Multiple Evolutionary Mechanisms Reduce Protein Aggregation

J. Reumers, F. Rousseau, J. Schymkowitz
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引用次数: 8

Abstract

The folding of polypeptides into stable globular protein structures requires protein sequences with a relatively high hydrophobicity and secondary structure propensity. These biophysical properties, however, also favor protein aggregation via the formation of intermolecular beta-sheets and, as a result, globular structure and aggregation are inextricable properties of protein polypeptides. Aggregates that are enriched in beta-sheet structures have been found in diseased tissues in association with at least twenty different human disorders and the effect of aggregation on protein function include simple loss-of-function but also often a gain of toxicity. Given both the ubiquity and the potentially lethal consequences of protein aggregation, negative selective pressure strongly minimizes aggregation. Various evolutionary strategies keep aggregation in check, including (1) the optimisation of the thermodynamic stability of the protein, which precludes aggregation by burial of the aggregation prone regions in solvent inaccessible regions of the structure, (2) segregation between folding nuclei and aggregation nuclei within a protein sequence, (3) the placement of so-called gatekeeper residues at the flanks of aggregating segments, that reduce the aggregation rate of (partially) unfolded proteins, and (4) molecular chaperones that target aggregation nucleating sequences directly, thereby further suppressing aggregation in a cellular environment. In this review we describe the intrinsic features built into protein sequence and structure that protect against aggregation.
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多种进化机制减少蛋白质聚集
多肽折叠成稳定的球状蛋白质结构需要具有较高疏水性和二级结构倾向的蛋白质序列。然而,这些生物物理特性也有利于蛋白质通过分子间β -片的形成聚集,因此,球状结构和聚集是蛋白质多肽不可分割的特性。在患病组织中发现了富含-片结构的聚集体,至少与20种不同的人类疾病有关,聚集体对蛋白质功能的影响包括简单的功能丧失,但通常也会增加毒性。鉴于蛋白质聚集的普遍性和潜在的致命后果,负选择压力强烈地使聚集最小化。各种进化策略可以控制聚集,包括:(1)优化蛋白质的热力学稳定性,通过将容易聚集的区域埋在溶剂无法到达的结构区域来阻止聚集;(2)蛋白质序列中折叠核和聚集核之间的隔离;(3)在聚集片段的侧翼放置所谓的守门员残基。这降低了(部分)未折叠蛋白质的聚集率,以及(4)直接靶向聚集成核序列的分子伴侣,从而进一步抑制细胞环境中的聚集。在这篇综述中,我们描述了蛋白质序列和结构的内在特征,以防止聚集。
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