适应导向分子动力学研究突变对心肌肌钙蛋白 C 调节域钙亲和力的影响。
Adaptative Steered Molecular Dynamics Study of Mutagenesis Effects on Calcium Affinity in the Regulatory Domain of Cardiac Troponin C.
机构信息
Department of Chemistry and Biochemistry, The Ohio State University, Columbus, Ohio 43210, United States.
出版信息
J Chem Inf Model. 2021 Jun 28;61(6):3052-3057. doi: 10.1021/acs.jcim.1c00419. Epub 2021 Jun 3.
Abstract
Calcium-dependent cardiac muscle contraction is regulated by the protein complex troponin (cTn) and specifically by the regulatory N-terminal domain (N-cTnC) which contains one active Ca binding site (site II). It has been previously shown that cardiac muscle contractility and functionality is affected by mutations in N-cTnC which alter calcium binding affinity. Here, we describe the application of adaptive steered molecular dynamics to characterize the influence of N-cTnC mutations on site II calcium binding affinity. We observed the correct trends for all of the studied calcium sensitizing and desensitizing mutants, in conjunction with loop II perturbations. Additionally, the potential of mean force accuracy was shown to increase substantially with increasingly slower speeds and using fewer trajectories. This study presents a novel approach to computationally estimate the Ca binding affinity of N-cTnC structures and is a valuable potential tool to support the design and characterization of novel mutations with potential therapeutic benefits.
摘要
钙依赖性心肌收缩受肌钙蛋白复合物(cTn)调节,特别是受调节的 N 端结构域(N-cTnC)调节,其包含一个活性钙结合位点(位点 II)。先前已经表明,N-cTnC 中的突变会影响钙结合亲和力,从而影响心肌收缩性和功能。在这里,我们描述了自适应导向分子动力学的应用,以表征 N-cTnC 突变对位点 II 钙结合亲和力的影响。我们观察到所有研究的钙敏化和脱敏突变体都与 II 环扰动一起呈现出正确的趋势。此外,随着速度越来越慢和使用的轨迹越来越少,平均力势的准确性潜力显示出大幅增加。这项研究提出了一种计算估计 N-cTnC 结构钙结合亲和力的新方法,是支持具有潜在治疗益处的新型突变体的设计和表征的有价值的潜在工具。
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