Pressure, motion, and conformational entropy in molecular recognition by proteins.

IF 2.4 Q3 BIOPHYSICS Biophysical reports Pub Date : 2023-03-08 DOI:10.1016/j.bpr.2022.100098
José A Caro, Kathleen G Valentine, Taylor R Cole, A Joshua Wand
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引用次数: 2

Abstract

The thermodynamics of molecular recognition by proteins is a central determinant of complex biochemistry. For over a half-century, detailed cryogenic structures have provided deep insight into the energetic contributions to ligand binding by proteins. More recently, a dynamical proxy based on NMR-relaxation methods has revealed an unexpected richness in the contributions of conformational entropy to the thermodynamics of ligand binding. Here, we report the pressure dependence of fast internal motion within the ribonuclease barnase and its complex with the protein barstar. In what we believe is a first example, we find that protein dynamics are conserved along the pressure-binding thermodynamic cycle. The femtomolar affinity of the barnase-barstar complex exists despite a penalty by -TΔSconf of +11.7 kJ/mol at ambient pressure. At high pressure, however, the overall change in side-chain dynamics is zero, and binding occurs with no conformational entropy penalty, suggesting an important role of conformational dynamics in the adaptation of protein function to extreme environments. Distinctive clustering of the pressure sensitivity is observed in response to both pressure and binding, indicating the presence of conformational heterogeneity involving less efficiently packed alternative conformation(s). The structural segregation of dynamics observed in barnase is striking and shows how changes in both the magnitude and the sign of regional contributions of conformational entropy to the thermodynamics of protein function are possible.

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蛋白质分子识别中的压力、运动和构象熵。
蛋白质分子识别的热力学是复杂生物化学的核心决定因素。半个多世纪以来,详细的低温结构为蛋白质对配体结合的能量贡献提供了深入的了解。最近,基于核磁共振弛豫方法的动态代理揭示了构象熵对配体结合热力学的贡献出乎意料的丰富。在这里,我们报告了核糖核酸酶的快速内部运动的压力依赖性及其与蛋白质barstar的复合体。在我们认为是第一个例子中,我们发现蛋白质动力学沿着压力结合热力学循环是守恒的。barnase-barstar复合物的飞摩尔亲和力存在,尽管在环境压力下-TΔSconf降低了+11.7 kJ/mol。然而,在高压下,侧链动力学的总体变化为零,并且结合发生时没有构象熵惩罚,这表明构象动力学在蛋白质功能适应极端环境中的重要作用。在压力和结合的反应中观察到独特的压力敏感性聚类,表明存在构象异质性,涉及效率较低的替代构象。在barnase中观察到的结构分离动力学是惊人的,并显示了构象熵对蛋白质功能热力学的区域贡献的大小和符号的变化是可能的。
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来源期刊
Biophysical reports
Biophysical reports Biophysics
CiteScore
2.40
自引率
0.00%
发文量
0
审稿时长
75 days
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