Introducing NMR strategies to define water molecules that drive metal binding in a transcriptional regulator

M. Villarruel Dujovne , M. Bringas , I.C. Felli , E. Ravera , S. Di Lella , D.A. Capdevila
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Abstract

Staphylococcus aureus CzrA is a paradigmatic member of the ArsR family of transcriptional metalloregulators, which are critical for the bacterial response to stress. Zinc binding to CzrA, which induces DNA derepression, is entropically driven, as shown by calorimetry. A detailed equilibrium dynamics study of different allosteric states of CzrA revealed that zinc induces an entropy redistribution that controls for DNA binding regulation; however, this change in conformational entropy only accounts for a small net contribution to the total entropy. This difference between the change in conformational entropy vs. total entropy of zinc binding implies a significant contribution of solvent molecule rearrangements to this equilibrium. However, the absence of major structural changes suggests that solvent rearrangements occur mainly on the protein surface and/or from zinc desolvation, concomitant with a dynamical redistribution of conformational entropy. Previous results also suggest that zinc binding not only leads to a redistribution of protein internal dynamics, but also release of water molecules from the protein surface. In turn, these water molecules may make a significant contribution to the allosteric response that results in dissociation from the DNA.

Quantifying the differential hydration of two conformational states that share very similar crystal structures and then correlating this with the protein's solvent entropy change constitutes an unresolved problem, even when thermodynamics suggest a significant contribution of solvent entropy. Here, we present different avenues to dissect hydration dynamics in a metal-binding transcriptional regulator that provide different insights into this complex problem. We explore primary solution NMR tools for probing protein–water interactions: the laboratory frame nuclear Overhauser effect (NOE) and its rotating frame counterpart (ROE) between long-lived water molecules and the protein residues. The wNOE/wROE ratio is a promising tool for the detection of hydration dynamics near the surface of a protein in a site-specific manner, minimizing contamination from bulk solvent. Molecular dynamics simulations and computational methods designed to provide a spatially resolved picture of solvent thermodynamics were also employed to provide a more complete panorama of solvent redistribution.

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引入核磁共振的策略来定义水分子驱动金属结合的转录调节
金黄色葡萄球菌(Staphylococcus aureus)的CzrA是ArsR转录金属调节因子家族的典型成员,对细菌的应激反应至关重要。锌与CzrA结合,诱导DNA抑制,是熵驱动的,如量热法所示。对CzrA不同变构状态的详细平衡动力学研究表明,锌诱导了控制DNA结合调控的熵重分布;然而,这种构象熵的变化对总熵的净贡献很小。锌结合的构象熵与总熵之间的差异意味着溶剂分子重排对这种平衡的重要贡献。然而,没有重大的结构变化表明溶剂重排主要发生在蛋白质表面和/或锌的脱溶,伴随着构象熵的动态重新分布。以往的研究结果也表明,锌的结合不仅会导致蛋白质内部动力学的重新分配,还会从蛋白质表面释放水分子。反过来,这些水分子可能对导致与DNA分离的变构反应做出重大贡献。尽管热力学表明溶剂熵对两种晶体结构非常相似的构象状态的水化差异有重要影响,但量化这两种构象状态的水化差异,并将其与蛋白质的溶剂熵变化联系起来,仍是一个未解决的问题。在这里,我们提出了不同的途径来剖析水合动力学中的金属结合转录调节剂,提供不同的见解,以了解这个复杂的问题。我们探索了用于探测蛋白质-水相互作用的主要溶液NMR工具:长寿命水分子和蛋白质残基之间的实验室框架核Overhauser效应(NOE)及其旋转框架对应物(ROE)。wNOE/wROE比值是一种很有前途的工具,用于以特定位点的方式检测蛋白质表面附近的水合动力学,最大限度地减少了本体溶剂的污染。分子动力学模拟和计算方法旨在提供溶剂热力学的空间分辨图,也用于提供溶剂再分配的更完整的全景。
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