Molecular switch of the dendrite-to-spine transport of TDP-43/FMRP-bound neuronal mRNAs and its impairment in ASD.

IF 9.2 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Cellular & Molecular Biology Letters Pub Date : 2025-01-15 DOI:10.1186/s11658-024-00684-5

Pritha Majumder, Biswanath Chatterjee, Khadiza Akter, Asmar Ahsan, Su Jie Tan, Chi-Chen Huang, Jen-Fei Chu, Che-Kun James Shen

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Abstract

Background: Regulation of messenger RNA (mRNA) transport and translation in neurons is essential for dendritic plasticity and learning/memory development. The trafficking of mRNAs along the hippocampal neuron dendrites remains translationally silent until they are selectively transported into the spines upon glutamate-induced receptor activation. However, the molecular mechanism(s) behind the spine entry of dendritic mRNAs under metabotropic glutamate receptor (mGluR)-mediated neuroactivation and long-term depression (LTD) as well as the fate of these mRNAs inside the spines are still elusive.

Method: Different molecular and imaging techniques, e.g., immunoprecipitation (IP), RNA-IP, Immunofluorescence (IF)/fluorescence in situ hybridization (FISH), live cell imaging, live cell tracking of RNA using beacon, and mouse model study are used to elucidate a novel mechanism regulating dendritic spine transport of mRNAs in mammalian neurons.

Results: We demonstrate here that brief mGluR1 activation-mediated dephosphorylation of pFMRP (S499) results in the dissociation of FMRP from TDP-43 and handover of TDP-43/Rac1 mRNA complex from the dendritic transport track on microtubules to myosin V track on the spine actin filaments. Rac1 mRNA thus enters the spines for translational reactivation and increases the mature spine density. In contrast, during mGluR1-mediated neuronal LTD, FMRP (S499) remains phosphorylated and the TDP-43/Rac1 mRNA complex, being associated with kinesin 1-FMRP/cortactin/drebrin, enters the spines owing to Ca²⁺-dependent microtubule invasion into spines, but without translational reactivation. In a VPA-ASD mouse model, this regulation become anomalous.

Conclusions: This study, for the first time, highlights the importance of posttranslational modification of RBPs, such as the neurodevelopmental disease-related protein FMRP, as the molecular switch regulating the dendrite-to-spine transport of specific mRNAs under mGluR1-mediated neurotransmissions. The misregulation of this switch could contribute to the pathogenesis of FMRP-related neurodisorders including the autism spectrum disorder (ASD). It also could indicate a molecular connection between ASD and neurodegenerative disease-related protein TDP-43 and opens up a new perspective of research to elucidate TDP-43 proteinopathy among patients with ASD.

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TDP-43/ fmrp结合的神经元mrna在ASD中树突到脊柱运输的分子开关及其损伤。

背景：神经元中信使RNA （mRNA）转运和翻译的调控对树突可塑性和学习/记忆发育至关重要。沿着海马神经元树突的mrna运输保持翻译沉默，直到它们被谷氨酸诱导的受体激活选择性地转运到棘中。然而，在代谢性谷氨酸受体（mGluR）介导的神经激活和长期抑制（LTD）下，树突状mrna进入脊柱的分子机制以及这些mrna在脊柱内的命运仍然是未知的。方法：利用不同的分子和成像技术，如免疫沉淀（IP）、RNA-IP、免疫荧光(IF)/荧光原位杂交（FISH）、活细胞成像、信标RNA活细胞跟踪和小鼠模型研究，阐明哺乳动物神经元树突棘转运mrna的新机制。结果：我们在这里证明，mGluR1激活介导的pFMRP （S499）的短暂去磷酸化导致FMRP与TDP-43分离，并将TDP-43/Rac1 mRNA复合物从微管上的树突运输轨道转移到脊柱肌动蛋白丝上的肌凝蛋白V轨道。因此，Rac1 mRNA进入脊柱进行翻译再激活，增加成熟脊柱密度。相比之下，在mglur1介导的神经元LTD中，FMRP （S499）保持磷酸化，TDP-43/Rac1 mRNA复合物与激酶1-FMRP/皮质蛋白/drebrin相关，由于Ca2+依赖性微管侵入脊柱而进入脊柱，但没有翻译再激活。在VPA-ASD小鼠模型中，这种调节变得异常。结论：本研究首次强调了rbp翻译后修饰的重要性，如神经发育疾病相关蛋白FMRP，在mglur1介导的神经传递中，rbp作为调节特定mrna从树突到脊柱运输的分子开关。这种开关的错误调节可能导致fmrp相关神经疾病的发病机制，包括自闭症谱系障碍（ASD）。提示ASD与神经退行性疾病相关蛋白TDP-43之间存在分子联系，为阐明ASD患者TDP-43蛋白病变开辟了新的研究视角。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cellular & Molecular Biology Letters 生物-生化与分子生物学

CiteScore

11.60

自引率

13.30%

发文量

101

审稿时长

3 months

期刊介绍： Cellular & Molecular Biology Letters is an international journal dedicated to the dissemination of fundamental knowledge in all areas of cellular and molecular biology, cancer cell biology, and certain aspects of biochemistry, biophysics and biotechnology.