An aggregate analysis of many predicted structures to reduce errors in protein structure comparison caused by conformational flexibility

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology
Brian G Godshall, Yisheng Tang, Wenjie Yang, Brian Y Chen
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引用次数: 6

Abstract

Conformational flexibility creates errors in the comparison of protein structures. Even small changes in backbone or sidechain conformation can radically alter the shape of ligand binding cavities. These changes can cause structure comparison programs to overlook functionally related proteins with remote evolutionary similarities, and cause others to incorrectly conclude that closely related proteins have different binding preferences, when their specificities are actually similar. Towards the latter effort, this paper applies protein structure prediction algorithms to enhance the classification of homologous proteins according to their binding preferences, despite radical conformational differences.

Specifically, structure prediction algorithms can be used to "remodel" existing structures against the same template. This process can return proteins in very different conformations to similar, objectively comparable states. Operating on close homologs exploits the accuracy of structure predictions on closely related proteins, but structure prediction is often a nondeterministic process. Identical inputs can generate subtly different models with very different binding cavities that make structure comparison difficult. We present a first method to mitigate such errors, called "medial remodeling", that examines a large number of predicted structures to eliminate extreme models of the same binding cavity.

Our results, on the enolase and tyrosine kinase superfamilies, demonstrate that remodeling can enable proteins in very different conformations to be returned to states that can be objectively compared. Structures that would have been erroneously classified as having different binding preferences were often correctly classified after remodeling, while structures that would have been correctly classified as having different binding preferences almost always remained distinct. The enolase superfamily, which exhibited less sequential diversity than the tyrosine kinase superfamily, was classified more accurately after remodeling than the tyrosine kinases. Medial remodeling reduced errors from models with unusual perturbations that distort the shape of the binding site, enhancing classification accuracy.

This paper demonstrates that protein structure prediction can compensate for conformational variety in the comparison of protein-ligand binding sites. While protein structure prediction introduces new uncertainties into the structure comparison problem, our results indicate that unusual models can be ignored through an analysis of many models, using techniques like medial remodeling. These results point to applications of protein structure comparison that extend beyond existing crystal structures.

Abstract Image

对许多预测结构进行汇总分析,以减少由于构象灵活性引起的蛋白质结构比较误差
构象灵活性在蛋白质结构的比较中产生错误。即使主链或侧链构象的微小变化也能从根本上改变配体结合腔的形状。这些变化可能导致结构比较程序忽略了具有遥远进化相似性的功能相关蛋白质,并导致其他人错误地得出结论,认为密切相关的蛋白质具有不同的结合偏好,而实际上它们的特异性相似。对于后者,本文应用蛋白质结构预测算法来增强同源蛋白质的分类,根据它们的结合偏好,尽管自由基构象的差异。具体来说,结构预测算法可用于针对相同模板对现有结构进行“重塑”。这个过程可以使不同构象的蛋白质返回到相似的、客观上可比较的状态。对接近同源物的操作利用了对密切相关蛋白质的结构预测的准确性,但结构预测通常是一个不确定的过程。相同的输入可以产生具有非常不同的结合腔的细微不同的模型,这使得结构比较变得困难。我们提出了第一种方法来减轻这种错误,称为“内侧重塑”,该方法检查大量预测结构以消除相同结合腔的极端模型。我们关于烯醇化酶和酪氨酸激酶超家族的研究结果表明,重塑可以使非常不同构象的蛋白质恢复到可以客观比较的状态。被错误分类为具有不同结合偏好的结构在重塑后通常被正确分类,而被正确分类为具有不同结合偏好的结构几乎总是保持不同。烯醇化酶超家族的序列多样性低于酪氨酸激酶超家族,但在重塑后的分类比酪氨酸激酶更准确。内侧重塑减少了异常扰动扭曲结合位点形状的模型的错误,提高了分类准确性。本文证明,蛋白质结构预测可以补偿蛋白质-配体结合位点比较中的构象变化。虽然蛋白质结构预测为结构比较问题引入了新的不确定性,但我们的研究结果表明,通过使用内侧重塑等技术对许多模型进行分析,可以忽略异常模型。这些结果指出了蛋白质结构比较的应用,超出了现有的晶体结构。
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来源期刊
BMC Structural Biology
BMC Structural Biology 生物-生物物理
CiteScore
3.60
自引率
0.00%
发文量
0
期刊介绍: BMC Structural Biology is an open access, peer-reviewed journal that considers articles on investigations into the structure of biological macromolecules, including solving structures, structural and functional analyses, and computational modeling.
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