The RhoB p.S73F mutation leads to cerebral palsy through dysregulation of lipid homeostasis.

IF 9 1区医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL EMBO Molecular Medicine Pub Date : 2024-09-01 Epub Date: 2024-07-30 DOI:10.1038/s44321-024-00113-2

Xinyu Wu, Ruonan Liu, Zhongtian Zhang, Jie Yang, Xin Liu, Liqiang Jiang, Mengmeng Fang, Shoutang Wang, Liangxue Lai, Yuning Song, Zhanjun Li

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Abstract

Cerebral palsy (CP) is a prevalent neurological disorder that imposes a significant burden on children, families, and society worldwide. Recently, the RhoB p.S73F mutation was identified as a de novo mutation associated with CP. However, the mechanism by which the RhoB p.S73F mutation causes CP is currently unclear. In this study, rabbit models were generated to mimic the human RhoB p.S73F mutation using the SpG-BE4max system, and exhibited the typical symptoms of human CP, such as periventricular leukomalacia and spastic-dystonic diplegia. Further investigation revealed that the RhoB p.S73F mutation could activate ACAT1 through the LYN pathway, and the subsequently altered lipid levels may lead to neuronal and white matter damage resulting in the development of CP. This study presented the first mammalian model of genetic CP that accurately replicates the RhoB p.S73F mutation in humans, provided further insights between RhoB and lipid metabolism, and novel therapeutic targets for human CP.

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RhoB p.S73F突变通过脂质平衡失调导致脑瘫。

脑性瘫痪（CP）是一种常见的神经系统疾病，给全世界的儿童、家庭和社会带来了沉重的负担。最近，RhoB p.S73F突变被确定为与CP相关的新突变。然而，RhoB p.S73F突变导致CP的机制目前尚不清楚。本研究利用 SpG-BE4max 系统生成了模拟人类 RhoB p.S73F 突变的家兔模型，该模型表现出人类 CP 的典型症状，如脑室周围白斑和痉挛性肌张力障碍性截瘫。进一步研究发现，RhoB p.S73F突变可通过LYN途径激活ACAT1，随后脂质水平的改变可能导致神经元和白质损伤，从而导致CP的发生。这项研究首次提出了准确复制人类 RhoB p.S73F 突变的遗传性 CP 哺乳动物模型，进一步揭示了 RhoB 与脂质代谢之间的关系，并提出了人类 CP 的新治疗靶点。

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来源期刊

EMBO Molecular Medicine 医学-医学：研究与实验

CiteScore

17.70

自引率

0.90%

发文量

105

审稿时长

4-8 weeks

期刊介绍： EMBO Molecular Medicine is an open access journal in the field of experimental medicine, dedicated to science at the interface between clinical research and basic life sciences. In addition to human data, we welcome original studies performed in cells and/or animals provided they demonstrate human disease relevance. To enhance and better specify our commitment to precision medicine, we have expanded the scope of EMM and call for contributions in the following fields: Environmental health and medicine, in particular studies in the field of environmental medicine in its functional and mechanistic aspects (exposome studies, toxicology, biomarkers, modeling, and intervention). Clinical studies and case reports - Human clinical studies providing decisive clues how to control a given disease (epidemiological, pathophysiological, therapeutic, and vaccine studies). Case reports supporting hypothesis-driven research on the disease. Biomedical technologies - Studies that present innovative materials, tools, devices, and technologies with direct translational potential and applicability (imaging technologies, drug delivery systems, tissue engineering, and AI)