Microbial assimilatory sulfate reduction-mediated H 2 S: an overlooked role in Crohn's disease development.

Background: H ₂ S imbalances in the intestinal tract trigger Crohn's disease (CD), a chronic inflammatory gastrointestinal disorder characterized by microbiota dysbiosis and barrier dysfunction. However, a comprehensive understanding of H ₂ S generation in the gut, and the contributions of both microbiota and host to systemic H ₂ S levels in CD, remain to be elucidated. This investigation aimed to enhance comprehension regarding the sulfidogenic potential of both the human host and the gut microbiota.
Results: Our analysis of a treatment-naive CD cohorts' fecal metagenomic and biopsy metatranscriptomic data revealed reduced expression of host endogenous H ₂ S generation genes alongside increased abundance of microbial exogenous H ₂ S production genes in correlation with CD. While prior studies focused on microbial H ₂ S production via dissimilatory sulfite reductases, our metagenomic analysis suggests the assimilatory sulfate reduction (ASR) pathway is a more significant contributor in the human gut, given its high prevalence and abundance. Subsequently, we validated our hypothesis experimentally by generating ASR-deficient E. coli mutants ∆cysJ and ∆cysM through the deletion of sulfite reductase and L-cysteine synthase genes. This alteration significantly affected bacterial sulfidogenic capacity, colon epithelial cell viability, and colonic mucin sulfation, ultimately leading to colitis in murine model. Further study revealed that gut microbiota degrade sulfopolysaccharides and assimilate sulfate to produce H ₂ S via the ASR pathway, highlighting the role of sulfopolysaccharides in colitis and cautioning against their use as food additives.
Conclusions: Our study significantly advances understanding of microbial sulfur metabolism in the human gut, elucidating the complex interplay between diet, gut microbiota, and host sulfur metabolism. We highlight the microbial ASR pathway as an overlooked endogenous H ₂ S producer and a potential therapeutic target for managing CD. Video Abstract.
(© 2024. The Author(s).)