大分子拥挤不仅仅是核心排斥。

IF 10.4 1区生物学 Q1 BIOPHYSICS

Annual Review of Biophysics Pub Date : 2022-02-03 DOI:10.1146/annurev-biophys-091321-071829

Shannon L. Speer, C. Stewart, Liel Sapir, D. Harries, G. Pielak

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引用次数: 36

摘要

细胞是拥挤的，但蛋白质几乎总是在稀释的水缓冲液中研究。我们回顾了拥挤影响蛋白质稳定性和蛋白质结合的平衡热力学的实验证据，并讨论了用于解释这些观察结果的理论。在此过程中，我们强调了合成聚合物和生物相关聚合物之间的差异。基于核心相互作用的理论只能预测群体诱导的熵稳定。然而，在生理相关条件下进行的基于实验的努力表明，拥挤可以破坏蛋白质及其复合物的稳定。此外，对大溶质和小溶质(包括渗透物、糖、合成聚合物和蛋白质)产生的拥挤效应的温度依赖性进行量化，揭示了稳定或破坏蛋白质的焓效应。拥挤诱导的不稳定和焓分量指向大分子、溶质和水之间的化学相互作用。最后，对今后的研究提出建议。预计《生物物理学年鉴》第51卷的最终在线出版日期为2022年5月。修订后的估计数请参阅http://www.annualreviews.org/page/journal/pubdates。

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Macromolecular Crowding Is More than Hard-Core Repulsions.

Cells are crowded, but proteins are almost always studied in dilute aqueous buffer. We review the experimental evidence that crowding affects the equilibrium thermodynamics of protein stability and protein association and discuss the theories employed to explain these observations. In doing so, we highlight differences between synthetic polymers and biologically relevant crowders. Theories based on hard-core interactions predict only crowding-induced entropic stabilization. However, experiment-based efforts conducted under physiologically relevant conditions show that crowding can destabilize proteins and their complexes. Furthermore, quantification of the temperature dependence of crowding effects produced by both large and small cosolutes, including osmolytes, sugars, synthetic polymers, and proteins, reveals enthalpic effects that stabilize or destabilize proteins. Crowding-induced destabilization and the enthalpic component point to the role of chemical interactions between and among the macromolecules, cosolutes, and water. We conclude with suggestions for future studies. Expected final online publication date for the Annual Review of Biophysics, Volume 51 is May 2022. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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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.