使用混合awsem -血红素模型探索血红素蛋白的折叠能量景观

IF 1.8 4区 生物学 Q3 BIOPHYSICS Journal of Biological Physics Pub Date : 2022-01-09 DOI:10.1007/s10867-021-09596-3
Xun Chen, Wei Lu, Min-Yeh Tsai, Shikai Jin, Peter G. Wolynes
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引用次数: 2

摘要

血红素是许多蛋白质的活性中心。在这里,我们通过计算探索血红素在蛋白质折叠和蛋白质结构中的作用。我们使用一种混合模型来模拟血红素蛋白,该模型采用了AWSEM哈密顿量,这是一种粗粒度的蛋白质链力场,而AMBER是血红素的全原子力场。我们精心设计了可转移力场来模拟蛋白质和血红素之间的相互作用。混合模型中蛋白质与配体相互作用的类型包括硫酯共价键、配位共价键、氢键和静电作用。我们探讨了不同类型的血红素(血红素b和血红素c)对折叠和结构预测的影响。包括这两种血红素可以提高蛋白质结构预测的质量。自由能图表明,这两种血红素都可以作为蛋白质折叠的成核位点,稳定蛋白质的折叠状态。在结合血红素时,血红素c的配位共价键和硫酯共价键将血红素推向天然口袋。静电也有助于寻找结合位点。
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Exploring the folding energy landscapes of heme proteins using a hybrid AWSEM-heme model

Heme is an active center in many proteins. Here we explore computationally the role of heme in protein folding and protein structure. We model heme proteins using a hybrid model employing the AWSEM Hamiltonian, a coarse-grained forcefield for the protein chain along with AMBER, an all-atom forcefield for the heme. We carefully designed transferable force fields that model the interactions between the protein and the heme. The types of protein–ligand interactions in the hybrid model include thioester covalent bonds, coordinated covalent bonds, hydrogen bonds, and electrostatics. We explore the influence of different types of hemes (heme b and heme c) on folding and structure prediction. Including both types of heme improves the quality of protein structure predictions. The free energy landscape shows that both types of heme can act as nucleation sites for protein folding and stabilize the protein folded state. In binding the heme, coordinated covalent bonds and thioester covalent bonds for heme c drive the heme toward the native pocket. The electrostatics also facilitates the search for the binding site.

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来源期刊
Journal of Biological Physics
Journal of Biological Physics 生物-生物物理
CiteScore
3.00
自引率
5.60%
发文量
20
审稿时长
>12 weeks
期刊介绍: Many physicists are turning their attention to domains that were not traditionally part of physics and are applying the sophisticated tools of theoretical, computational and experimental physics to investigate biological processes, systems and materials. The Journal of Biological Physics provides a medium where this growing community of scientists can publish its results and discuss its aims and methods. It welcomes papers which use the tools of physics in an innovative way to study biological problems, as well as research aimed at providing a better understanding of the physical principles underlying biological processes.
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