Disease-related misassembly of membrane proteins.

Annual review of biophysics and biomolecular structure Pub Date : 2004-01-01 DOI:10.1146/annurev.biophys.33.110502.140348

Charles R Sanders, Jeffrey K Myers

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引用次数: 244

Abstract

Medical genetics so far has identified approximately 16,000 missense mutations leading to single amino acid changes in protein sequences that are linked to human disease. A majority of these mutations affect folding or trafficking, rather than specifically affecting protein function. Many disease-linked mutations occur in integral membrane proteins, a class of proteins about whose folding we know very little. We examine the phenomenon of disease-linked misassembly of membrane proteins and describe model systems currently being used to study the delicate balance between proper folding and misassembly. We review a mechanism by which cells recognize membrane proteins with a high potential to misfold before they actually do, and which targets these culprits for degradation. Serious disease phenotypes can result from loss of protein function and from misfolded proteins that the cells cannot degrade, leading to accumulation of toxic aggregates. Misassembly may be averted by small-molecule drugs that bind and stabilize the native state.

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与疾病相关的膜蛋白错误组装。

到目前为止，医学遗传学已经确定了大约16000个导致与人类疾病有关的蛋白质序列中单个氨基酸变化的错义突变。这些突变中的大多数影响折叠或运输，而不是专门影响蛋白质的功能。许多与疾病相关的突变发生在整体膜蛋白中，这是一类我们对其折叠知之甚少的蛋白质。我们研究了与疾病相关的膜蛋白错组装现象，并描述了目前用于研究适当折叠和错组装之间微妙平衡的模型系统。我们回顾了一种机制，通过这种机制，细胞在实际折叠之前识别出具有高错误折叠潜力的膜蛋白，并针对这些罪魁祸首进行降解。严重的疾病表型可由蛋白质功能丧失和细胞无法降解的错误折叠蛋白质引起，从而导致有毒聚集体的积累。通过结合和稳定天然状态的小分子药物可以避免错误组装。

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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