Enteromorpha prolifera Diet Drives Intestinal Microbiome Composition in Siganus oramin

Enteromorpha prolifera ( E. prolifera ) contains complex sulfated polysaccharides that are resistant to biological degradation. Most organisms cannot digest biomass of E. prolifera , except Siganus oramin ( S. oramin) . This study was conducted to identify the bacteria in the intestine of S. oramin...

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Bibliographic Details
Published in:Current microbiology 2021, Vol.78 (1), p.229-237
Main Authors: Xu, Yan, Li, Jin, Han, Xuefeng, Zhang, Zhibiao, Zhong, Mingqi, Hu, Zhong
Format: Article
Language:English
Subjects:
Algae
Bacteria
Bacteroidetes
Biodegradation
Biomedical and Life Sciences
Biotechnology
Diet
Digestion
Enteromorpha prolifera
Esterases
Firmicutes
Flora
Gastrointestinal Microbiome - genetics
Gene expression
Gene sequencing
Genes
Glycosidases
Glycoside hydrolase
Humans
Hydrolase
Intestinal microflora
Intestine
Life Sciences
Metagenome
Metagenomics
Microbiology
Microbiomes
Microbiota
Next-generation sequencing
Polysaccharides
rRNA 16S
Saccharides
Sequence analysis
Siganus oramin
Sulfate resistance
Ulva
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Summary:Enteromorpha prolifera ( E. prolifera ) contains complex sulfated polysaccharides that are resistant to biological degradation. Most organisms cannot digest biomass of E. prolifera , except Siganus oramin ( S. oramin) . This study was conducted to identify the bacteria in the intestine of S. oramin facilitating the digestion of E. prolifera polysaccharides (EPP) . Metagenomic sequencing analysis of the S. oramin intestinal microbiota revealed that E. prolifera diet increased the number of Firmicutes, replacing Proteobacteria to be the dominant bacteria. The proportion of Firmicutes increased from 38.8 to 58.6%, with Bacteroidetes increasing nearly fivefold from 5 to 23.7%. 16S rDNA high-throughput sequencing showed that EPP-induced Bacteroidetes increased significantly in the intestinal flora of S. oramin cultivated in vitro. Metatranscriptome analysis showed that EPP induced more transferase, polysaccharide hydrolase, glycoside hydrolase, and esterases expressed in vitro, and most of them were taxonomically annotated to Bacteroidetes. Compared with the aggregation of GH family genes in metagenomic sequencing analysis in vivo, EPP induced more CBM32, GH2, GT2, GT30, and GH30 families gene expression in vitro. In general, We found that the bacteria in intestinal tract of S. oramin responsible for digestion of E. prolifera were Firmicutes and Bacteroidetes, while Bacteroidetes was the dominant bacteria involved in EPP degradation in vitro cultures. Compared with in vivo experiments, only GH family genes were mostly involved, we detected a more complete and complex EPP degradation pathway in vitro. The results may benefit the further study of biodegradation of E. prolifera and has potential implications for the utilization of E. prolifera for biotechnology.
ISSN:0343-8651
1432-0991
DOI:10.1007/s00284-020-02218-6