Characterization of Markers, Functional Properties, and Microbiome Composition in Human Gut-derived Bacterial Extracellular Vesicles

Overview

Journal Gut Microbes

Specialties Gastroenterology
Microbiology

Date 2023 Dec 1

PMID 38038385

Authors

Chih-Chi Li

Wei-Fan Hsu

Po-Chieh Chiang

Ming-Che Kuo

Andrew M Wo

Yufeng Jane Tseng

Affiliations

Soon will be listed here.

Abstract

Past studies have confirmed the etiologies of bacterial extracellular vesicles (BEVs) in various diseases, including inflammatory bowel disease (IBD) and colorectal cancer (CRC). This study aimed to investigate the characteristics of stool-derived bacterial extracellular vesicles (stBEVs) and discuss their association with stool bacteria. First, three culture models - gram-positive (G+)BEVs (from ), gram-negative (G-)BEVs (from ), and eukaryotic cell-derived EVs (EEV, from Colo205 cell line) - were used to benchmark various fractions of stEVs separated from optimized density gradient approach (DG). As such, WB, TEM, NTA, and functional assays, were utilized to analyze properties and distribution of EVs in cultured and stool samples. Stool samples from healthy individuals were interrogated using the approaches developed. Results demonstrated successful separation of most stBEVs (within DG fractions 8&9) from stEEVs (within DG fractions 5&6). Data also suggest the presence of stBEV DNA within vesicles after extraction of BEV DNA and DNase treatment. Metagenomic analysis from full-length (FL) region sequencing results confirmed significant differences between stool bacteria and stBEVs. Significantly, F8&9 and the pooled sample (F5-F9) exhibited a similar microbial composition, indicating that F8&9 were enriched in most stBEV species, primarily dominated by (89.6%). However, F5&6 and F7 still held low-density BEVs with a significantly higher proportion of (20.5% and 40.7%, respectively) and (24% and 13.7%, respectively), considerably exceeding the proportions in stool and F8&9. Importantly, among five healthy individuals, significant variations were observed in the gut microbiota composition of their respective stBEVs, indicating the potential of stBEVs as a target for personalized medicine and research.

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