Your search keyword '"Yu, Guangli"' showing total 16 results

1. Bacteroides salyersiae is a potent chondroitin sulfate-degrading species in the human gut microbiota.

Author

Wang, Yamin, Ma, Mingfeng, Dai, Wei, Shang, Qingsen, and Yu, Guangli

Subjects

HUMAN microbiota, GUT microbiome, CHONDROITIN sulfates, BACTEROIDES, CHONDROITIN, SHORT-chain fatty acids

Abstract

Chondroitin sulfate (CS) has widely been used as a symptomatic slow-acting drug or a dietary supplement for the treatment and prevention of osteoarthritis. However, CS could not be absorbed after oral intake due to its polyanionic nature and large molecular weight. Gut microbiota has recently been proposed to play a pivotal role in the metabolism of drugs and nutrients. Nonetheless, how CS is degraded by the human gut microbiota has not been fully characterized. In the present study, we demonstrated that each human gut microbiota was characterized with a unique capability for CS degradation. Degradation and fermentation of CS by the human gut microbiota produced significant amounts of unsaturated CS oligosaccharides (CSOSs) and short-chain fatty acids. To uncover which microbes were responsible for CS degradation, we isolated a total of 586 bacterial strains with a potential CS-degrading capability from 23 human fecal samples. Bacteroides salyersiae was a potent species for CS degradation in the human gut microbiota and produced the highest amount of CSOSs as compared to other well-recognized CS-degraders, including Bacteroides finegoldii, Bacteroides thetaiotaomicron, Bacteroides xylanisolvens, and Bacteroides ovatus. Genomic analysis suggested that B. salyersiae was armed with multiple carbohydrate-active enzymes that could potentially degrade CS into CSOSs. By using a spent medium assay, we further demonstrated that the unsaturated tetrasaccharide (udp4) produced by the primary degrader B. salyersiae could serve as a "public goods" molecule for the growth of Bacteroides stercoris, a secondary CS-degrader that was proficient at fermenting CSOSs but not CS. Taken together, our study provides insights into the metabolism of CS by the human gut microbiota, which has promising implications for the development of medical and nutritional therapies for osteoarthritis. DpwXZ6r7Gzgb1kGmYdwQH9 Video Abstract [ABSTRACT FROM AUTHOR]

Published

2024

2. Canagliflozin Prevents Lipid Accumulation, Mitochondrial Dysfunction, and Gut Microbiota Dysbiosis in Mice With Diabetic Cardiovascular Disease.

Author

Wang, Xueliang, Wang, Zhe, Liu, Di, Jiang, Hao, Cai, Chao, Li, Guoyun, and Yu, Guangli

Subjects

SODIUM-glucose cotransporters, GUT microbiome, CARDIOVASCULAR diseases, TYPE 2 diabetes, CANAGLIFLOZIN, DYSBIOSIS

Abstract

Type 2 diabetes mellitus (T2DM) is associated with cardiovascular disease (CVD) and sodium glucose cotransporter 2 inhibitors, as oral medications for T2DM treatment have shown the potential to improve vascular dysfunction. The aim of this study was to evaluate the ability of canagliflozin (Cana) to relieve CVD in T2DM mice and its possible action mechanism. Mice with diabetic CVD was conducted by a high-fat diet for 24 weeks, followed by oral gavaging with metformin (200 mg/kg/day) or Cana (50 mg/kg/day) for 6 weeks. The result demonstrated that Cana reduced serum lipid accumulation, and decreased the arteriosclerosis index and atherogenic index of plasma. In addition, Cana treatment reduced the circulating markers of inflammation. More importantly, Cana improved cardiac mitochondrial homeostasis and relieved oxidative stress. Moreover, Cana treatment alleviated the myocardial injury with decreasing levels of serous soluble cluster of differentiation 40 ligand and cardiac troponin I. Thus, cardiovascular abnormality was relieved by suppressing fibrosis and basement membrane thickening, while elevating the cluster of differentiation 31 expression level. Importantly, Cana increased the ratio of gut bacteria Firmicutes/Bacteroidetes and the relative abundance of Alistipes , Olsenella , and Alloprevotella , while it decreased the abundance of Mucispirillum , Helicobacter , and Proteobacteria at various taxonomic levels in mice with diabetic CVD. In short, Cana treatment altered the colonic microbiota composition close to the normal level, which was related with blood lipid, inflammation, and oxidative stress, and might play a vital role in CVD. In general, the improvements in the gut microbiota and myocardial mitochondrial homeostasis may represent the mechanism of Cana on CVD treatment. [ABSTRACT FROM AUTHOR]

Published

2022

3. Enterotype-Specific Effect of Human Gut Microbiota on the Fermentation of Marine Algae Oligosaccharides: A Preliminary Proof-of-Concept In Vitro Study.

Author

Fu, Tianyu, Zhou, Luning, Fu, Zhiliang, Zhang, Bin, Li, Quancai, Pan, Lin, Zhou, Chen, Zhao, Qing, Shang, Qingsen, and Yu, Guangli

Subjects

HUMAN microbiota, GUT microbiome, OLIGOSACCHARIDES, CARBOHYDRATE metabolism, MARINE algae, FERMENTATION, DIETARY carbohydrates

Abstract

The human gut microbiota plays a critical role in the metabolism of dietary carbohydrates. Previous studies have illustrated that marine algae oligosaccharides could be utilized and readily fermented by human gut microbiota. However, the human gut microbiota is classified into three different enterotypes, and how this may affect the fermentation processes of marine algae oligosaccharides has not been studied. Here, using in vitro fermentation and 16 S high-throughput sequencing techniques, we demonstrate that the human gut microbiota has an enterotype-specific effect on the fermentation outcomes of marine algae oligosaccharides. Notably, microbiota with a Bacteroides enterotype was more proficient at fermenting carrageenan oligosaccharides (KOS) as compared to that with a Prevotella enterotype and that with an Escherichia enterotype. Interestingly, the prebiotic effects of marine algae oligosaccharides were also found to be enterotype dependent. Altogether, our study demonstrates an enterotype-specific effect of human gut microbiota on the fermentation of marine algae oligosaccharides. However, due to the availability of the fecal samples, only one sample was used to represent each enterotype. Therefore, our research is a proof-of-concept study, and we anticipate that more detailed studies with larger sample sizes could be conducted to further explore the enterotype-specific prebiotic effects of marine oligosaccharides. [ABSTRACT FROM AUTHOR]

Published

2022

4. Dietary Polysaccharide from Enteromorpha clathrata Attenuates Obesity and Increases the Intestinal Abundance of Butyrate-Producing Bacterium, Eubacterium xylanophilum , in Mice Fed a High-Fat Diet.

Author

Wei, Jiali, Zhao, Yiran, Zhou, Chen, Zhao, Qing, Zhong, Hongqian, Zhu, Xinyu, Fu, Tianyu, Pan, Lin, Shang, Qingsen, and Yu, Guangli

Subjects

HIGH-fat diet, EUBACTERIALES, ENTEROMORPHA, INTESTINES, NUCLEOTIDE sequencing, GUT microbiome

Abstract

Previous studies have suggested that polysaccharide from Enteromorpha clathrata (ECP) could be used as a potential prebiotic to treat dysbiosis-associated diseases. However, whether it has any therapeutic effects on obesity has not been investigated. In the present study, we explored the anti-obesity effect of ECP and illustrated that it can significantly reduce the body weight and decrease the serum levels of triacylglycerol and cholesterol in high-fat diet (HFD)-fed mice. As revealed by 16S rRNA high-throughput sequencing and bioinformatic analysis, HFD remarkably changed the composition of the gut microbiota and promoted the growth of opportunistic pathogens such as Mucispirillum, Desulfobacterota and Alphaproteobacteria in obese mice. Interestingly, ECP improved intestinal dysbiosis caused by HFD and reshaped the structure of the gut microbiota in diseased mice by increasing the abundance of butyrate-producing bacterium, Eubacterium xylanophilum, in the gut. Altogether, we demonstrate for the first time an anti-obesity effect of ECP and shed new light into its therapeutic mechanisms from the perspective of gut microbiota. Our study will pave the way for the development of ECP as new prebiotic for the treatment of obesity and its associated disorders. [ABSTRACT FROM AUTHOR]

Published

2021

5. Degradation and fermentation of hyaluronic acid by Bacteroides spp. from the human gut microbiota.

Author

Fang, Ziyi, Ma, Mingfeng, Wang, Yamin, Dai, Wei, Shang, Qingsen, and Yu, Guangli

Subjects

*HUMAN microbiota, *GUT microbiome, *BACTEROIDES fragilis, *BACTEROIDES, *HYALURONIC acid, *CARBOHYDRATE metabolism, *KEYSTONE species

Abstract

Bacteroides spp. are prominent members of the human gut microbiota that play critical roles in the metabolism of complex carbohydrates from the daily diet. Hyaluronic acid (HA) is a multifunctional polysaccharide which has been extensively used in the food and biomedical industry. However, how HA is degraded and fermented by Bacteroides spp. has not been fully characterized. Here, we comprehensively investigated the detailed degradation profiles and fermentation characteristics of four different HAs with discrete molecular weight (Mw) by fourteen distinctive Bacteroides spp. from the human gut microbiota. Our results indicated that high-Mw HAs were more degradable and fermentable than low-Mw HAs. Interestingly, B. salyersiae showed the best degrading capability for both high-Mw and low-Mw HAs, making it a keystone species for HA degradation among Bacteroides spp.. Specifically, HA degradation by B. salyersiae produced significant amounts of unsaturated tetrasaccharide (udp4). Co-culture experiments indicated that the produced udp4 could be further fermented and utilized by non-proficient HA-degraders, suggesting a possible cross-feeding interaction in the utilization of HA within the Bacteroides spp.. Altogether, our study provides novel insights into the metabolism of HA by the human gut microbiota, which has considerable implications for the development of new HA-based nutraceuticals and medicines. [ABSTRACT FROM AUTHOR]

Published

2024

6. Fermentation of alginate and its derivatives by different enterotypes of human gut microbiota: Towards personalized nutrition using enterotype-specific dietary fibers.

Author

Fu, Tianyu, Pan, Lin, Shang, Qingsen, and Yu, Guangli

Subjects

*GUT microbiome, *HUMAN microbiota, *ALGINATE derivatives, *ALGINATES, *ENTEROTYPES, *FOOD additives, *BUTYRATES, *DIETARY fiber

Abstract

Alginate and its derivatives are widely used as food additives and dietary fibers. Previous studies indicated that alginate, polyguluronate (PG) and polymannuronate acid (PM) could be fermented by human gut microbiota. However, how different compositions of the microbiota may affect the fermentation outcomes of these polysaccharides remains unknown. Here we show that Bacteroides -dominated microbiota (Bacteroides enterotype) is more proficient at degrading and utilizing PG and PM as compared to Prevotella -dominated (Prevotella enterotype) and Escherichia -dominated microbiota (Escherichia enterotype). Enterotype dictates the fermentation outcomes of the three fibers and the amount of short-chain fatty acids (SCFAs) that are produced. Fermentation of alginate and PM by Bacteroides -dominated microbiota produced the highest amount of total SCFAs and butyrate. Our study demonstrates an enterotype-specific effect of microbiota on the fermentation of alginate and its derivatives and highlights that personalized nutrition using dietary fibers should be tailored according to individual's composition of the gut microbiome. • Enterotype poses a significant effect on the fermentation outcomes of alginate and its derivatives. • Fermentation of alginate and its derivatives by human gut microbiota is enterotype-specific. • Personalized nutrition using dietary fibers should be tailored in accordance with individual's enterotype. [ABSTRACT FROM AUTHOR]

Published

2021

7. Recent progress and advanced technology in carbohydrate-based drug development.

Author

Pan, Lin, Cai, Chao, Liu, Chanjuan, Liu, Di, Li, Guoyun, Linhardt, Robert J, and Yu, Guangli

Subjects

*DRUG development, *GUT microbiome, *CARBOHYDRATES, *BIOMOLECULES, *CANNABIDIOL, *GLYCOCONJUGATES, *MICROFLUIDICS

Abstract

[Display omitted] • A brief overview of CBD development in recent decades is presented. • Approaches for accessing specific carbohydrates and glycoconjugates are clarified. • Microarray and library are critical for rapid screening of bioactive carbohydrates. • Gut microbiota system is promising for evaluation of orally administrated CBD. • Advanced technologies and toolkit accelerated the CBD discovery. Carbohydrates, one of the most abundant and widespread biomolecules in nature, play indispensable roles in diverse biological functions, and represent a treasure trove of untapped potential for pharmaceutical applications. Here, we provide a brief overview of carbohydrate-based drug development (CBDD) over the past two decades. More importantly, advanced techniques and methodologies related to CBDD are emerging, including enzymatic synthesis, metabolic engineering, site-specific glycoconjugation, carbohydrate libraries and microarrays as well as carbohydrate-gut microbiome evaluation. These technologies have dramatically accelerated the speed of CBDD. The recently approved drugs and emerging techniques summarized herein will inspire new sights into potential opportunities to discover novel carbohydrate drugs. [ABSTRACT FROM AUTHOR]

Published

2021

8. Marine polysaccharides attenuate metabolic syndrome by fermentation products and altering gut microbiota: An overview.

Author

Wang, Xueliang, Wang, Xin, Jiang, Hao, Cai, Chao, Li, Guoyun, Hao, Jiejie, and Yu, Guangli

Subjects

*POLYSACCHARIDES, *METABOLIC syndrome, *FERMENTATION, *GUT microbiome, *PEROXISOMES

Abstract

Marine polysaccharides (MPs), including plant, animal, and microbial-derived polysaccharides, can alleviate metabolic syndrome (MetS) by different regulation mechanisms. MPs and their derivatives can attenuate MetS by vary cellular signal pathways, such as peroxisome proliferator-activated receptor, 5′ adenosine monophosphate-activated protein kinase, and CCAAT/enhancer binding protein-α. Also, most of MPs cannot be degraded by human innate enzymes, but they can be degraded and fermented by human gut microbiota. The final metabolic products of these polysaccharides are usually short-chain fatty acids (SCFAs), which can change the gut microbiota ecology by altering the existing percentage of special microorganisms. In addition, the SCFAs and changed gut microbiota can regulate enteroendocrine hormone secretion, blood glucose, lipid metabolism levels, and other MetS symptoms. Here, we summarize the up-to-date findings on the effects of MPs, particularly marine microbial-derived polysaccharides, and their metabolites on attenuating MetS. [ABSTRACT FROM AUTHOR]

Published

2018

9. Gut microbiota fermentation of marine polysaccharides and its effects on intestinal ecology: An overview.

Author

Shang, Qingsen, Jiang, Hao, Cai, Chao, Hao, Jiejie, Li, Guoyun, and Yu, Guangli

Subjects

*POLYSACCHARIDES, *FERMENTATION, *GUT microbiome, *MAMMAL ecology, *HOMEOSTASIS

Abstract

The gut microbiota that resides in the mammalian intestine plays a critical role in host health, nutrition, metabolic and immune homeostasis. As symbiotic bacteria, these microorganisms depend mostly on non-digestible fibers and polysaccharides as energy sources. Dietary polysaccharides that reach the distal gut are fermented by gut microbiota and thus exert a fundamental impact on intestinal ecology. Marine polysaccharides contain a class of dietary fibers that are widely used in food and pharmaceutical industries (e.g., agar and carrageenan). In this regard, insights into fermentation of marine polysaccharides and its effects on intestinal ecology are of vital importance for understanding the beneficial effects of these glycans. Here, in this review, to provide an overlook of current advances and facilitate future studies in this field, we describe and summarize up-to-date findings on how marine polysaccharides are metabolized by gut microbiota and what effects these polysaccharides have on intestinal ecology. [ABSTRACT FROM AUTHOR]

Published

2018

10. Carrageenan-induced colitis is associated with decreased population of anti-inflammatory bacterium, Akkermansia muciniphila, in the gut microbiota of C57BL/6J mice.

Author

Shang, Qingsen, Sun, Weixia, Shan, Xindi, Jiang, Hao, Cai, Chao, Hao, Jiejie, Li, Guoyun, and Yu, Guangli

Subjects

*CARRAGEENANS, *COLITIS, *ANTI-inflammatory agents, *AKKERMANSIA muciniphila, *GUT microbiome

Abstract

Carrageenan as a food additive has been used for years. However, controversy exists regarding to the safety of carrageenan and accumulating evidence indicates that it could induce colitis in experimental models. Here, to provide more information on this issue and solve the debate, we studied and compared in detail the toxic effects of different isomers of carrageenan (κ-, ι-, and λ-) on the colon of C57BL/6J mice. Interestingly, all isomers of carrageenan were found to induce colitis with a comparable activity. Given that carrageenan is unabsorbed after oral administration, and also in light of the fact that gut microbiota plays a pivotal role in the pathogenesis of colitis, we further investigated the effect of carrageenan on gut microbiota using high-throughput sequencing. Intriguingly, carrageenan-induced colitis was observed to be robustly correlated with changes in the composition of gut microbiota. Specifically, all carrageenans significantly decreased the abundance of a potent anti-inflammatory bacterium, Akkermansia muciniphila , in the gut, which is highly relevant for understanding the toxic effect of carrageenan. Altogether, our results corroborate previous studies demonstrating harmful gastrointestinal effect of carrageenan and, from a gut microbiota perspective, shed new light into the mechanism by which carrageenan induces colitis in experimental animals. [ABSTRACT FROM AUTHOR]

Published

2017

11. Structural modulation of gut microbiota by chondroitin sulfate and its oligosaccharide.

Author

Shang, Qingsen, Shi, Jingjing, Song, Guanrui, Zhang, Meifang, Cai, Chao, Hao, Jiejie, Li, Guoyun, and Yu, Guangli

Subjects

*GUT microbiome, *CHONDROITIN sulfates, *OLIGOSACCHARIDES, *DIETARY supplements, *PREVOTELLACEAE, *MULTIPLE correspondence analysis (Statistics)

Abstract

Chondroitin sulfate (CS) as a dietary supplement and a symptomatic slow acting (SYSA) drug has been used for years. Recently, CS has been demonstrated to be readily degraded and fermented in vitro by specific human gut microbes, hinting that dietary CS may pose a potential effect on gut microbiota composition in vivo . However, until now, little information is available on modulations of gut microbiota by CS. In the present study, modulations of gut microbiota in Kunming mice by CS and its oligosaccharide (CSO) were investigated by high-throughput sequencing. As evidenced by Heatmap and principal component analysis (PCA), the female microbiota were more vulnerable than the male microbiota to CS and CSO treatment. Besides, it is of interest to found that CS and CSO had differing effects on the abundance of Bacteroidales S24-7 , Bacteroides , Helicobacter , Odoribacter , Prevotellaceae and Lactobacillus in male mice versus female mice. Collectively, we demonstrated a sex-dependent effect on gut microbiota of CS and CSO. In addition, since gut microbiota exerts a major effect on host physiology, our study highlighted that certain beneficial effects of CS may be associated with modulations of gut microbiota, which merits further investigation. [ABSTRACT FROM AUTHOR]

Published

2016

12. In vitro fermentation of alginate and its derivatives by human gut microbiota.

Author

Li, Miaomiao, Li, Guangsheng, Shang, Qingsen, Chen, Xiuxia, Liu, Wei, Pi, Xiong'e, Zhu, Liying, Yin, Yeshi, Yu, Guangli, and Wang, Xin

Subjects

*GUT microbiome, *ALGINIC acid, *FERMENTATION, *FOOD additives, *BACTEROIDES thetaiotaomicron

Abstract

Alginate (Alg) has a long history as a food ingredient in East Asia. However, the human gut microbes responsible for the degradation of alginate and its derivatives have not been fully understood yet. Here, we report that alginate and the low molecular polymer derivatives of mannuronic acid oligosaccharides (MO) and guluronic acid oligosaccharides (GO) can be completely degraded and utilized at various rates by fecal microbiota obtained from six Chinese individuals. However, the derivative of propylene glycol alginate sodium sulfate (PSS) was not hydrolyzed. The bacteria having a pronounced ability to degrade Alg, MO and GO were isolated from human fecal samples and were identified as Bacteroides ovatus , Bacteroides xylanisolvens , and Bacteroides thetaiotaomicron . Alg, MO and GO can increase the production level of short chain fatty acids (SCFA), but GO generates the highest level of SCFA. Our data suggest that alginate and its derivatives could be degraded by specific bacteria in the human gut, providing the basis for the impacts of alginate and its derivates as special food additives on human health. [ABSTRACT FROM AUTHOR]

Published

2016

13. Degradation of chondroitin sulfate by the gut microbiota of Chinese individuals.

Author

Shang, Qingsen, Yin, Yeshi, Zhu, Liying, Li, Guoyun, Yu, Guangli, and Wang, Xin

Subjects

*CHONDROITIN sulfates, *GUT microbiome, *BIODEGRADATION, *CHINESE people, *OSTEOARTHRITIS treatment, *DISEASES

Abstract

Oral preparations of chondroitin sulfate (CS) have long been used as anti-osteoarthritis (anti-OA) drugs. However, little is known about the degradation of CS by human gut microbiota. In the present study, degradation profiles of CSA (the main constituent of CS drugs) by the human gut microbiota from six healthy subjects were investigated. Each individual’s microbiota had differing degradation activities, but ΔUA-GalNAc4S was the end product in all cases. To elucidate the mechanisms underlying this phenomenon, different CSA-degrading bacteria were isolated from each individual’s microbiota and tested for CSA degradation. In addition to Bacteroides thetaiotaomicron J1, Bacteroides thetaiotaomicron 82 and Bacteroides ovatus E3, a new CSA-degrading bacterium, Clostridium hathewayi R4, was isolated and characterized. Interestingly, at least two different CSA-degrading species were identified from each individual’s gut microbiota. Predictably, these functional bacteria also had differing degradation rates, but still generated the same end product, ΔUA-GalNAc4S. In addition, the human fecal isolates produced different degradation profiles for CSC, CSD, and CSE, suggesting that CS could be readily metabolized to varying extents by diverse microbial consortiums, which may help to explain the poor bioavailability and unequal efficacy of CS among individuals in OA treatment. [ABSTRACT FROM AUTHOR]

Published

2016

14. Polysaccharide from edible alga Gloiopeltis furcata attenuates intestinal mucosal damage by therapeutically remodeling the interactions between gut microbiota and mucin O-glycans.

Author

Pan, Lin, Fu, Tianyu, Cheng, Hao, Mi, Jianchen, Shang, Qingsen, and Yu, Guangli

Subjects

*GUT microbiome, *MUCINS, *DEXTRAN sulfate, *DEXTRAN, *INTESTINES, *ALGAE

Abstract

Gloiopeltis furcata is an edible alga that has long been consumed in China. However, the bioactive polysaccharides from G. furcata have been largely unexplored. Here, we show for the first time that a sulfated polysaccharide from G. furcata (SAO) could improve the integrity of the colonic epithelial layer and protect against dextran sulfate sodium-induced intestinal mucosal damage. Mechanistically, SAO attenuated colonic mucosal damage by therapeutically remodeling the interactions between gut microbiota and mucin O -glycans. Specifically, SAO increased the proportions of complex long-chain mucin O -glycans in the epithelial layer with two terminal N -acetylneuraminic acid residues and promoted the growth of probiotic bacteria including Roseburia spp. and Muribaculaceae. Altogether, our study demonstrates a novel application of SAO for the treatment of inflammatory bowel disease-associated mucosal damage and forms the basis to understand the therapeutic effects of natural polysaccharides from the perspective of symbiotic interactions between host mucin O -glycome and gut microbiome. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

15. In vitro fermentation of hyaluronan by human gut microbiota: Changes in microbiota community and potential degradation mechanism.

Author

Pan, Lin, Ai, Xuze, Fu, Tianyu, Ren, Li, Shang, Qingsen, Li, Guoyun, and Yu, Guangli

Subjects

*GUT microbiome, *HUMAN microbiota, *HYALURONIC acid, *GLYCOSIDASES, *FERMENTATION, *BIOAVAILABILITY, *FOOD fermentation

Abstract

Hyaluronan (HA) has been widely used as a dietary supplement which can be degraded by gut microbiota. However, the interactions between HA and gut microbiota have not been fully characterized. Here, using an in vitro system, we found that HA is readily fermented by human gut microbiota but with differing fermentative activities among individuals. HA-fermentation boosted Bacteroides spp., Bifidobacterium spp., Dialister spp., Faecalibacterium spp. and produced a significant amount of acetate, propionate and butyrate. Fermentation products profiling indicated that HA could be degraded into unsaturated even-numbered and saturated odd-numbered oligosaccharides. Further, polysaccharide lyases (PLs) and glycoside hydrolases (GHs) including GH88, PL8, PL29, PL35 and PL33 were identified from B. ovatus E3, which can help to explain the structure of the fermentation products. Collectively, our study sheds new light into the metabolism of HA and forms the basis for understanding the bioavailability of HA from a gut microbiota perspective. [Display omitted] • HA is fermented by gut microbiota with differing fermentative activities. • HA fermentation can modulate the gut microbiota and produced SCFAs. • HA was degraded into unsaturated even-numbered and saturated odd-numbered oligosaccharides. • Bacteroides spp. play critical roles in the HA degradation. • GH88, PL8, PL29, PL35 and PL33 were identified as HA-active enzymes. [ABSTRACT FROM AUTHOR]

Published

2021

16. In vitro fermentation and isolation of heparin-degrading bacteria from human gut microbiota.

Author

Pan, Lin, Sun, Weixia, Shang, Qingsen, Niu, Qingfeng, Liu, Chanjuan, Li, Guoyun, and Yu, Guangli

Subjects

*GUT microbiome, *HUMAN microbiota, *BIOAVAILABILITY, *HEPARIN, *FERMENTATION, *BACTERIA, *BACTEROIDES fragilis

Abstract

Heparin and its derivative are commonly used as injectable anticoagulants in clinical procedures, but possess poor oral bioavailability. To explore the role of gut microbiota in the poor oral effect of heparin, the degradation profiles of heparin on six human gut microbiota were investigated. The heparin-degradation ability varied significantly among individuals. Furthermore, two strains of heparin-degrading bacteria, Bacteroides ovatus A2 and Bacteroides cellulosilyticus B19, were isolated from the gut microbiota of different individuals and the degradation products of the isolates were profiled. The ΔUA2S-GlcNS6S was the major end product with almost no desulfation. 3- O -sulfo group-containing tetrasaccharides were detected, which indicated that the antithrombin binding site was broken and this explained the lost anticoagulant activity of heparin. Collectively, the present study assessed the degradation profiles of heparin by human gut microbiota and provided references for the development of oral administration of heparin from a gut microbiota perspective. • The heparin-degradation ability varied significantly among individuals. • B. ovatus and B. cellulosilyticus isolated from human fecal could degrade heparin. • The ΔUA2S-GlcNS6S was the major end degradation product in all isolates. • The products of 3- O -sulfo group-containing tetrasacchardes were detected. • Several breakdown products explained the destroyed anticoagulant activity of heparin. [ABSTRACT FROM AUTHOR]

Published

2021