肌酸转运蛋白未折叠:脑肌酸缺乏综合征的一个棘手前提。

IF 2.8 4区 医学 Q2 NEUROSCIENCES Frontiers in Synaptic Neuroscience Pub Date : 2020-10-23 eCollection Date: 2020-01-01 DOI:10.3389/fnsyn.2020.588954
Clemens V Farr, Ali El-Kasaby, Michael Freissmuth, Sonja Sucic
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引用次数: 23

摘要

肌酸为细胞提供高能磷酸盐,用于水解三磷酸腺苷的快速重建。肌酸转运蛋白(CRT1/SLC6A8)属于溶质载体6(SLC6)蛋白家族。CRT1的关键作用是将肌酸转运通过组织屏障并进入靶细胞,如神经元和肌细胞。携带人类CRT1基因编码序列突变的个体会发展为肌酸转运蛋白缺乏症(CTD),这是脑肌酸缺乏综合征的关键潜在原因之一。CTD包括一系列临床表现,包括严重智力残疾、癫痫、自闭症、发育迟缓和运动功能障碍。CTD的特征是不存在脑肌酸,这意味着CRT1在向脑细胞供应肌酸方面发挥着不可或缺的作用。CTD相关变体通过CRT1显著降低或消除肌酸转运活性。其中许多是已知会触发折叠缺陷的点突变,导致编码的CRT1蛋白保留在内质网中,并阻止其传递到细胞表面。几种相关的SLC6转运蛋白的错误折叠也会导致人的有害病理状况;例如,多巴胺转运蛋白的突变诱导婴儿帕金森综合征/肌张力障碍,而GABA转运蛋白1的突变导致耐治疗性癫痫。在某些情况下,折叠缺陷可以被称为药理学和化学伴侣的小分子拯救,这些小分子恢复了以前无功能蛋白质的细胞表面表达和转运活性。最近CTD的分子、动物和人类病例研究的见解有助于我们理解这种复杂的疾病,并揭示了对CRT1功能障碍的广泛影响。这为治疗CTD患者提供了新的治疗前景,例如,修饰肌酸分子以促进CRT1独立进入脑细胞,或使用药物伴侣和/或变构调节剂纠正折叠缺陷和功能丧失的CTD变体。后者证明了寻找具有纠正突变特异性缺陷能力的额外化合物的合理性。
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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The Creatine Transporter Unfolded: A Knotty Premise in the Cerebral Creatine Deficiency Syndrome.

Creatine provides cells with high-energy phosphates for the rapid reconstitution of hydrolyzed adenosine triphosphate. The eponymous creatine transporter (CRT1/SLC6A8) belongs to a family of solute carrier 6 (SLC6) proteins. The key role of CRT1 is to translocate creatine across tissue barriers and into target cells, such as neurons and myocytes. Individuals harboring mutations in the coding sequence of the human CRT1 gene develop creatine transporter deficiency (CTD), one of the pivotal underlying causes of cerebral creatine deficiency syndrome. CTD encompasses an array of clinical manifestations, including severe intellectual disability, epilepsy, autism, development delay, and motor dysfunction. CTD is characterized by the absence of cerebral creatine, which implies an indispensable role for CRT1 in supplying the brain cells with creatine. CTD-associated variants dramatically reduce or abolish creatine transport activity by CRT1. Many of these are point mutations that are known to trigger folding defects, leading to the retention of encoded CRT1 proteins in the endoplasmic reticulum and precluding their delivery to the cell surface. Misfolding of several related SLC6 transporters also gives rise to detrimental pathologic conditions in people; e.g., mutations in the dopamine transporter induce infantile parkinsonism/dystonia, while mutations in the GABA transporter 1 cause treatment-resistant epilepsy. In some cases, folding defects are amenable to rescue by small molecules, known as pharmacological and chemical chaperones, which restore the cell surface expression and transport activity of the previously non-functional proteins. Insights from the recent molecular, animal and human case studies of CTD add toward our understanding of this complex disorder and reveal the wide-ranging effects elicited upon CRT1 dysfunction. This grants novel therapeutic prospects for the treatment of patients afflicted with CTD, e.g., modifying the creatine molecule to facilitate CRT1-independent entry into brain cells, or correcting folding-deficient and loss-of-function CTD variants using pharmacochaperones and/or allosteric modulators. The latter justifies a search for additional compounds with a capacity to correct mutation-specific defects.

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CiteScore
7.10
自引率
2.70%
发文量
74
审稿时长
14 weeks
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