CIDEB中的体细胞功能丧失突变通过增加脂肪分解和脂肪酸氧化来减轻肝脂肪变性。

Somatic loss-of-function mutations in CIDEB reduce hepatic steatosis by increasing lipolysis and fatty acid oxidation.

作者信息

Zeng Qiyu, Patel Satish, Wang Xun, Hsieh Meng-Hsiung, Li Zhijie, Ren Xiongzhao, Wang Jingjing, Kim Dohun, Li Shili, Gu Xinping, Mannino Greg, Maggiore Gianna, Fang Xiangyi, Li Lin, Zhu Min, Wang Mengmeng, Li Boyuan, Bellary Amaey, Lim Koini, Qi Zhetuo, Pushpa Pushpa, Mandour Mandour Omer, Saudek Vladimir, Sharma Tripti, Zhang Yu, Hoxhaj Gerta, Mishra Prashant, Gopal Purva, Campbell Peter, Hoare Matthew, Savage David B, Zhu Hao

机构信息

Children's Research Institute, Departments of Pediatrics and Internal Medicine, Center for Regenerative Science and Medicine, Children's Research Institute Mouse Genome Engineering Core, University of Texas Southwestern Medical Center, Dallas, TX 75390, USA.

University of Cambridge Metabolic Research Laboratories, Wellcome Trust-MRC Institute of Metabolic Science, Cambridge, CB2 0QQ, UK.

出版信息

J Hepatol. 2025 Jul 4. doi: 10.1016/j.jhep.2025.06.021.

DOI:10.1016/j.jhep.2025.06.021

PMID:40618957

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12313214/

Abstract

BACKGROUND & AIMS: Somatic and germline CIDEB mutations are associated with protection from chronic liver diseases. The mechanistic basis and whether CIDEB suppression would be an effective therapy against fatty liver disease remain unclear.

METHODS

21 CIDEB somatic mutations were introduced into cells to assess functionality. In vivo screening was used to trace Cideb mutant clones in mice fed normal chow, western (WD), and choline-deficient, L-amino acid-defined, high-fat (CDA-HFD) diets. Constitutive and conditional Cideb knockout mice were generated to study Cideb in liver disease. Isotope tracing was used to evaluate fatty acid oxidation and de novo lipogenesis. Transcriptomics, lipidomics, and metabolic analyses were utilized to explore molecular mechanisms. Double knockout models (Cideb/Atgl and Cideb/Pparα) tested mechanisms underlying Cideb loss.

RESULTS

Most CIDEB mutations showed that they impair function, and lineage-tracing showed that loss-of-function clones were positively selected with CDA-HFD, but not all fatty liver inducing diets. Cideb KO mice were protected from WD, CDA-HFD, and alcohol diets, but had the greatest impact on CDA-HFD induced liver disease. Hepatocyte-specific Cideb deletion could ameliorate disease after metabolic dysfunction-associated steatotic liver disease (MASLD) establishment, modeling the impact of therapeutic siRNAs. Cideb loss protected livers via increased β-oxidation, specifically through ATGL and PPARα activation.

CONCLUSIONS

Cideb deletion is more protective in some types of fatty liver disease. β-oxidation is an important component of the Cideb protective mechanism. CIDEB inhibition represents a promising approach, and somatic mutations in CIDEB might predict the patient populations that might benefit the most.

IMPACT AND IMPLICATIONS

It is not clear why somatic and germline CIDEB mutations are protective in MASLD. Cideb mutations are predominantly loss of function, and Cideb-deficient clones selectively expand in specific dietary contexts such as CDA-HFD-induced MASLD. Consistently, liver-wide deletion of Cideb ameliorates MASLD most profoundly after CDA-HFD feeding. Mechanistically, Cideb deficiency enhances hepatic fatty acid β-oxidation via ATGL and PPARα activation. These findings suggest that CIDEB inhibition might be most effective in patients with the subtypes of MASLD that promote the expansion of CIDEB mutant clones.

摘要

背景与目的

体细胞和生殖系CIDEB突变与预防慢性肝病有关。其机制基础以及CIDEB抑制是否会成为治疗脂肪肝疾病的有效疗法仍不清楚。

方法

将21种CIDEB体细胞突变引入细胞以评估其功能。体内筛选用于追踪喂食正常饲料、西式（WD）和胆碱缺乏、L-氨基酸定义的高脂（CDA-HFD）饮食的小鼠中的Cideb突变克隆。构建组成型和条件性Cideb基因敲除小鼠以研究肝病中的Cideb。采用同位素示踪法评估脂肪酸氧化和从头脂肪生成。利用转录组学、脂质组学和代谢分析来探索分子机制。双敲除模型（Cideb/Atgl和Cideb/Pparα）测试Cideb缺失的潜在机制。

结果

大多数CIDEB突变显示它们损害功能，谱系追踪表明功能丧失的克隆在CDA-HFD饮食中被阳性选择，但并非所有诱导脂肪肝的饮食都是如此。Cideb基因敲除小鼠对WD、CDA-HFD和酒精饮食具有抗性，但对CDA-HFD诱导的肝病影响最大。肝细胞特异性Cideb缺失可在代谢功能障碍相关脂肪性肝病（MASLD）形成后改善疾病，模拟治疗性小干扰RNA的影响。Cideb缺失通过增加β-氧化来保护肝脏，特别是通过激活ATGL和PPARα。

结论

Cideb缺失在某些类型的脂肪肝疾病中具有更强的保护作用。β-氧化是Cideb保护机制的重要组成部分。抑制CIDEB是一种有前景的方法，CIDEB中的体细胞突变可能预测最可能受益的患者群体。

影响与意义

尚不清楚为什么体细胞和生殖系CIDEB突变在MASLD中具有保护作用。Cideb突变主要是功能丧失，并且Cideb缺陷克隆在特定饮食环境中选择性扩增，如CDA-HFD诱导的MASLD。一致地，在CDA-HFD喂养后，肝脏全范围缺失Cideb对MASLD的改善最为显著。从机制上讲，Cideb缺乏通过激活ATGL和PPARα增强肝脏脂肪酸β-氧化。这些发现表明，抑制CIDEB可能对促进CIDEB突变克隆扩增的MASLD亚型患者最有效。