Phocaeicola coprophilus-Derived 6-Methyluracil Attenuates Radiation-Induced Intestinal Fibrosis by Suppressing the IDO1-Kynurenine-AHR Axis
Jiaxin Zhang, Zhen Wang, Shuang Li, Chao Luo, Han Li, Shengjie Ma, Pai Wang, Heshi Liu, Lijun Sun, Yue Yin, Weizhen Zhang, Quan Wang
Journal:Advanced Science
IF:14.1
DOI:10.1002/advs.202518502
PMID:41560360
Published:2026-01-20
research field:分子生物学细胞生理学进化遗传学微生物生态学转录组学比较基因组学
Abstract
Therapeutic options for radiation-induced intestinal fibrosis (RIF) remain limited. This study reveals that intestinal kynurenine (Kyn) is persistently elevated after radiation and correlates with fibrosis severity in both murine models and human rectal cancer samples. Exogenous Kyn exacerbated RIF, whereas inhibition of indoleamine 2,3-dioxygenase 1 (IDO1) attenuated fibrotic progression. Mechanistically, Kyn activates the aryl hydrocarbon receptor (AHR) to promote fibroblast activation and fibrosis. Antibiotic depletion of gut microbiota abrogates radiation-induced IDO1-Kyn upregulation and protects against RIF. Conversely, fecal microbiota transplantation from irradiated mice recapitulates the elevated IDO1-Kyn phenotype. Metagenomic analysis identify radiation-induced depletion of Phocaeicola coprophilus ( P. coprophilus ), whose abundance inversely correlates with Kyn levels. Supplementation with live P. coprophilus suppresses IDO1-Kyn signaling and ameliorates RIF. Untargeted metabolomics further show that radiation reduces 6-methyluracil, a metabolite derived from P. coprophilus . Exogenous 6-methyluracil replenishment inhibits repression of the IDO1-Kyn axis and mitigates fibrosis. Together, these findings define a microbiota–metabolite–host pathway in which radiation depletes P. coprophilus , leading to loss of 6-methyluracil and derepression of the IDO1-Kyn-AHR axis, thereby driving fibrogenesis. Restoration of either P. coprophilus or its metabolite 6-methyluracil represents a promising therapeutic strategy against RIF.
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