小岛
生物
免疫系统
细胞生物学
平衡
胰腺
葡萄糖稳态
氧化磷酸化
氧化应激
抗氧化剂
细胞
代谢途径
表型
胰岛素
新陈代谢
巨噬细胞
肠内分泌细胞
线粒体
活性氧
炎症
生物化学
胰岛
内分泌系统
细胞代谢
肉碱
碳水化合物代谢
电池类型
免疫学
转录组
氧化代谢
核糖核酸
先天免疫系统
化学
作者
Amélie Grosjean,Aude Jalon,Claire Leveau,Marc Diedisheim,David Alejandro Bejarano,Joyceline Cuenco,Kevin Mulder,Zhaoyuan Liu,Audrey Le Guernic,Marie-Laure Island,Jarne Walkiers,Gamze Ates,Clément Materne,Andréia Gonçalves,Ivan Nemazanyy,Laura G. Baudrin,Sylvain Baulande,Martine Ropert,Jean-François Gautier,Ahmed Hamaï
出处
期刊:Science immunology
[American Association for the Advancement of Science]
日期:2025-11-14
卷期号:10 (113): eadz5181-eadz5181
标识
DOI:10.1126/sciimmunol.adz5181
摘要
Pancreatic islet-resident macrophages (IRMs) display an activated phenotype and contribute to islet development and remodeling, yet their origin, heterogeneity, and functional roles remain poorly understood. Using complementary fate-mapping systems, we show that, in adult mice, around half of IRMs originate from circulating monocytes and undergo minimal turnover. Integrated multiple single-cell RNA sequencing analyses of mouse and human islets identified four major IRM cell states that collectively reveal their inflammatory and metabolic activation. Among these, a transcriptional program driven by the cystine-glutamate antiporter SLC7A11 and enriched in CD9 high IRMs was associated with enhanced antioxidant defense, mitochondrial activity, and iron-lipid metabolic pathways. We found that Slc7a11 -expressing IRMs preserve β cell redox homeostasis and insulin secretion, both at baseline and under stress. These findings position IRMs as specialized immune sentinels in the endocrine pancreas and identify SLC7A11 as a key macrophage-intrinsic safeguard against oxidative stress, with broad implications for islet resilience and metabolic health.
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