Biagioli Michele, Di Giorgio Cristina, Massa Carmen, Marchianò Silvia, Bellini Rachele, Bordoni Martina, Urbani Ginevra, Roselli Rosalinda, Lachi Ginevra, Morretta Elva, Piaz Fabrizio Dal, Charlier Bruno, Fiorillo Bianca, Catalanotti Bruno, Cari Luigi, Nocentini Giuseppe, Ricci Patrizia, Distrutti Eleonora, Festa Carmen, Sepe Valentina, Zampella Angela, Monti Maria Chiara, Fiorucci Stefano
Department of Medicine and Surgery, University of Perugia, Perugia, Italy.
Bar Pharmaceuticals s.r.l., Via Gramsci 88/A, Reggio Emilia 42124, Italy.
Biomed Pharmacother. 2024 Dec;181:117731. doi: 10.1016/j.biopha.2024.117731. Epub 2024 Dec 9.
The interplay between the dysbiotic microbiota and bile acids is a critical determinant for development of a dysregulated immune system in inflammatory bowel disease (IBD). Here we have investigated the fecal bile acid metabolome, gut microbiota composition, and immune responses in IBD patients and murine models of colitis and found that IBD associates with an elevated excretion of primary bile acids while secondary, allo- and oxo- bile acids were reduced. These changes correlated with the disease severity, mucosal expression of pro-inflammatory cytokines and chemokines, and reduced inflow of anti-inflammatory macrophages and Treg in the gut. Analysis of bile acids metabolome in the feces allowed the identification of five bile acids: 3-oxo-DCA, 3-oxo-LCA, allo-LCA, iso-allo-LCA and 3-oxo-UDCA, whose excretion was selectively decreased in IBD patients and diseased mice. By transactivation assay and docking calculations all five bile acids were shown to act as GPBAR1 agonists and RORγt inverse agonists, skewing Th17/Treg ratio and macrophage polarization toward an M2 phenotype. In a murine model of colitis, administration of 3-oxo-DCA suffices to reverse colitis development and intestinal dysbiosis in a GPBAR1-dependent manner. In vivo administration of 3-oxo-DCA to colitic mice also reverses disease severity and RORγt activation induced by a RORγt agonist and IL-23, a Th17 inducing cytokine. These results demonstrated that intestinal excretion of 3-oxoDCA, a dual GPBAR1 agonist and RORγt inverse agonist, is reduced in IBD and in models of colitis and its restitution protects against colitis development, highlighting a potential role for this agent in IBD management.
失调的微生物群与胆汁酸之间的相互作用是炎症性肠病(IBD)中免疫系统失调发展的关键决定因素。在此,我们研究了IBD患者以及结肠炎小鼠模型的粪便胆汁酸代谢组、肠道微生物群组成和免疫反应,发现IBD与初级胆汁酸排泄增加相关,而次级、别构和氧代胆汁酸减少。这些变化与疾病严重程度、促炎细胞因子和趋化因子的黏膜表达以及肠道中抗炎巨噬细胞和调节性T细胞的流入减少相关。对粪便中胆汁酸代谢组的分析鉴定出五种胆汁酸:3-氧代脱氧胆酸(3-oxo-DCA)、3-氧代石胆酸(3-oxo-LCA)、别构石胆酸(allo-LCA)、异别构石胆酸(iso-allo-LCA)和3-氧代熊去氧胆酸(3-oxo-UDCA),它们在IBD患者和患病小鼠中的排泄选择性降低。通过反式激活分析和对接计算表明,所有这五种胆汁酸均作为G蛋白偶联胆汁酸受体1(GPBAR1)激动剂和维甲酸相关孤儿受体γt(RORγt)反向激动剂起作用,使辅助性T细胞17/调节性T细胞(Th17/Treg)比例和巨噬细胞极化偏向M2表型。在结肠炎小鼠模型中,给予3-氧代脱氧胆酸足以以依赖GPBAR1的方式逆转结肠炎发展和肠道生态失调。对结肠炎小鼠进行3-氧代脱氧胆酸的体内给药还可逆转由RORγt激动剂和白细胞介素23(IL-23,一种Th17诱导细胞因子)诱导的疾病严重程度和RORγt激活。这些结果表明,IBD和结肠炎模型中,作为双重GPBAR1激动剂和RORγt反向激动剂的3-氧代脱氧胆酸的肠道排泄减少,其恢复可预防结肠炎发展,突出了该药物在IBD治疗中的潜在作用。
