心得安可减少体外模型C9orf72-ALS/FTD细胞毒性聚集体的积累

Mira Seidel , Sandeep Rajkumar , Christina Steffke , Vivien Noeth , Shreya Agarwal , Kevin Roger , Joanna Lipecka , Albert Ludolph , Chiara Ida Guerrera , Tobias Boeckers , Alberto Catanese
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引用次数: 0

摘要

C9orf72基因突变是家族性肌萎缩侧索硬化症(ALS)和额颞叶痴呆症(FTD)的最常见原因。与该基因相关的致病机制是位于1a和1b非编码外显子之间的GGGGCC六核苷酸的异常内含子扩增的直接结果,其可以被转录形成细胞毒性RNA焦点,甚至翻译成易于聚集的二肽重复蛋白。重要的是,这些重复序列的异常长度也影响C9orf72本身的表达水平,这表明单倍性不足是额外的病理机制。因此,在C9orf72突变的情况下,毒性功能获得和功能丧失似乎是不同的但仍然共存的特征,有助于疾病的发作。在这项研究中,我们旨在确定一种策略来解决C9orf72相关病理生物化学的两个方面,并为更好地理解导致神经元损失的机制提供原理证明信息。通过使用过表达毒性poly(GA)(GGGGCC重复序列中最丰富的蛋白质产物)的原代神经元,我们发现抗心律失常药物普萘洛尔可以有效减少异常聚集体的积累,并提高C9orf72相关培养物的存活率。有趣的是,分解代谢的改善似乎不依赖于主要的降解途径,如自噬和蛋白酶体。通过分析普萘洛尔暴露后表达poly(GA)的神经元的蛋白质组,我们发现该药物通过一种直接涉及C9orf72蛋白的机制增加了溶酶体降解,其水平在治疗后增加。β受体阻滞剂对hiPSC衍生的C9orf72突变运动神经元聚集体的积累和存活的有益作用的进一步证实,加强了解决C9orf七十二病理学的两个方面可能是治疗这些ALS/FTD病例的有效策略的发现。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Propranolol reduces the accumulation of cytotoxic aggregates in C9orf72-ALS/FTD in vitro models

Propranolol reduces the accumulation of cytotoxic aggregates in C9orf72-ALS/FTD in vitro models

Mutations in the C9orf72 gene are the most common cause of familial amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). The pathogenetic mechanisms linked to this gene are a direct consequence of an aberrant intronic expansion of a GGGGCC hexanucleotide located between the 1a and 1b non-coding exons, which can be transcribed to form cytotoxic RNA foci or even translated into aggregation-prone dipeptide repeat proteins. Importantly, the abnormal length of these repeats affects also the expression levels of C9orf72 itself, which suggests haploinsufficiency as additional pathomechanism. Thus, it appears that both toxic gain of function and loss of function are distinct but still coexistent features contributing to the insurgence of the disease in case of C9orf72 mutations. In this study, we aimed at identifying a strategy to address both aspects of the C9orf72-related pathobiochemistry and provide proof-of-principle information for a better understanding of the mechanisms leading to neuronal loss. By using primary neurons overexpressing toxic poly(GA), the most abundant protein product of the GGGGCC repeats, we found that the antiarrhythmic drug propranolol could efficiently reduce the accumulation of aberrant aggregates and increase the survival of C9orf72-related cultures. Interestingly, the improved catabolism appeared to not depend on major degradative pathways such as autophagy and the proteasome. By analyzing the proteome of poly(GA)-expressing neurons after exposure to propranolol, we found that the drug increased lysosomal degradation through a mechanism directly involving C9orf72 protein, whose levels were increased after treatment. Further confirmation of the beneficial effect of the beta blocker on aggregates' accumulation and survival of hiPSC-derived C9orf72-mutant motoneurons strengthened the finding that addressing both facets of C9orf72 pathology might represent a valid strategy for the treatment of these ALS/FTD cases.

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