从自然序列多样性推断蛋白质折叠机制

IF 3.2 3区生物学 Q2 BIOPHYSICS

Biophysical journal Pub Date : 2025-06-26 DOI:10.1016/j.bpj.2025.06.034

Ezequiel A. Galpern, Ernesto A. Roman, Diego U. Ferreiro

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引用次数: 0

摘要

蛋白质序列是形成其功能结构的进化约束的自然记录。我们表明，仅使用序列信息就可以超越预测天然结构和全局稳定性来推断球状蛋白的折叠机制。氨基酸水平上的一体和二体进化能量场被映射到折叠的粗粒度描述，其中蛋白质被分为连续的折叠元素，通常被称为折叠子。对于15个不同的蛋白质家族，我们通过模拟一个伊辛折叠链计算了数百种蛋白质的折叠机制，它们的能量由氨基酸序列决定。我们表明，蛋白质拓扑结构对一个家族内折叠协同性的可变性施加了限制。虽然大多数β和α / β结构显示只有少数可能的机制，尽管高序列多样性，α拓扑结构允许不同的折叠场景在家庭成员之间。我们证明突变引起的稳定性和协同性变化都可以使用基于序列的进化模型直接计算。

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Inferring protein folding mechanisms from natural sequence diversity

Protein sequences serve as a natural record of the evolutionary constraints that shape their functional structures. We show that it is possible to use only sequence information to go beyond predicting native structures and global stability to infer the folding mechanisms of globular proteins. The one- and two-body evolutionary energy fields at the amino-acid level are mapped to a coarse-grained description of folding, where proteins are divided into contiguous folding elements, commonly referred to as foldons. For 15 diverse protein families, we calculated the folding mechanisms of hundreds of proteins by simulating an Ising chain of foldons, with their energetics determined by the amino acid sequences. We show that protein topology imposes limits on the variability of folding cooperativity within a family. While most beta and alpha/beta structures exhibit only a few possible mechanisms despite high sequence diversity, alpha topologies allow for diverse folding scenarios among family members. We show that both the stability and cooperativity changes induced by mutations can be computed directly using sequence-based evolutionary models.

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来源期刊

Biophysical journal 生物-生物物理

CiteScore

6.10

自引率

5.90%

发文量

3090

审稿时长

2 months

期刊介绍： BJ publishes original articles, letters, and perspectives on important problems in modern biophysics. The papers should be written so as to be of interest to a broad community of biophysicists. BJ welcomes experimental studies that employ quantitative physical approaches for the study of biological systems, including or spanning scales from molecule to whole organism. Experimental studies of a purely descriptive or phenomenological nature, with no theoretical or mechanistic underpinning, are not appropriate for publication in BJ. Theoretical studies should offer new insights into the understanding ofexperimental results or suggest new experimentally testable hypotheses. Articles reporting significant methodological or technological advances, which have potential to open new areas of biophysical investigation, are also suitable for publication in BJ. Papers describing improvements in accuracy or speed of existing methods or extra detail within methods described previously are not suitable for BJ.