human lipid metabolism, the abnormality of lipids and their metabolites can increase the risk of suffering from a variety of diseases.Therefore, maintaining normal lipid metabolism level is helpful for the body to maintain a healthy state.Tea is one of the most widely consumed beverages in the world.Its rich contents and active ingredients have been proved to have a significant effect on reducing body fat and preventing obesity.In the way that tea regulates lipid metabolism, its active ingredients can interact with gut microbiota, improve the composition and homeostasis of gut microbiota, help to maintain intestinal barrier function, and regulate fat consumption and accumulation, which is an important part of tea participating in lipid metabolism.This review focuses on the active components of tea, including tea polyphenols, tea polysaccharides and caffeine, which regulate the biological functions of intestinal microecology in different ways, such as the relative abundance of bacteria, bile acid metabolism, and the interaction between bacteria and tea metabolites, thus affecting lipid metabolism, providing the latest scientific evidence for related research.

Key words: tea; active ingredient; gut microbiota; lipid metabolism; obesity

参考文献

[1] ZECHNER R, ZIMMERMANN R, EICHMANN T O, et al.FAT SIGNALS—Lipases and lipolysis in lipid metabolism and signaling[J].Cell Metabolism, 2012, 15(3):279-291.
[2] CORBIN K D, CARNERO E A, DIRKS B, et al.Host-diet-gut microbiome interactions influence human energy balance:A randomized clinical trial[J].Nature Communications, 2023, 14(1):3161.
[3] 满子意, 凤怡, 吴祥庭.儿茶素单体EGC对胰脂肪酶的抑制作用及其机理研究[J].茶叶科学, 2022, 42(6):863-874.
MAN Z Y, FENG Y, WU X T.Inhibitory effect of catechin monomer EGC on pancreatic lipase and mechanism[J].Journal of Tea Science, 2022, 42(6):863-874.
[4] MI Y S, LIU X, TIAN H Y, et al.EGCG stimulates the recruitment of brite adipocytes, suppresses adipogenesis and counteracts TNF-α-triggered insulin resistance in adipocytes[J].Food & Function, 2018, 9(6):3374-3386.
[5] WU Z H, HUANG S M, LI T T, et al.Gut microbiota from green tea polyphenol-dosed mice improves intestinal epithelial homeostasis and ameliorates experimental colitis[J].Microbiome, 2021, 9(1):184.
[6] WANG L, ZENG B H, LIU Z W, et al.Green tea polyphenols modulate colonic microbiota diversity and lipid metabolism in high-fat diet treated HFA mice[J].Journal of Food Science, 2018, 83(3):864-873.
[7] LI J, CHEN C F, YANG H, et al.Tea polyphenols regulate gut microbiota dysbiosis induced by antibiotic in mice[J].Food Research International, 2021, 141:110153.
[8] ZHOU F, LI Y L, ZHANG X, et al.Polyphenols from Fu brick tea reduce obesity via modulation of gut microbiota and gut microbiota-related intestinal oxidative stress and barrier function[J].Journal of Agricultural and Food Chemistry, 2021, 69(48):14530-14543.
[9] HASANI A, EBRAHIMZADEH S, HEMMATI F, et al.The role of Akkermansia muciniphila in obesity, diabetes and atherosclerosis[J].Journal of Medical Microbiology, 2021, 70(10).DOI:10.1099/jmm.0.001435.
[10] ANNUNZIATA G, MAISTO M, SCHISANO C, et al.Colon bioaccessibility and antioxidant activity of white, green and black tea polyphenols extract after in vitro simulated gastrointestinal digestion[J].Nutrients, 2018, 10(11):1711.
[11] ZHAO Y, ZHANG X.Interactions of tea polyphenols with intestinal microbiota and their implication for anti-obesity[J].Journal of the Science of Food and Agriculture, 2020, 100(3):897-903.
[12] FAN Y M, ZHOU X F, HUANG G L.Preparation, structure, and properties of tea polysaccharide[J].Chemical Biology & Drug Design, 2022, 99(1):75-82.
[13] FAN M H, ZHU J X, QIAN Y L, et al.Effect of purity of tea polysaccharides on its antioxidant and hypoglycemic activities[J].Journal of Food Biochemistry, 2020, 44(8):e13277.
[14] LIU D, GAO H, TANG W, et al.Plant non-starch polysaccharides that inhibit key enzymes linked to type 2 diabetes mellitus[J].Annals of the New York Academy of Sciences, 2017, 1401(1):28-36.
[15] 欧阳建, 周方, 卢丹敏, 等.茶多糖调控肥胖作用研究进展[J].茶叶科学, 2020, 40(5):565-575.
OUYANG J, ZHOU F, LU D M, et al.Research progress of tea polysaccharides in regulating obesity[J].Journal of Tea Science, 2020, 40(5):565-575.
[16] CHEN G J, BAI Y X, ZENG Z Q, et al.Structural characterization and immunostimulatory activity of heteropolysaccharides from Fuzhuan brick tea[J].Journal of Agricultural and Food Chemistry, 2021, 69(4):1368-1378.
[17] WANG Y, LI T, LIU Y Y, et al.Heimao tea polysaccharides ameliorate obesity by enhancing gut microbiota-dependent adipocytes thermogenesis in mice fed with high fat diet[J].Food & Function, 2022, 13(24):13014-13027.
[18] 李祎, 毛彦, 黄丽, 等.六堡茶多糖对高脂血症大鼠结肠微生态的影响[J].大众科技, 2023, 25(2):99-104.
LI Y, MAO Y, HUANG L, et al.Effect of Liubao tea polysaccharide on colonic microecology in hyperlipidemia rats[J].Popular Science and Technology, 2023, 25(2):99-104.
[19] 杜海平. 肠AKK菌介导茯砖茶多糖调控脂肪产热功能的研究[D].西安:陕西师范大学,2020.
DU H P.The study of intestinal AKK bacteria mediating the regulation of fat thermogenesis by Fu brick tea polysaccharide[D].Xi′an:Shaanxi Normal University, 2020.
[20] HANHINEVA K, TÖRRÖNEN R, BONDIA-PONS I, et al.Impact of dietary polyphenols on carbohydrate metabolism[J].International Journal of Molecular Sciences, 2010, 11(4):1365-1402.
[21] BROTHERS H M, MARCHALANT Y, WENK G L.Caffeine attenuates lipopolysaccharide-induced neuroinflammation[J].Neuroscience Letters, 2010, 480(2):97-100.
[22] NEHLIG A.Effects of coffee on the gastro-intestinal tract:A narrative review and literature update[J].Nutrients, 2022, 14(2):399.
[23] DAI A N, HOFFMAN K, XU A A, et al.The association between caffeine intake and the colonic mucosa-associated gut microbiota in humans—A preliminary investigation[J].Nutrients, 2023, 15(7):1747.
[24] LI H Y, HUANG S Y, XIONG R G, et al.Anti-obesity effect of theabrownin from dark tea in C57BL/6 J mice fed a high-fat diet by metabolic profiles through gut microbiota using untargeted metabolomics[J].Foods, 2022, 11(19):3000.
[25] YUE S J, SHAN B, PENG C X, et al.Theabrownin-targeted regulation of intestinal microorganisms to improve glucose and lipid metabolism in Goto-Kakizaki rats[J].Food & Function, 2022, 13(4):1921-1940.
[26] 蒋慧颖, 马玉仙, 曾文治, 等.茶黄素、茶红素与茶褐素对高脂饮食大鼠肠道菌群的影响[J].食品工业科技, 2018, 39(20):274-279;351.
JIANG H Y, MA Y X, ZENG W Z, et al.Effects of theaflavins, thearubicins and theafocins on intestinal flora in rats fed with high-fat diet[J].Science and Technology of Food Industry, 2018, 39(20):274-279;351.
[27] VALLIANOU N, STRATIGOU T, CHRISTODOULATOS G S, et al.Understanding the role of the gut microbiome and microbial metabolites in obesity and obesity-associated metabolic disorders:Current evidence and perspectives[J].Current Obesity Reports, 2019, 8(3):317-332.
[28] LIU B N, LIU X T, LIANG Z H, et al.Gut microbiota in obesity[J].World Journal of Gastroenterology, 2021, 27(25):3837-3850.
[29] BÄCKHED F, DING H, WANG T, et al.The gut microbiota as an environmental factor that regulates fat storage[J].Proceedings of the National Academy of Sciences of the United States of America, 2004, 101(44):15718-15723.
[30] WANG L, SHU X O, CAI H, et al.Tea consumption and gut microbiome in older Chinese adults[J].The Journal of Nutrition, 2023, 153(1):293-300.
[31] BLANCO C.The influence of the gut microbiome on obesity[J].Journal of the American Association of Nurse Practitioners, 2020, 32(7):504-510.
[32] YUAN Y, HE J L, TANG M, et al.Preventive effect of Ya′an Tibetan tea on obesity in rats fed with a hypercaloric high-fat diet revealed by gut microbiology and metabolomics studies[J].Food Research International, 2023, 165:112520.
[33] HOU Y, ZHANG Z F, CUI Y S, et al.Pu-erh tea and theabrownin ameliorate metabolic syndrome in mice via potential microbiota-gut-liver-brain interactions[J].Food Research International, 2022, 162(Pt B):112176.
[34] LIU X L, HU G S, WANG A H, et al.Black tea reduces diet-induced obesity in mice via modulation of gut microbiota and gene expression in host tissues[J].Nutrients, 2022, 14(8):1635.
[35] 欧阳建. 岳阳黄茶对高脂饮食大鼠肠道屏障和肠道菌群的影响[D].长沙:湖南农业大学, 2021.
OUYANG J.Effect of Yueyang yellow tea on intestinal barrier and intestinal flora in rats with high-fat diet[D].Changsha:Hunan Agricultural University, 2021.
[36] 仇振明, 王文学.肠道菌群及其代谢物与溃疡性结肠炎的研究进展[J].微生物学免疫学进展, 2023, 51(3):89-95.
QIU Z M, WANG W X.Research progress of gut microbiota and its metabolites in ulcerative colitis[J].Progress in Microbiology-Immunology, 2023, 51(3):89-95.
[37] CHIANG J Y L, FERRELL J M.Discovery of farnesoid X receptor and its role in bile acid metabolism[J].Molecular and Cellular Endocrinology, 2022, 548:111618.
[38] HUANG F J, ZHENG X J, MA X H, et al.Theabrownin from Pu-erh tea attenuates hypercholesterolemia via modulation of gut microbiota and bile acid metabolism[J].Nature Communications, 2019, 10(1):4971.
[39] KATAFUCHI T, MAKISHIMA M.Molecular basis of bile acid-FXR-FGF15/19 signaling axis[J].International Journal of Molecular Sciences, 2022, 23(11):6046.
[40] HU T, WU P, ZHAN J F, et al.Influencing factors on the physicochemical characteristics of tea polysaccharides[J].Molecules, 2021, 26(11):3457.
[41] LI C R, ZHOU K, XIAO N Q, et al.The effect of qiweibaizhu powder crude polysaccharide on antibiotic-associated diarrhea mice is associated with restoring intestinal mucosal bacteria[J].Frontiers in Nutrition, 2022, 9:952647.
[42] WIJDEVELD M, NIEUWDORP M, IJZERMAN R.The interaction between microbiome and host central nervous system:The gut-brain axis as a potential new therapeutic target in the treatment of obesity and cardiometabolic disease[J].Expert Opinion on Therapeutic Targets, 2020, 24(7):639-653.
[43] ZHU M Z, OUYANG J, ZHOU F, et al.Polysaccharides from Fu brick tea ameliorate obesity by modulating gut microbiota and gut microbiota-related short chain fatty acid and amino acid metabolism[J].The Journal of Nutritional Biochemistry, 2023, 118:109356.
[44] DALILE B, VAN OUDENHOVE L, VERVLIET B, et al.The role of short-chain fatty acids in microbiota-gut-brain communication[J].Nature Reviews.Gastroenterology & Hepatology, 2019, 16(8):461-478.
[45] 陈立. 咖啡因通过调节ChREBP介导的脂肪从头合成对NAFLD的作用机制研究[D].汕头:汕头大学, 2022.
CHEN L.Study on the mechanism of caffeine on NAFLD by regulating ChREBP-mediated de novo lipogenesis[D].Shantou:Shantou University, 2022.
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