首页|期刊导航|陆军军医大学学报|NUPR1下调介导巨噬细胞氧化磷酸化损伤参与溃疡性结肠炎发病

NUPR1下调介导巨噬细胞氧化磷酸化损伤参与溃疡性结肠炎发病OA

NUPR1 downregulation-mediated impairment of macrophage oxidative phosphorylation participates in the pathogenesis of ulcerative colitis

中文摘要英文摘要

目的 巨噬细胞是参与溃疡性结肠炎(ulcerative colitis,UC)发生发展的关键细胞类型,其功能水平与氧化磷酸化(oxidative phosphorylation,OXPHOS)能力息息相关,但UC患者的巨噬细胞OXPHOS水平变化尚不明确.本研究旨在评估UC患者结肠组织中巨噬细胞OXPHOS水平,识别并验证关键调控基因.方法 整合5个UC队列结肠单细胞RNA测序数据集,共计纳入54例样本,其中18例健康对照(healthy control,HC),36例UC患者,聚类与细胞注释后,主要针对单核细胞及巨噬细胞亚群进行分析.5种基因集评分算法(AUCell、UCell、singscore、ssGSEA和JASMINE)获取两类细胞OXPHOS水平得分.秩聚合(robust rank aggregation,RRA)分别评估HC与UC之间2类细胞OXPHOS得分差异.枢纽基因分析结果与差异分析结果交集获得潜在关键调控基因.采用随机数字表法将C57BL/6N雄性小鼠[10~12周龄;体质量:(25±2)g]随机分为葡聚糖硫酸钠(dextran sulfate sodium salt,DSS)诱导的急性结肠炎组(n=6)和对照组(CTR组,n=8),利用免疫荧光染色检测结肠巨噬细胞的核蛋白转录因子1(nuclear protein 1,transcriptional regulator,NUPR1)表达水平.siRNA 干扰小鼠原代骨髓巨噬细胞(bone marrow-derived macrophages,BMDMs)Nupr1 表达后,检测 BMDMs 中 ATP含量的改变.拟时序分析及虚拟敲除技术进行潜在机制探索.结果 相较于HC组,UC组中髓系细胞比例升高,单核细胞增加而巨噬细胞减少;巨噬细胞OXPHOS通路评分显著降低(P<0.05),而单核细胞无明显变化.筛选出OXPHOS枢纽(hub)基因19个(P<0.05),与巨噬细胞差异基因取交集得到关键基因NUPR1,NUPR1在UC患者(adj.P<0.001)和DSS结肠炎小鼠结肠的巨噬细胞中显著下调(P<0.001).siRNA敲减BMDMs的Nupr1(P<0.05)后,BMDMs的TOM20荧光强度下降(P<0.001).BMDMs 的 ATP含量在Nupr1敲减(P<0.01)以及LPS刺激后(P<0.001)显著下降,Nupr1敲减与LPS刺激联合处理相较于Nupr1敲减(P<0.01)或LPS刺激(P<0.05)单独作用效果更强.拟时序分析显示,NUPR1随着伪时间推移表达逐渐下降,与常见炎症相关基因(IL1B,CD83)表达趋势一致.虚拟敲除NUPR1后,ATP代谢及线粒体调控相关通路受到显著干扰(P<0.05).结论 UC患者结肠巨噬细胞存在显著的OXPHOS功能下降,NUPR1是与该过程密切相关的关键调控基因,其下调可能通过影响线粒体功能和ATP代谢损害巨噬细胞OXPHOS能力,为UC的能量代谢调控干预提供了潜在靶点及依据.

Objective Macrophages are key cellular contributors to the development and progression of ulcerative colitis(UC),and their functional state is closely related to oxidative phosphorylation(OXPHOS)capacity.However,changes in macrophage OXPHOS levels in UC patients remain unclear.This study aims to evaluate macrophage OXPHOS capacity in colonic tissues of UC patients and to identify and validate key regulatory genes.Methods Five colonic scRNA-seq datasets from UC cohorts were integrated,comprising 54 samples in total,including 18 healthy controls(HC)and 36 UC cases.After clustering and cell annotation,analyses were focused mainly on monocyte and macrophage subsets.Five gene set scoring algorithms,including AUCell,UCell,singscore,ssGSEA,and JASMINE,were used to calculate OXPHOS scores in these 2 cell types.Robust rank aggregation(RRA)was employed to compare the OXPHOS scores of monocyte and macrophage subsets between HC and UC cells.Candidate regulatory genes were identified by intersecting hub genes with differentially expressed genes(DEGs).Male C57BL/6N mice(10 to 12 weeks old,weighing 25±2 g)were randomly assigned to a DSS-induced acute colitis group(n=6)or a CTR group(n=8).Immunofluorescence assay was utilized to detect nuclear protein 1,transcriptional regulator(NUPR1)expression in colonic macrophages.After siRNA-mediated knockdown of Nupr1 in mouse primary bone marrow-derived macrophages(BMDMs),the ATP levels were measured.Pseudotime analysis and virtual knockout were further performed to explore potential mechanisms.Results Compared with the HC group,the UC group exhibited an increased proportion of myeloid cells,with an increase in monocytes and a decrease in macrophages.OXPHOS pathway scores were significantly reduced in macrophages(P<0.05),whereas no obvious change was observed in monocytes.Nineteen OXPHOS hub genes were identified(P<0.05),and intersection with macrophage DEGs yielded NUPR1 as a key candidate gene.NUPR1 was significantly downregulated in macrophages from UC patients(adj.P<0.001)and in colonic macrophages from DSS-induced colitis mice.After siRNA-mediated knockdown of Nupr1 in BMDMs(P<0.05),the fluorescence intensity of TOM20 was decreased(P<0.001).ATP levels in BMDMs were significantly reduced after Nupr1 knockdown(P<0.01)and LPS stimulation(P<0.001),and the combined treatment had a stronger effect than either Nupr1 knockdown(P<0.01)or LPS stimulation alone(P<0.05).Pseudotime analysis showed that NUPR1 expression was gradually decreased with pseudotime,consistent with the expression trends of common inflammation-related genes IL1B and CD83.After virtual knockout of NUPR1,ATP metabolism and mitochondrial-related pathways were significantly perturbed(P<0.05).Conclusion Colonic macrophages from UC patients exhibit a marked decline in OXPHOS function.NUPR1 is a key regulatory gene closely associated with this process,and its downregulation may impair macrophage OXPHOS capacity by affecting mitochondrial function and ATP metabolism.These findings provide a potential target and rationale interventions for regulating energy metabolism in UC.

余思睿;何佳利;巫明月;柴进

陆军军医大学(第三军医大学)第一附属医院消化内科,全军消化病研究所胆汁淤积肝病中心,代谢相关脂肪性肝病中心,重庆陆军军医大学(第三军医大学)第一附属医院消化内科,全军消化病研究所胆汁淤积肝病中心,代谢相关脂肪性肝病中心,重庆陆军军医大学(第三军医大学)第一附属医院消化内科,全军消化病研究所胆汁淤积肝病中心,代谢相关脂肪性肝病中心,重庆陆军军医大学(第三军医大学)第一附属医院消化内科,全军消化病研究所胆汁淤积肝病中心,代谢相关脂肪性肝病中心,重庆

医药卫生

溃疡性结肠炎巨噬细胞氧化磷酸化核蛋白转录因子1

ulcerative colitismacrophagesoxidative phosphorylationnuclear protein 1,transcriptional regulator

《陆军军医大学学报》 2026 (11)

1505-1517,13

四大慢病重大专项(2026ZD0557000)国家自然科学基金面上项目(82570651)重庆西南医院优青拔尖项目(2025YQBJ-5)重庆自然科学基金面上项目(CSTB2023NSCQ-MSQ0657) Supported by the Noncommunicable Chronic Diseases-National Science and Technology Major Project(2026ZD0557000),the General Program of National Natural Science Foundation of China(82570651),the Outstanding Young Scholar Project of Southwest Hospital(2025YQBJ-5),and the General Project of National Natural Science Foundation of Chongqing(CSTB2023NSCQ-MSQ0657).

10.16016/j.2097-0927.202602104

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