Modulation of the human gut microbiota by phenolics and phenolic fiber‐rich foods

The gut microbiota plays a prominent role in human health. Alterations in the gut microbiota are linked to the development of chronic diseases such as obesity, inflammatory bowel disease, metabolic syndrome, and certain cancers. We know that diet plays an important role to initiate, shape, and modulate the gut microbiota. Long‐term dietary patterns are shown to be closely related with the gut microbiota enterotypes, specifically long‐term consumption of carbohydrates (related to Prevotella abundance) or a diet rich in protein and animal fats (correlated to Bacteroides). Short‐term consumption of solely animal‐ or plant‐based diets have rapid and reproducible modulatory effects on the human gut microbiota. These alterations in microbiota profile by dietary alterations can be due to impact of different dietary macronutrients, carbohydrates, protein, and fat, which have diverse modulatory effects on gut microbial composition. Food‐derived phenolics, which encompass structural variants of flavonoids, hydroxybenzoic acids, hydroxycinnamic acids, coumarins, stilbenes, ellagitannins, and lignans can modify the gut microbiota. Gut microbes have been shown to act on dietary fibers and phenolics to produce functional metabolites that contribute to gut health. Here, we discuss recent studies on the impacts of phenolics and phenolic fiber‐rich foods on the human gut microbiota and provide an insight into potential synergistic roles between their bacterial metabolic products in the regulation of the intestinal microbiota.     

Effects of Potato Fiber and Potato‐Resistant Starch on Biomarkers of Colonic Health in Rats Fed Diets Containing Red Meat

Abstract: The effects of red meat consumption with and without fermentable carbohydrates on indices of large bowel health in rats were examined. Sprague‐Dawley rats were fed cellulose, potato fiber, or potato‐resistant starch diets containing 12% casein for 2 wk, then similar diets containing 25% cooked beef for 6 wk. After week 8, cecal and colonic microbiota composition, fermentation end‐products, colon structure, and colonocyte DNA damage were analyzed. Rats fed potato fiber had lower Bacteroides‐Prevotella‐Porphyromonas group compared to other diet groups. Colonic Bifidobacterium spp. and/or Lactobacillus spp. were higher in potato fiber and potato‐resistant starch diets than in the cellulose diet. Beneficial changes were observed in short‐chain fatty acid concentrations (acetic, butyric, and propionic acids) in rats fed potato fiber compared with rats fed cellulose. Phenol and p‐cresol concentrations were lower in the cecum and colon of rats fed potato fiber. An increase in goblet cells per crypt and longer crypts were found in the colon of rats fed potato fiber and potato‐resistant starch diets. Fermentable carbohydrates had no effect on colonic DNA damage. Dietary combinations of red meat with potato fiber or potato‐resistant starch have distinctive effects in the large bowel. Future studies are essential to examine the efficacy of different types of nondigestible carbohydrates in maintaining colonic health during long‐term consumption of high‐protein diets. Practical Application: Improved understanding of interactions between the food consumed and gut microbiota provides knowledge needed to make healthier food choices for large bowel health. The impact of red meat on large bowel health may be ameliorated by consuming with fermentable dietary fiber, a colonic energy source that produces less harmful by‐products than the microbial breakdown of colonic protein for energy. Developing functional red meat products with fermentable dietary fiber could be one way to promote a healthy and balanced macronutrient diet.     

Dietary grape seed extract ameliorates symptoms of inflammatory bowel disease in IL10‐deficient mice

Grape seed extract (GSE) is a by‐product of the wine industry, with abundant polyphenolic compounds known for their anti‐inflammatory and anti‐oxidative effects. Using IL10‐deficient mice (IL10KO), here we showed that GSE (1% of dry feed weight) ameliorated inflammatory bowel disease indices, increased colonic goblet cell numbers and decreased myeloperoxidase levels in the large intestine. Concomitantly, GSE supplementation attenuated inflammation, decreased the expression of pore forming tight junction protein claudin2, and increased levels of Lactobacilli and Bacteroides in the gut microbiota of IL10KO mice. In summary, our study shows that GSE has protective roles on inflammatory bowel disease through altering gut inflammation, tight junction protein expression, and gut microbiota composition.     

Continuously Ingesting Fructooligosaccharide Can't Maintain Rats’ Gut Bifidobacterium at a High Level

Fructooligosaccharide (FOS) has been reported to increase Lactobacillus and Bifidobacterium populations in animal and human gut. Hence, it has been utilized to regulate the balance of gut microbiota. In this study, we compared the effects of high‐FOS (HFOS) diet on normal and obese rats’ gut Lactobacillus and Bifidobacterium, with high‐soybean‐fibers (HSF) diet as control. The results showed that the level of Bifidobacterium population substantially increased at week 4 in groups of rats fed the HFOS diet (P < 0.05), but significantly reduced to a small level at week 8 (P < 0.05); the abundance of Lactobacillus was increased in normal rats (P < 0.05), but decreased in obese rats (P < 0.05). The HSF diet did not promote the growth of Lactobacillus and Bifidobacterium in rats’ gut. The findings suggested that Bifidobacterium population could not be maintained at a high level when the rats continuously ingested the HFOS diet for 8 wk; additionally, Lactobacillus population could adapt to a relatively stable level with the consumption of HFOS diet.     

Fabrication of quercetin-loaded nanoparticles based on Hohenbuehelia serotina polysaccharides and their modulatory effects on intestinal function and gut microbiota in vivo

This research was aimed to construct the nanoparticles based on Hohenbuehelia serotina polysaccharides for encapsulation of quercetin (QC-HSP NPs), and investigate their effects on intestinal function and gut microbiota in mice. Results showed that in comparison with HSP and control, QC-HSP NPs significantly improved immune organ indexes, colon length, fecal moisture content and intestinal peristalsis capacity of mice. The productions of short-chain fatty acids (SCFAs) in colon were also increased after treatment with QC-HSP NPs, while the colonic fecal pH was decreased and defecation time was shortened. Through analysis of 16S rRNA sequencing, QC-HSP NPs could increase α and β diversities of gut microbiota, modulate their structure and composition, and increase the relative abundance of beneficial bacteria together with reducing the richness of harmful bacteria. In addition, QC-HSP NPs ameliorated the metabolic functions of gut microbiota by modulating metabolic pathways. This study suggested that QC-HSP NPs might be served as a prebiotic for protecting intestinal health.     

Green Tea Liquid Consumption Alters the Human Intestinal and Oral Microbiome

1 Scope

GTPs (green tea polyphenols) exert anti‐CRC (colorectal cancer) activity. The intestinal microbiota and intestinal colonization by bacteria of oral origin has been implicated in colorectal carcinogenesis. GT modulates the composition of mouse gut microbiota harmonious with anticancer activity. Therefore, the effect of green tea liquid (GTL) consumption on the gut and oral microbiome is investigated in healthy volunteers (n = 12).

2 Methods and results

16S sequencing and phylogenetic investigation of communities by reconstruction of unobserved states (PICRUSt) analysis of both fecal and saliva samples (collected before intervention, after 2 weeks of GTL (400 mL per day) and after a washout period of one week) in healthy volunteers show changes in microbial diversity and core microbiota and difference in clear classification (partial least squares‐discriminant analysis [PLS‐DA]). An irreversible, increased FIR:BAC (Firmicutes to Bacteroidetes ratio), elevated SCFA producing genera, and reduction of bacterial LPS synthesis in feces are discovered in response to GTL. GTL alters the salivary microbiota and reduces the functional pathways abundance relevance to carcinogenesis. Similar bacterial networks in fecal and salivary microbiota datasets comprising putative oral bacteria are found and GTL reduces the fecal levels of Fusobacterium. Interestingly, both Lachnospiraceae and B/E (Bifidobacterium to Enterobacteriacea ratio—markers of colonization resistance [CR]) are negatively associated with the presence of oral‐like bacterial networks in the feces.

3 Conclusion

These results suggest that GTL consumption causes both oral and gut microbiome alterations.     

应用Illumina NovaSeq测序技术比较3 种杂粮对大鼠肠道菌群的影响

为探究燕麦、荞麦和小米对健康大鼠肠道结构、肠道菌群及肠道中短链脂肪酸（short-chain fatty acids,SCFAs）含量的影响,本实验将48 只SPF级雄性SD大鼠随机分为4 组（空白对照组（饲喂标准维持饲料）、燕麦组（饲喂含22%（质量分数,下同）燕麦的饲料）、荞麦组（饲喂含22%荞麦的饲料）和小米组（饲喂含22%小米的饲料））,每周测定大鼠体质量,12 周后处死大鼠,取肝脏、结肠组织及结肠内容物,对大鼠肝脏和结肠组织进行病理学检测;应用Illumina NovaSeq高通量测序技术检测大鼠肠道菌群变化;利用液相色谱-质谱联用仪检测大鼠结肠内容物SCFAs含量。结果表明,燕麦可增加大鼠肠道菌群多样性,提高大鼠结肠乳杆菌属（Lactobacillus）和阿克曼氏菌属（Akkermansia）丰度;荞麦和小米可增加厚壁菌门（Firmicutes）相对丰度,降低疣微菌门（Verrucomicrobia）和拟杆菌门（Bacteroidetes）相对丰度;燕麦、荞麦和小米均可降低拟杆菌属（Bacteroides）丰度;燕麦和小米可显著提高大鼠结肠内乙酸和总SCFAs含量（P＜0.05）,小米可显著提高丙酸和异丁酸含量（P＜0.05）。综上,燕麦对大鼠肠道菌群具有一定的改善作用,荞麦和小米对肠道菌群的影响相似度较高,相关研究结果可为谷物功能食品的开发提供科学依据。     

Is a vegan or a vegetarian diet associated with the microbiota composition in the gut? Results of a new cross-sectional study and systematic review

Abstract

It is assumed that diet influences the composition of gut microbiota, which in turn may affect human health status. This systematic review aimed to summarize associations of a vegan or vegetarian diet with the composition of microbiota. A literature search was conducted in PubMed and Embase for eligible human studies with vegan or vegetarian diets as an exposure and microbiota composition as an outcome in healthy adults. Furthermore, data from our cross-sectional study with vegan participants were included. Out of sixteen included studies, six investigated the association between gut microbiota composition in both vegans and in vegetarians, six in vegans and four studies in vegetarians compared to omnivores, respectively. Among 5 different phyla, 28 families, 96 genera and 177 species, Bacteroides, Bifidobacterium and Prevotella were the most reported genera, followed by the species Prevotella copri, Faecalibacterium prausnitzii and Escherichia coli in all diets. No consistent association between a vegan diet or vegetarian diet and microbiota composition compared to omnivores could be identified. Moreover, some studies revealed contradictory results. This result could be due to high microbial individuality, and/or differences in the applied approaches. Standardized methods with high taxonomical and functional resolutions are needed to clarify this issue.     

Pectin and inulin stimulated the mucus formation at a similar level: An omics-based comparative analysis

Mucin 2 (MUC2) is the skeleton of colonic mucus that comprises the physical intestinal barrier. Different dietary polysaccharides may affect colonic mucus at different extents. The effect of pectin on MUC2 production is contradictory. To investigate whether and how pectin affected hosts’ colonic mucus, the amount of MUC2 in colon, the cecal, mucosal microbiota, and metabolites profiles were analyzed and compared with inulin. The results showed pectin stimulated the production of MUC2 at a similar level to inulin. Both interventions increased the abundance of cecal Lachnospira and Christensenellaceae_R-7_group, and enhanced the production of specific metabolites including soyasapogenol B 24-O-b-d -glucoside, lucyoside Q, trans-EKODE-(E)-Ib, and 1,26-dicaffeoylhexacosanediol. Additionally, pectin increased the relative abundance (RA) of cecal Lactobacillus, and induced less RA of potentially harmful bacteria such as Helicobacter in mucosal microbiota than inulin. In conclusion, we first reported that pectin and inulin stimulated the mucus formation at a similar level. Two genera of cecal bacteria and four metabolites may play an important role in enhancing the production of MUC2. Moreover, the MUC2 production may be unrelated to several traditional health-beneficial bacteria; pectin possibly performed as good as or better than the inulin in rats’ gut.     

Dietary Amino Acids and the Gut‐Microbiome‐Immune Axis: Physiological Metabolism and Therapeutic Prospects

Dietary amino acids (AAs) are not only absorbed and metabolized by enterocytes but also available to the microbiota in the gut in mammals. In addition to serving as the materials for protein synthesis, AAs can act as precursors for numerous metabolic end products in reactions involving the intestinal mucosa and microbiota. After penetrating the epithelial barrier, microbial metabolites can enter and accumulate in the host circulatory system, where they are sensed by immune cells and then elicit a wide range of biological functions via different receptors and mechanisms. Some intestinal bacteria can also synthesize certain AAs, implying that the exchange of AAs between hosts and microorganisms is bidirectional. Changes in AA composition and abundance can affect AA‐metabolizing bacterial communities and modulate macrophages and dendritic cells via toll‐like receptors (TLRs), autoinducer‐2 (AI‐2), and NOD‐like receptors (NLRs), and also regulate the gut‐microbiome‐immune axis via aryl hydrocarbon receptor (AhR), serotonin/5‐hydroxytryptamine (5‐HT), and other signaling pathways, all of which play critical roles in regulating the intestinal mucosal immunity and microbiota directly or indirectly, contributing to intestinal homeostasis. Therefore, the current findings of the effects of certain functional AAs on the gut‐microbiome‐immune axis are reviewed, illustrating signaling pathways of tryptophan (Trp), glutamine (Gln), methionine (Met), and branched‐chain AAs (BCAAs) in the intestinal barrier and regarding immunity via crosstalk with their receptors or ligands. These findings have shed light on the clinical applications of dietary AAs in improving gut microbiota and mucosal immunity, therefore benefiting the gut as well as local and systemic health.     

Different Flavonoids Can Shape Unique Gut Microbiota Profile In Vitro

The impact of flavonoids has been discussed on the relative viability of bacterial groups in human microbiota. This study was aimed to compare the modulation of various flavonoids, including quercetin, catechin and puerarin, on gut microbiota culture in vitro, and analyze the interactions between bacterial species using fructo‐oligosaccharide (FOS) as carbon source under the stress of flavonoids. Three plant flavonoids, quercetin, catechin, and puerarin, were added into multispecies culture to ferment for 24 h, respectively. The bacterial 16S rDNA amplicons were sequenced, and the composition of microbiota community was analyzed. The results revealed that the tested flavonoids, quercetin, catechin, and puerarin, presented different activities of regulating gut microbiota; flavonoid aglycones, but not glycosides, may inhibit growth of certain species. Quercetin and catechin shaped unique biological webs. Bifidobacterium spp. was the center of the biological web constructed in this study.     

Metabolic and microbial modulation of phenolic compounds from raspberry leaf extract under in vitro digestion and fermentation

Raspberry leaves, by-products in raspberry production, are also a rich source of bioactive phytochemicals. In this study, the changes of phenolic compounds in raspberries leaf extract (RLE) under in vitro digestion and colonic fermentation were further studied by HPLC-MS analysis and 16S rRNA. The results showed that the phenolic compounds in RLE were relatively stable during in vitro gastric digestion; however, in the subsequent intestinal digestion and colonic fermentation, their content decreased sharply. A large amount of hydroxyphenylpropionic acid, hydroxyphenylacetic acid and urolithins were produced under the action of gut microbiota. Moreover, compared with corresponding control, RLE significantly reduced the ratio of Firmicutes/Bacteroidetes in all volunteers, increased the relative abundances of some beneficial bacteria, Enterococcus, Prevotella, and decreased the relative abundances of potential pathogens, Clostridium and Faecalibacterium. These findings suggest that RLE during in vitro digestion and fermentation has positive effects on gut microbiota and potential value of maintaining intestinal health.     

Short‐term feeding of fermentable dietary fibres influences the gut microbiota composition and metabolic activity in rats

This study investigated the effects of dietary fibres on gut bacterial abundance and metabolic activity in rats fed short‐term. Faecal samples from rats fed for 7 days showed differences in the effects of dietary fibres on gut bacterial populations. Broccoli fibre, inulin, potato fibre and potato resistant starch significantly increased the faecal Bacteroides‐Prevotella‐Porphyromonas group compared with cellulose. Growth of pathogenic bacteria such as Clostridium perfringens, Escherichia coli and Enterococcus spp. was decreased significantly in rats fed barley β‐glucan, citrus pectin, inulin and broccoli fibre diets. An increase in Bifidobacterium spp. and butyric acid levels, the so‐called bifidogenic and butyrogenic effects, was observed in rats fed inulin and potato fibre diets. Organic acid concentrations and polysaccharide contents in the rat faeces confirm the fermentability of dietary fibres in the gut. This study demonstrates the positive effects of plant‐sourced dietary fibres on gut microbiota composition and metabolic activity.     

广西长寿饮食模式对人体肠道菌群结构的调节作用

该研究旨在探究所构建的广西长寿饮食模式对人体肠道菌群的具体影响。14名志愿者被筛选并要求其高依从地遵循广西长寿饮食模式2周,在干预前后采集志愿者粪便样品并进行16S rDNA高通量测序。结果表明：饮食干预后志愿者肠道菌群多样性从多个层面发生了变化。在门水平上,TM7相对丰度显著降低（由0.05%降低至0.01%）,变形菌门（Proteobacteria）相对丰度、厚壁菌门（Firmicutes）与拟杆菌门（Bacteroidetes）比值的相对丰度也有所降低。在属水平上,粪球菌属（Coprococcus）相对丰度显著升高（由1.04%增至1.39%）,而埃希菌属（Escherichia,由14.00%降至9.62%）、瘤胃球菌属（Ruminococcus,由5.67%降至2.48%）和巨单胞菌属（Megamonas,由4.06%降至0.04%）相对丰度显著降低。通过冗余分析表明肠道菌群的变化与每日摄入食物种类密切相关,其中蔬菜的每日平均摄入量与其相关性最高（r2=0.89,p<0.01）。该研究结果证明广西长寿饮食模式可有效调节人体肠道菌群结构,降低肠道内部分有害菌的丰度,对维持机体健康状态具有积极作用,也为从肠道菌群的角度揭示通过饮食调控机体健康长寿的成效机制提供了参考依据。     

Bovine milk oligosaccharides decrease gut permeability and improve inflammation and microbial dysbiosis in diet-induced obese mice

Obesity is characterized by altered gut homeostasis, including dysbiosis and increased gut permeability closely linked to the development of metabolic disorders. Milk oligosaccharides are complex sugars that selectively enhance the growth of specific beneficial bacteria in the gastrointestinal tract and could be used as prebiotics. The aim of the study was to demonstrate the effects of bovine milk oligosaccharides (BMO) and Bifidobacterium longum ssp. infantis (B. infantis) on restoring diet-induced obesity intestinal microbiota and barrier function defects in mice. Male C57/BL6 mice were fed a Western diet (WD, 40% fat/kcal) or normal chow (C, 14% fat/kcal) for 7 wk. During the final 2 wk of the study, the diet of a subgroup of WD-fed mice was supplemented with BMO (7% wt/wt). Weekly gavage of B. infantis was performed in all mice starting at wk 3, yet B. infantis could not be detected in any luminal contents when mice were killed. Supplementation of the WD with BMO normalized the cecal and colonic microbiota with increased abundance of Lactobacillus compared with both WD and C mice and restoration of Allobaculum and Ruminococcus levels to that of C mice. The BMO supplementation reduced WD-induced increase in paracellular and transcellular flux in the large intestine as well as mRNA levels of the inflammatory marker tumor necrosis factor α. In conclusion, BMO are promising prebiotics to modulate gut microbiota and intestinal barrier function for enhanced health.     

Dietary whole Goji berry (Lycium barbarum) intake improves colonic barrier function by altering gut microbiota composition in mice

Diet strongly affects human health by modulating gut microbiota (GM) composition. Lycium barbarum (LB), which contains polysaccharides and polyphenols, can alter the GM and intestinal barrier function, thereby reducing and preventing the occurrence of intestinal diseases. To investigate how LB improves colonic barrier function, male C57BL/6J mice were fed diets containing 1.5% or 3% LB for 10 weeks. Results of HiSeq 16S rDNA analysis showed that LB markedly altered microbial profile by supporting the growth of Verrucomicrobia, Bacteroidetes, Bacteroidales_S24-7_group, Anaerotruncus, Coprococcus_1, Ruminococcaceae_UCG-014 and Akkermansia, while suppressing Firmicutes, Helicobacter, Bacteroides and Mucispirillum. LB supported the short-chain fatty acid (SCFA)-producing bacteria, and the SCFA concentrations increased, while the ammonia concentrations and pH values in faeces decreased, thereby increasing the expression of tight junction proteins and mucin, subsequently improving intestinal function and histomorphology. Dietary LB, as a functional dietary component, enhanced colonic barrier function and improved gut health by altering GM composition.     

Olive-Derived Antioxidant Dietary Fiber Modulates Gut Microbiota Composition and Attenuates Atopic Dermatitis Like Inflammation in Mice

Scope

Epidemiological data suggest that altered gut microbiota contributes to the development of atopic dermatitis (AD). The effect of an olive-derived antioxidant dietary fiber (OADF) in relieving AD symptoms in a murine model of 2,4-dinitrofluorobenzene (DNFB)-induced AD is examined and the effect of OADF in modulating host gut microbiota is explored.

Methods and results

Mice are fed with either standard diet or standard diet + OADF for 3 weeks prior to induction of AD and maintained on the same diet throughout the DNFB application period. Dietary OADF causes significant improvement of AD-like symptoms with reduced serum levels of immunoglobulin (Ig)E, interleukin (IL)-1β, IL-6, C-X-C motif ligand (CXCL)1, and increased serum levels of IL-10. OADF supplementation restore gut microbiota composition that are altered in AD mice. Specifically, OADF increases the proportion of intestinal bacteria (Ruminococcaceae UCG014, GCA900066575, UBA1819) associated with enhanced butyrate production, along with inhibiting Clostridiales vadin BB60 which are more prevalent in AD mice.

Conclusion

OADF modulates gut microbiota composition, improves cytokine profile and butyrate production influencing AD-associated immune response. Results highlight the importance of the gut-skin axis for the AD dietary therapeutic agents.     

Dietary Casein and Soy Protein Isolate Modulate the Effects of Raffinose and Fructooligosaccharides on the Composition and Fermentation of Gut Microbiota in Rats

Although diet has an important influence on the composition of gut microbiota, the impact of dietary protein sources has only been studied to a minor extent. In this study, we examined the influence of different dietary protein sources regarding the effects of prebiotic oligosaccharides on the composition and metabolic activity of gut microbiota. Thirty female rats were fed casein and soy protein isolate with cellulose, raffinose (RAF), and fructooligosaccharides (FOS). Microbiota composition was examined by real‐time qPCR and denaturing gradient gel electrophoresis. Dietary protein source affected cecum microbiota; acetic acid concentration and Lactobacillus spp. populations were greater with soy protein than with casein. Prebiotic oligosaccharides had distinctive effects on gut microbiota; RAF increased the acetic acid concentration and Bifidobacterium spp. populations, and FOS increased the butyric acid concentration regardless of the dietary protein. Likewise, Bifidobacterium sp., Collinsella sp., and Lactobacillus sp. were detected in microbiota of the rats fed RAF, and Bacteroides sp., Roseburia sp., and Blautia sp. were seen in microbiota of the rats fed FOS. Interactions between dietary proteins and prebiotic oligosaccharides were observed with Clostridium perfringens group populations and cecum IgA concentration. RAF and FOS decreased C. perfringens group populations in casein‐fed rats, and the combination of soy protein and RAF substantially increased cecum IgA concentration. These results indicate that dietary proteins can differentially modulate the effects of prebiotic oligosaccharides on gut fermentation and microbiota, depending on the type of carbohydrate polymers involved.     

Green tea polyphenols reduce obesity in high‐fat diet‐induced mice by modulating intestinal microbiota composition

In this study, the modulatory effect of green tea polyphenols (GTP) on human intestinal microbiota was investigated. Firstly, germ‐free mice were inoculated with faecal suspension derived from healthy volunteers to obtain human flora‐associated (HFA) mice model. When the high‐fat diet‐induced obese mice model was successfully established, they were randomly divided into high‐fat diet group (HFD) and high‐fat diet group with GTP (HFD‐GTP), and the shifts in relative abundance of the dominant taxa at the phylum, family and genus levels were studied by high‐throughput sequencing. The diversity of the total bacterial community reached the maximum after GTP treatment for 3 weeks, and then decreased when the mice were fed without GTP. Despite interindividual variation, the relative abundance of Bacteroidetes increased from 0.56 ± 0.06 (1st week) to 0.60 ± 0.05 (3th week), while Firmicutes decreased from 0.42 ± 0.06 to 0.37 ± 0.02. Interestingly, certain bacterial communities such as Bacteroidetes and Proteobacteria still increased and Firmicutes showed a decreasing trend when the mice were fed without GTP (4th week). The results showed that GTP benefits the stability of certain gut microbiota, especially in an environment‐triggered microbial imbalance; therefore, it may have prebiotic‐like activity contributing to the prevention of obesity.     

A critical review of the relationship between dietary components,the gut microbe Akkermansia muciniphila,and human health

Abstract

The human gut contains trillions of microorganisms with a great diversity that are associated with various health benefits. Recent studies have reported an increasing correlation between diet, gut microbiota, and human health, indicating rapid development in the field of gut health. Diet is an important factor that determines the gut microbiota composition. The gut comprises great diversities of microbes involved in immune modulation and other functions. In particular, Akkermansia muciniphila is a mucin-degrading bacterium is believed to have several health benefits in humans. Several studies have evaluated the prebiotic effects of various dietary components on A. muciniphila and their association with various ailments, such as diabetes mellitus, atherosclerosis, and cancer. Hence, this review aims to provide a plausible mechanistic basis for the interactions between dietary components, and A. muciniphila and for the therapeutic benefits of this interaction on various illnesses.