Multi-omics analysis identifies a microbiota-bile acid-TLR signaling axis driving bladder injury in interstitial cystitis.

Hunner-type interstitial cystitis/bladder pain syndrome (HIC) is a debilitating condition defined by bladder pain and urinary urgency, yet its upstream drivers remain poorly understood. To identify upstream mechanisms that exacerbate urothelial injury, here we apply an integrative multi-omics framework combining metagenomic sequencing, targeted metabolomics of urine and serum, and single-cell RNA sequencing. This approach reveals a microbial signature enriched in Enterococcus avium and a marked alteration in bile acid metabolism, including increased taurochenodeoxycholic acid (TCDCA). Single-cell analysis indicates that these changes converge on Toll-like receptor 3 (TLR3) activation in urothelial cells. Further validations show that a microbiota-bile acid-TLR3 axis disrupts epithelial barrier integrity and triggers inflammatory responses in experimental models. Transplantation and metabolite administration confirm the causal role of E. avium and TCDCA, while TLR3 inhibition ameliorates injury. These findings uncover an upstream pathway linking gut-derived metabolites to bladder pathology and suggest opportunities for biomarker development and targeted therapies for HIC.