ELAVL1-mediated USP29 mRNA degradation activates TAK1 driving M1 microglial polarization and neural stem cell differentiation dysregulation in spinal cord injury.

IF 6.1 2区生物学 Q1 CELL BIOLOGY

Cell Death Discovery Pub Date : 2025-07-09 DOI:10.1038/s41420-025-02604-8

Chunhe Sha, Feng Pan, Xiaodong Liu, Zhiqing Wang, Guohui Liu, Kai Huang

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Abstract

Spinal cord injury (SCI) represents a profound neurological condition characterized by motor dysfunction and sensory impairment. Microglial polarization significantly influences neurorepair and regeneration post SCI. This study aims to investigate the regulatory role of the ELAV-like RNA binding protein 1 (ELAVL1)-ubiquitin-specific peptidase 29 (USP29)-transforming growth factor beta-activated kinase 1 (TAK1) axis in microglial polarization and its effects on differentiation of neural stem cells (NSCs). A rat model of SCI was established via spinal cord transection at the tenth thoracic vertebra segment, followed by short hairpin RNA (shRNA) lentivirus infection. Motor function and coordination were evaluated while histopathological analysis of spinal cord tissues was conducted. Microglial polarization and NSC differentiation were assessed via immunofluorescence and Western blot analysis. In cellular experiments, lipopolysaccharide (LPS) was utilized to induce M1 polarization in HMC3 cells, with polarization status determined by flow cytometry, immunofluorescence, and WB. Co-immunoprecipitation, GST pull-down, and ubiquitination assays elucidated USP29 effects on TAK1 ubiquitination and activation. In SCI rat spinal cord tissues and LPS-treated HMC3 cells, we observed upregulation of ELAVL1 and phosphorylated level of TAK1, while USP29 expression was downregulated. ELAVL1 was found to bind USP29 mRNA, promoting its degradation and suppressing USP29 expression. USP29 directly interacted with TAK1, inhibiting its ubiquitination and phosphorylation. Knockdown of ELAVL1 significantly enhanced USP29 mRNA stability, inhibited TAK1 activation, promoted M2 microglial polarization, and suppressed M1 polarization. In vivo downregulation of ELAVL1 promoted the differentiation of NSCs into neurons by inhibiting M1 polarization and promoting M2 polarization, thereby improving motor function, alleviating nerve injury, and facilitating spinal cord repair. ELAVL1 exacerbates SCI pathology by degrading USP29 mRNA, thereby activating TAK1 and driving M1 microglial polarization. Targeting the ELAVL1-USP29-TAK1 axis may offer therapeutic potential for enhancing neurorepair in SCI. Schematic diagram of the ELAVL1-USP29-TAK1 axis mediating M1 microglial polarization and NSC differentiation dysregulation exacerbating SCI.

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elavl1介导的USP29 mRNA降解激活TAK1驱动M1小胶质细胞极化和脊髓损伤中神经干细胞分化失调。

脊髓损伤是一种以运动功能障碍和感觉障碍为特征的严重神经系统疾病。小胶质细胞极化对脊髓损伤后神经修复和再生有显著影响。本研究旨在探讨elav样RNA结合蛋白1 (ELAVL1)-泛素特异性肽酶29 (USP29)-转化生长因子β活化激酶1 （TAK1）轴在小胶质细胞极化中的调控作用及其对神经干细胞（NSCs）分化的影响。通过横断第10胸椎段脊髓，用短发夹RNA （shRNA）慢病毒感染建立脊髓损伤大鼠模型。评估运动功能和协调性，同时对脊髓组织进行组织病理学分析。免疫荧光和Western blot分析小胶质细胞极化和NSC分化。在细胞实验中，利用脂多糖（LPS）诱导HMC3细胞M1极化，通过流式细胞术、免疫荧光和WB检测极化状态。共免疫沉淀、GST下拉和泛素化分析阐明了USP29对TAK1泛素化和激活的影响。在脊髓损伤大鼠脊髓组织和lps处理的HMC3细胞中，我们观察到ELAVL1和TAK1磷酸化水平上调，而USP29表达下调。发现ELAVL1结合USP29 mRNA，促进其降解并抑制USP29的表达。USP29直接与TAK1相互作用，抑制其泛素化和磷酸化。敲低ELAVL1显著增强USP29 mRNA稳定性，抑制TAK1激活，促进M2小胶质细胞极化，抑制M1极化。体内下调ELAVL1通过抑制M1极化和促进M2极化，促进NSCs向神经元分化，从而改善运动功能，减轻神经损伤，促进脊髓修复。ELAVL1通过降解USP29 mRNA，从而激活TAK1并驱动M1小胶质细胞极化，从而加剧SCI病理。靶向ELAVL1-USP29-TAK1轴可能为增强脊髓损伤的神经修复提供治疗潜力。ELAVL1-USP29-TAK1轴介导M1小胶质细胞极化和NSC分化失调加重脊髓损伤的示意图。

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来源期刊

Cell Death Discovery Biochemistry, Genetics and Molecular Biology-Cell Biology

CiteScore

8.30

自引率

1.40%

发文量

468

审稿时长

9 weeks

期刊介绍： Cell Death Discovery is a multidisciplinary, international, online-only, open access journal, dedicated to publishing research at the intersection of medicine with biochemistry, pharmacology, immunology, cell biology and cell death, provided it is scientifically sound. The unrestricted access to research findings in Cell Death Discovery will foster a dynamic and highly productive dialogue between basic scientists and clinicians, as well as researchers in industry with a focus on cancer, neurobiology and inflammation research. As an official journal of the Cell Death Differentiation Association (ADMC), Cell Death Discovery will build upon the success of Cell Death & Differentiation and Cell Death & Disease in publishing important peer-reviewed original research, timely reviews and editorial commentary. Cell Death Discovery is committed to increasing the reproducibility of research. To this end, in conjunction with its sister journals Cell Death & Differentiation and Cell Death & Disease, Cell Death Discovery provides a unique forum for scientists as well as clinicians and members of the pharmaceutical and biotechnical industry. It is committed to the rapid publication of high quality original papers that relate to these subjects, together with topical, usually solicited, reviews, editorial correspondence and occasional commentaries on controversial and scientifically informative issues.