Gain-of-function PPM1D mutations attenuate ischemic stroke

IF 13.7 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Cell Death and Differentiation Pub Date : 2025-05-21 DOI:10.1038/s41418-025-01523-6

Wenyan He, Yan Li, Junwan Fan, Yang Liu, Meng Yuan, Si Cheng, Xinying Huang, Bo Yan, Zhuoran Zhang, Yuwen Xiu, Huimin Zhu, Tian Lan, Zhilin Chang, Yong Jiang, Hao Li, Xia Meng, Yilong Wang, Luc Van Kaer, Alexei Verkhratsky, Yongjun Wang, Fu-Dong Shi, Wei-Na Jin

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Abstract

Identification of genetic aberrations in stroke, the second leading cause of death worldwide, is of paramount importance for understanding the disease pathogenesis and generating new therapies. Whole-genome sequencing from 10,241 ischemic stroke patients identified eight patients carrying gain-of-function mutations on coding variants in the protein phosphatase magnesium-dependent 1 δ (PPM1D) gene. Patients carrying PPM1D mutations exhibit better stroke-related clinical phenotypes, including improvements in peripheral inflammation, fibrinogen, low-density lipoprotein, cholesterol and plateletcrit level. Experimental brain ischemia in Ppm1d-deficient (Ppm1d⁻^/⁻) mice resulted in enlarged lesions and pronounced neurological impairments. Spatial transcriptomics revealed a distinct Ppm1d-associated gene expression pattern, indicating disrupted endothelial homeostasis during ischemic brain injury. Proteomic analysis demonstrated that differentially expressed proteins in primary brain endothelial cells from Ppm1d⁻^/⁻ mice were significantly enriched in the peroxisome proliferator-activated receptors (PPARs)-mediated metabolic signaling. Mechanistically, Ppm1d deficiency promoted aberrant fatty acid β-oxidation and increased oxidative stress, which impaired endothelial cell function through the PPARα pathway. A small molecule, T2755, was identified to engage Trp427 and stabilize PPM1D, thereby mitigating ischemic brain injury in mice. Collectively, we find that PPM1D protects against ischemic brain injury and validates its pharmacological stabilizer T2755 as a promising therapy for ischemic stroke.

Gain-of-function PPM1D mutations attenuate ischemic cerebral injury. Whole-genome sequencing data of 10,241 ischemic stroke patients from the Third Chinese National Stroke Registry (CNSR-III) identified eight patients with gain-of-function mutations in the protein phosphatase magnesium-dependent 1 δ (PPM1D) gene (17q23.2). These mutation carriers displayed improved peripheral inflammation, decreased fibrinogen, low-density lipoprotein, cholesterol and plateletcrit level. Ppm1d-deficient (Ppm1d⁻^/⁻) mice exhibited exacerbated stroke outcomes, characterized by enlarged infarct volumes, disrupted cerebrovascular architecture, and enhanced neuro-inflammation. Mechanistically, Ppm1d deficiency induced the disturbance of endothelial fatty acid metabolism involving the PPARα pathway. Through integrated computational modeling, virtual screening, and in vitro validation, T2755 was identified as a small molecule PPM1D stabilizer. Pharmacological PPM1D stabilization with T2755 significantly attenuated ischemic brain injury in murine models.

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功能获得的PPM1D突变可减弱缺血性卒中

中风是全球第二大死亡原因，识别中风的遗传异常对于了解疾病发病机制和产生新的治疗方法至关重要。对10,241例缺血性卒中患者进行全基因组测序，发现8例患者携带蛋白磷酸酶镁依赖性1 δ (PPM1D)基因编码变异的功能获得突变。携带PPM1D突变的患者表现出更好的卒中相关临床表型，包括外周炎症、纤维蛋白原、低密度脂蛋白、胆固醇和血小板水平的改善。Ppm1d缺陷小鼠（Ppm1d−/−）的实验性脑缺血导致病变扩大和明显的神经损伤。空间转录组学揭示了不同的ppm1d相关基因表达模式，表明缺血性脑损伤期间内皮稳态被破坏。蛋白质组学分析表明，Ppm1d−/−小鼠原代脑内皮细胞中的差异表达蛋白在过氧化物酶体增殖激活受体（PPARs）介导的代谢信号中显著富集。从机制上讲，Ppm1d缺乏促进脂肪酸β-氧化异常和氧化应激增加，从而通过PPARα途径损害内皮细胞功能。一种名为T2755的小分子被发现与Trp427结合，稳定PPM1D，从而减轻小鼠缺血性脑损伤。总之，我们发现PPM1D对缺血性脑损伤具有保护作用，并验证了其药理稳定剂T2755作为缺血性脑卒中的一种有希望的治疗方法。功能获得的PPM1D突变可减轻缺血性脑损伤。来自第三个中国国家卒中登记处（CNSR-III）的10,241例缺血性卒中患者的全基因组测序数据发现，8例患者在蛋白磷酸酶镁依赖性1 δ (PPM1D)基因（17q23.2）中存在功能获得性突变。这些突变携带者表现出外周炎症改善，纤维蛋白原、低密度脂蛋白、胆固醇和血小板水平降低。Ppm1d缺陷（Ppm1d−/−）小鼠中风结果加重，表现为梗死面积增大、脑血管结构破坏和神经炎症增强。机制上，Ppm1d缺乏诱导内皮脂肪酸代谢紊乱，涉及PPARα途径。通过综合计算建模、虚拟筛选和体外验证，T2755被确定为小分子PPM1D稳定剂。用T2755稳定PPM1D可显著减轻小鼠缺血性脑损伤模型。

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来源期刊

Cell Death and Differentiation 生物-生化与分子生物学

CiteScore

24.70

自引率

1.60%

发文量

181

审稿时长

3 months

期刊介绍： Mission, vision and values of Cell Death & Differentiation: To devote itself to scientific excellence in the field of cell biology, molecular biology, and biochemistry of cell death and disease. To provide a unified forum for scientists and clinical researchers It is committed to the rapid publication of high quality original papers relating to these subjects, together with topical, usually solicited, reviews, meeting reports, editorial correspondence and occasional commentaries on controversial and scientifically informative issues.