CoDIAC: A comprehensive approach for interaction analysis reveals novel insights into SH2 domain function and regulation

Alekhya Kandoor, Gabrielle Martinez, Julianna M. Hitchcock, Savannah Angel, Logan Campbell, Saqib Rizvi, Kristen M. Naegle
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引用次数: 0

Abstract

Protein domains are conserved structural and functional units and are the functional building blocks of proteins. Evolutionary expansion means that domain families are often represented by many members in a species, which are found in various configurations with other domains, which have evolved new specificity for interacting partners. Here, we develop a structure-based interface analysis to comprehensively map domain interfaces from available experimental and predicted structures, including interfaces with other macromolecules and intraprotein interfaces (such as might exist between domains in a protein). We hypothesized that a comprehensive approach to contact mapping of domains could yield new insights. Specifically, we use it to gain information about how domains selectivity interact with ligands, whether domain-domain interfaces of repeated domain partnerships are conserved across diverse proteins, and identify regions of conserved post-translational modifications, using relationship to interaction interfaces as a method to hypothesize the effect of post-translational modifications (and mutations). We applied this approach to the human SH2 domain family, an extensive modular unit that is the foundation of phosphotyrosine-mediated signaling, where we identified a novel approach to understanding the binding selectivity of SH2 domains and evidence that there is coordinated and conserved regulation of multiple SH2 domain binding interfaces by tyrosine and serine/threonine phosphorylation and acetylation, suggesting that multiple signaling systems can regulate protein activity and SH2 domain interactions in a regulated manner. We provide the extensive features of the human SH2 domain family and this modular approach, as an open source Python package for COmprehensive Domain Interface Analysis of Contacts (CoDIAC).
CoDIAC:一种用于相互作用分析的综合方法揭示了有关 SH2 结构域功能和调控的新见解
蛋白质结构域是保守的结构和功能单元,是蛋白质的功能构件。进化扩张意味着结构域家族在一个物种中往往有许多成员,这些成员与其他结构域以不同的构型存在,从而进化出新的特异性相互作用伙伴。在这里,我们开发了一种基于结构的界面分析方法,从现有的实验和预测结构中全面绘制结构域界面,包括与其他大分子的界面和蛋白质内部界面(如蛋白质中结构域之间可能存在的界面)。我们假设,采用综合方法绘制结构域接触图可以产生新的见解。具体来说,我们利用这种方法来获得有关结构域如何选择性地与配体相互作用的信息,了解重复结构域伙伴关系的结构域-结构域界面在不同蛋白质中是否是保守的,并确定翻译后修饰的保守区域,利用与相互作用界面的关系作为一种方法来假设翻译后修饰(和突变)的影响。我们将这种方法应用于人类 SH2 结构域家族,这是一个广泛的模块化单元,是磷酸化酪氨酸介导的信号转导的基础。我们发现了一种新的方法来理解 SH2 结构域的结合选择性,并且有证据表明,酪氨酸和丝氨酸/苏氨酸磷酸化和乙酰化对多个 SH2 结构域结合界面进行了协调和保守的调控,这表明多种信号系统可以以调控的方式调控蛋白质的活性和 SH2 结构域的相互作用。我们提供了人类 SH2 结构域家族的广泛特征和这种模块化方法,并将其作为一个开源 Python 软件包,用于联系的综合结构域界面分析(CoDIAC)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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