Ancestral Reconstruction and the Evolution of Protein Energy Landscapes.

IF 10.4 1区生物学 Q1 BIOPHYSICS

Annual Review of Biophysics Pub Date : 2024-07-01 Epub Date: 2024-06-28 DOI:10.1146/annurev-biophys-030722-125440

Lauren O Chisholm, Kona N Orlandi, Sophia R Phillips, Michael J Shavlik, Michael J Harms

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引用次数: 0

Abstract

A protein's sequence determines its conformational energy landscape. This, in turn, determines the protein's function. Understanding the evolution of new protein functions therefore requires understanding how mutations alter the protein energy landscape. Ancestral sequence reconstruction (ASR) has proven a valuable tool for tackling this problem. In ASR, one phylogenetically infers the sequences of ancient proteins, allowing characterization of their properties. When coupled to biophysical, biochemical, and functional characterization, ASR can reveal how historical mutations altered the energy landscape of ancient proteins, allowing the evolution of enzyme activity, altered conformations, binding specificity, oligomerization, and many other protein features. In this article, we review how ASR studies have been used to dissect the evolution of energy landscapes. We also discuss ASR studies that reveal how energy landscapes have shaped protein evolution. Finally, we propose that thinking about evolution from the perspective of an energy landscape can improve how we approach and interpret ASR studies.

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蛋白质能量景观的祖先重建与进化

蛋白质的序列决定了它的构象能谱。这反过来又决定了蛋白质的功能。因此，要了解蛋白质新功能的进化，就必须了解突变是如何改变蛋白质的能量景观的。事实证明，祖先序列重建（ASR）是解决这一问题的重要工具。在 ASR 中，人们通过系统发育推断古代蛋白质的序列，从而确定其特性。当与生物物理、生物化学和功能表征相结合时，ASR 可以揭示历史突变是如何改变古代蛋白质的能量景观的，从而实现酶活性、构象改变、结合特异性、寡聚化和许多其他蛋白质特征的进化。在本文中，我们将回顾 ASR 研究是如何被用于剖析能量景观的进化的。我们还讨论了揭示能量景观如何影响蛋白质进化的 ASR 研究。最后，我们提出，从能量景观的角度来思考进化可以改善我们处理和解释 ASR 研究的方法。生物物理学年刊》（Annual Review of Biophysics）第 53 卷的最终在线出版日期预计为 2024 年 5 月。修订后的预计日期请参见 http://www.annualreviews.org/page/journal/pubdates。

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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来源期刊

Annual Review of Biophysics 生物-生物物理

CiteScore

21.00

自引率

0.00%

发文量

期刊介绍： The Annual Review of Biophysics, in publication since 1972, covers significant developments in the field of biophysics, including macromolecular structure, function and dynamics, theoretical and computational biophysics, molecular biophysics of the cell, physical systems biology, membrane biophysics, biotechnology, nanotechnology, and emerging techniques.