利用高斯弹性网络相关图距离探索血红蛋白T到R2的路径。

IF 2.8 4区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Proteins-Structure Function and Bioinformatics Pub Date : 2025-07-05 DOI:10.1002/prot.70014

Yuval Valenci, Dror Tobi

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引用次数: 0

摘要

蛋白质是动态的，会发生构象变化。这些变化可能会影响蛋白质不同区域执行的运动，并反映在运动相关图中。在一组四聚体血红蛋白结构上提出并举例说明了一种精确测量这些变化的方法。利用高斯网络模型计算各结构的运动相关图。不同结构的地图元素之间的平方根差被用来计算它们之间的距离。利用这个新的距离，计算出T态和R2态之间的路径。沿路径的中间产物表现出逐渐的组间和组内相关变化。同一二聚体中每个亚基与另一个亚基的相关性在T→R2跃迁过程中变得越来越正。同时，从界面（α1β2 / β1α2）来看，域间的相关系数越来越负。此外，这些距离用于聚类Hb结构。新提出的距离与基于结构的距离无关，为探索蛋白质的构象空间提供了一种新的方法。

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Exploring the Hemoglobin T to R2 Path Using Gaussian Elastic Network Correlation Map Distance.

Proteins are dynamic and undergo conformational changes. These changes may affect the motions executed by different regions of the proteins and are reflected in the motion correlation map. A method to accurately measure these changes is presented and exemplified on a set of tetrameric Hemoglobin structures. Using the Gaussian Network Model, the motion correlation map of each structure is calculated. The root of the square differences between the elements of the map of different structures is used to calculate their distance. Using this novel distance, the path between the T and R2 states is calculated. The intermediates along the path show gradual inter and intradimer correlation changes. The correlation of each subunit with the other in the same dimer becomes increasingly positive upon the T → R2 transition. Meanwhile, the interdomain correlation, as seen from the interface (α1β2 / β1α2), becomes increasingly negative. In addition, these distances are used to cluster the Hb structures. The newly suggested distance does not correlate with structure-based distances and offers a new way to explore the conformational space of proteins.

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来源期刊

Proteins-Structure Function and Bioinformatics 生物-生化与分子生物学

CiteScore

5.90

自引率

3.40%

发文量

172

审稿时长

3 months

期刊介绍： PROTEINS : Structure, Function, and Bioinformatics publishes original reports of significant experimental and analytic research in all areas of protein research: structure, function, computation, genetics, and design. The journal encourages reports that present new experimental or computational approaches for interpreting and understanding data from biophysical chemistry, structural studies of proteins and macromolecular assemblies, alterations of protein structure and function engineered through techniques of molecular biology and genetics, functional analyses under physiologic conditions, as well as the interactions of proteins with receptors, nucleic acids, or other specific ligands or substrates. Research in protein and peptide biochemistry directed toward synthesizing or characterizing molecules that simulate aspects of the activity of proteins, or that act as inhibitors of protein function, is also within the scope of PROTEINS. In addition to full-length reports, short communications (usually not more than 4 printed pages) and prediction reports are welcome. Reviews are typically by invitation; authors are encouraged to submit proposed topics for consideration.