结肠炎
炎症性肠病
巨噬细胞
微生物学
重编程
纤维
体内
化学
离体
新陈代谢
炎症性肠病
生物
粪便
免疫学
肠道菌群
移植
免疫系统
外周血单个核细胞
膳食纤维
表型
炎症
食品科学
拉伤
免疫
炎症反应
微生物群
细胞生物学
机制(生物学)
疾病
作者
Seong-eun G. Kim,Rachael Ott,Alexis Bretin,Hirohito Abo,Yanling Wang,Yadong Wang,Shawn Winer,Daniel A. Winer,Lavanya Reddivari,Stacey L. Heaver,Ruth E. Ley,Michael Pellizzon,Vu L. Ngo,Andrew T. Gewirtz
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2026-03-25
卷期号:12 (13): eaec5757-eaec5757
标识
DOI:10.1126/sciadv.aec5757
摘要
's presence in gnotobiotic mice resulted in WF-induced fecal metabolites that reprogrammed macrophages toward an M2-like phenotype. Metabolic and phenotypic reprogramming of macrophages ex vivo via WF-induced metabolites, followed by their transplantation into mice, recapitulated WF's protection against colitis. Thus, microbiota-mediated metabolism of WF promotes macrophages that reduce proneness to intestinal inflammation, suggesting a mechanism by which WF consumption may curb development of IBD.
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