Gut Microbiota Participates and Remodels Host Metabolism: From Treating Patients to Treating Their Gut Flora

Overview

Journal World J Gastroenterol

Publisher Baishideng Publishing Group

Specialty Gastroenterology

Date 2024 Dec 9

PMID 39649550

Authors

Shuang Han

Rui-Hua Li

Peng Gao

Affiliations

Soon will be listed here.

Abstract

In this editorial, we comment on Liu s article published in the recent issue of the . Biochemically and pathologically, Liu proved that the urate-lowering activity of leech total protein (LTP) was mainly attributed to the rectification of gut microbiota. Specifically, we noticed the change in and after LTP administration. Both bacteria have been reported to alleviate metabolic dysfunction-associated steatohepatitis and other chronic metabolic diseases. LTP was administrated through intragastric manners. Most possibly, LTP would be digested by the gut microbiota further. The anti-hyperuricemia effects should, to the most possible extent, be exerted by the peptides or their secondary metabolic products. Human gut microbiota communicates with other organs through metabolites generated by the microbes or co-metabolized with the host. Whether the anti-hyperuricemia effect could be partially ascribed to the microbiota metabolites also deserves to be discussed. Although metabolomics analysis was performed for serum samples, fecal metabolomics was highly advocated which could facilitate exact mechanism explanation. This study implied that gut microbiota contains many unexplored targets with different therapeutic potentials. It is foreseeable that utilizing these targets can avoid the impairment or side effects of directly using human targets to some extent.

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