The Effects of Codon Usage on Protein Structure and Folding.

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-030722-020555

McKenze J Moss, Laura M Chamness, Patricia L Clark

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Abstract

The rate of protein synthesis is slower than many folding reactions and varies depending on the synonymous codons encoding the protein sequence. Synonymous codon substitutions thus have the potential to regulate cotranslational protein folding mechanisms, and a growing number of proteins have been identified with folding mechanisms sensitive to codon usage. Typically, these proteins have complex folding pathways and kinetically stable native structures. Kinetically stable proteins may fold only once over their lifetime, and thus, codon-mediated regulation of the pioneer round of protein folding can have a lasting impact. Supporting an important role for codon usage in folding, conserved patterns of codon usage appear in homologous gene families, hinting at selection. Despite these exciting developments, there remains few experimental methods capable of quantifying translation elongation rates and cotranslational folding mechanisms in the cell, which challenges the development of a predictive understanding of how biology uses codons to regulate protein folding.

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密码子使用对蛋白质结构和折叠的影响

蛋白质合成的速度比许多折叠反应都要慢，而且根据编码蛋白质序列的同义密码子的不同而变化。因此，同义密码子替换有可能调节蛋白质的共翻译折叠机制，而且越来越多的蛋白质已被发现具有对密码子使用敏感的折叠机制。通常，这些蛋白质具有复杂的折叠途径和动力学稳定的原生结构。动力学上稳定的蛋白质在其一生中可能只折叠一次，因此，密码子介导的对蛋白质折叠先驱的调控可能会产生持久的影响。同源基因家族中出现的密码子使用的保守模式支持了密码子使用在折叠中的重要作用，暗示了选择。尽管取得了这些令人兴奋的进展，但能够量化细胞中翻译伸长率和共翻译折叠机制的实验方法仍然很少，这对发展对生物学如何利用密码子调控蛋白质折叠的预测性理解提出了挑战。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%

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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.