Peter Yuli Xing scite author profile

While modulatory effects of gut microbes on neurological phenotypes have been reported, the mechanisms remain largely unknown. Here, we demonstrate that indole, a tryptophan metabolite produced by tryptophanase-expressing gut microbes, elicits neurogenic effects in the adult mouse hippocampus. Neurogenesis is reduced in germ-free (GF) mice and in GF mice monocolonized with a single-gene tnaA knockout (KO) mutant Escherichia coli unable to produce indole. External administration of systemic indole increases adult neurogenesis in the dentate gyrus in these mouse models and in specific pathogen-free (SPF) control mice. Indole-treated mice display elevated synaptic markers postsynaptic density protein 95 and synaptophysin, suggesting synaptic maturation effects in vivo. By contrast, neurogenesis is not induced by indole in aryl hydrocarbon receptor KO (AhR−/−) mice or in ex vivo neurospheres derived from them. Neural progenitor cells exposed to indole exit the cell cycle, terminally differentiate, and mature into neurons that display longer and more branched neurites. These effects are not observed with kynurenine, another AhR ligand. The indole-AhR–mediated signaling pathway elevated the expression of β-catenin, Neurog2, and VEGF-α genes, thus identifying a molecular pathway connecting gut microbiota composition and their metabolic function to neurogenesis in the adult hippocampus. Our data have implications for the understanding of mechanisms of brain aging and for potential next-generation therapeutic opportunities.

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Microbial Metabolites and Intestinal Stem Cells Tune Intestinal Homeostasis

Xing

Pettersson

Kundu

2020

Proteomics

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Microorganisms that colonize the gastrointestinal tract, collectively known as the gut microbiota, are known to produce small molecules and metabolites that significantly contribute to host intestinal development, functions, and homeostasis. Emerging insights from microbiome research reveal that gut microbiota‐derived signals and molecules influence another key player maintaining intestinal homeostasis—the intestinal stem cell niche, which regulates epithelial self‐renewal. In this review, the literature on gut microbiota‐host crosstalk is surveyed, highlighting the effects of gut microbial metabolites on intestinal stem cells. The production of various classes of metabolites, their actions on intestinal stem cells are discussed and, finally, how the production and function of metabolites are modulated by aging and dietary intake is commented upon.

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Microbe-derived indole tunes organ-function and links microbe metabolites to biological ageing

Xing

Jayaraman

Zhang

et al. 2023

Preprint

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To investigate the underlying molecular mechanisms on how the gut microbe metabolite, indoles, regulate host organ growth and function, germ-free male mice were mono-colonized with indole-producing wildtype Escherichia coli or tryptophanase-encoding tnaA knockout mutant indole-non-producing E. coli. The indole mutant E. coli recipient mice exhibited significant multiorgan decline and growth retardation combined with catabolism and energy deficiency despite increased food intake compared to control mice. In addition, indole mutant mice displayed malfunctional intestine, enlarged caecum, reduced numbers of colonic enterochromaffin cells and reduced circulating serotonin levels, resulting in reduced gut motility, diminished digestion, and lower energy harvest. Furthermore, indole mutant mice also displayed decreased expression of Kcnj12 gene, suggesting reduced excitability of enteric neurons thus adding to intestinal dysfunctional phenotype. In conclusion, indoles are necessary to maintain adult metabolic homeostasis across multiple organs in vivo. Impairment of indole levels results in multiorgan functional decline suggesting a mechanism whereby gut microbe metabolites may regulate biological ageing and thus increase the risk for disease.

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Peter Yuli Xing

Tryptophan-metabolizing gut microbes regulate adult neurogenesis via the aryl hydrocarbon receptor

Microbial Metabolites and Intestinal Stem Cells Tune Intestinal Homeostasis

Microbe-derived indole tunes organ-function and links microbe metabolites to biological ageing

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