水溶液中小溶质二聚化过程中的极端焓熵补偿。

IF 2.2 4区生物学 Q3 BIOPHYSICS European Biophysics Journal Pub Date : 2024-10-15 DOI:10.1007/s00249-024-01722-y

David J Scott, Donald J Winzor

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引用次数: 0

摘要

这篇通讯总结了最早接触极端焓熵补偿的研究成果，这一现象最早是在 20 世纪 50 年代通过重新评估等焓法和热量测定法对尿素水溶液进行溶质自结合测量而发现的。由于当时对羧酸缔合的研究仅限于通过电导率、红外分光光度法或电位滴定法测量平衡常数，二聚常数与温度无关的特性被错误地认为表示 Δ H o 的值为零，而不是 (Δ H o - TΔ S o)。在这些关于小溶质自结合的研究中，极高的焓熵补偿反映了水作为反应物的作用，其羟基与参与自结合的溶质羰基竞争。这种作用导致了 Δ H o 的正温度依赖性，它很可能与通常观察到的蛋白质-配体相互作用的负温度依赖性一致，后者表现出极高的焓熵补偿，其中溶剂对能量的贡献反映了疏水环境中有序水结构程度的变化。

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Extreme enthalpy‒entropy compensation in the dimerization of small solutes in aqueous solution.

This communication summarizes findings from the earliest encounters with extreme enthalpy‒entropy compensation, a phenomenon first detected in the 1950s by a reappraisal of isopiestic and calorimetric measurements on aqueous urea solutions in terms of solute self-association. Because concurrent studies of carboxylic acid association were confined to measurement of the equilibrium constant by conductance, IR spectrophotometry or potentiometric titration measurements, temperature-independence of the dimerization constant was mistakenly taken to signify a value of zero for Δ $H^{o}$ instead of (Δ $H^{o}$ ‒ TΔ $S^{o}$ ). In those studies of small-solute self-association the extreme enthalpy‒entropy compensation was reflecting the action of water as a reactant whose hydroxyl groups were competing for the solute carbonyl involved in self-association. Such action gives rise to a positive temperature dependence of Δ $H^{o}$ that could well be operating in concert with that responsible for the commonly observed negative dependence for protein‒ligand interactions exhibiting extreme enthalpy‒entropy compensation, where the solvent contribution to the energetics reflects changes in the extent of ordered water structure in hydrophobic environments.

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来源期刊

European Biophysics Journal 生物-生物物理

CiteScore

4.30

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： The journal publishes papers in the field of biophysics, which is defined as the study of biological phenomena by using physical methods and concepts. Original papers, reviews and Biophysics letters are published. The primary goal of this journal is to advance the understanding of biological structure and function by application of the principles of physical science, and by presenting the work in a biophysical context. Papers employing a distinctively biophysical approach at all levels of biological organisation will be considered, as will both experimental and theoretical studies. The criteria for acceptance are scientific content, originality and relevance to biological systems of current interest and importance. Principal areas of interest include: - Structure and dynamics of biological macromolecules - Membrane biophysics and ion channels - Cell biophysics and organisation - Macromolecular assemblies - Biophysical methods and instrumentation - Advanced microscopics - System dynamics.