Coyne Alyssa N, Zaepfel Benjamin L, Zarnescu Daniela C
Department of Molecular and Cellular Biology, University of ArizonaTucson, AZ, United States.
Department of Neuroscience, University of ArizonaTucson, AZ, United States.
Front Cell Neurosci. 2017 Aug 17;11:243. doi: 10.3389/fncel.2017.00243. eCollection 2017.
Amyotrophic Lateral Sclerosis (ALS) is a progressive and fatal neurodegenerative disease affecting both upper and lower motor neurons. The molecular mechanisms underlying disease pathogenesis remain largely unknown. Multiple genetic loci including genes involved in proteostasis and ribostasis have been linked to ALS providing key insights into the molecular mechanisms underlying disease. In particular, the identification of the RNA binding proteins TDP-43 and fused in sarcoma (FUS) as causative factors of ALS resulted in a paradigm shift centered on the study of RNA dysregulation as a major mechanism of disease. With wild-type TDP-43 pathology being found in ~97% of ALS cases and the identification of disease causing mutations within its sequence, TDP-43 has emerged as a prominent player in ALS. More recently, studies of the newly discovered repeat expansion are lending further support to the notion of defects in RNA metabolism as a key factor underlying ALS. RNA binding proteins are involved in all aspects of RNA metabolism ranging from splicing, transcription, transport, storage into RNA/protein granules, and translation. How these processes are affected by disease-associated mutations is just beginning to be understood. Considerable work has gone into the identification of splicing and transcription defects resulting from mutations in RNA binding proteins associated with disease. More recently, defects in RNA transport and translation have been shown to be involved in the pathomechanism of ALS. A central hypothesis in the field is that disease causing mutations lead to the persistence of RNA/protein complexes known as stress granules. Under times of prolonged cellular stress these granules sequester specific mRNAs preventing them from translation, and are thought to evolve into pathological aggregates. Here we will review recent efforts directed at understanding how altered RNA metabolism contributes to ALS pathogenesis.
肌萎缩侧索硬化症(ALS)是一种进行性致命的神经退行性疾病,会影响上下运动神经元。疾病发病机制背后的分子机制在很大程度上仍然未知。包括参与蛋白质稳态和核糖体稳态的基因在内的多个基因位点已与ALS相关联,这为疾病背后的分子机制提供了关键见解。特别是,RNA结合蛋白TDP-43和肉瘤融合蛋白(FUS)被鉴定为ALS的致病因素,导致了以RNA失调研究为主要疾病机制的范式转变。在约97%的ALS病例中发现了野生型TDP-43病理学特征,并且在其序列中鉴定出致病突变,TDP-43已成为ALS中的一个重要因素。最近,对新发现的重复扩增的研究进一步支持了RNA代谢缺陷是ALS潜在关键因素的观点。RNA结合蛋白参与RNA代谢的各个方面,从剪接、转录、运输、储存到RNA/蛋白质颗粒以及翻译。这些过程如何受到疾病相关突变的影响才刚刚开始被理解。已经进行了大量工作来鉴定与疾病相关的RNA结合蛋白突变导致的剪接和转录缺陷。最近,RNA运输和翻译缺陷已被证明与ALS的发病机制有关。该领域的一个核心假说是,致病突变导致称为应激颗粒的RNA/蛋白质复合物持续存在。在细胞长期应激时,这些颗粒会隔离特定的mRNA,阻止它们翻译,并被认为会演变成病理性聚集体。在这里,我们将综述最近为理解RNA代谢改变如何导致ALS发病机制所做的努力。
