DynaDom: structure-based prediction of T cell receptor inter-domain and T cell receptor-peptide-MHC (class I) association angles

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology BMC Structural Biology Pub Date : 2017-02-02 DOI:10.1186/s12900-016-0071-7
Thomas Hoffmann, Antoine Marion, Iris Antes
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引用次数: 11

Abstract

T cell receptor (TCR) molecules are involved in the adaptive immune response as they distinguish between self- and foreign-peptides, presented in major histocompatibility complex molecules (pMHC). Former studies showed that the association angles of the TCR variable domains (Vα/Vβ) can differ significantly and change upon binding to the pMHC complex. These changes can be described as a rotation of the domains around a general Center of Rotation, characterized by the interaction of two highly conserved glutamine residues.

We developed a computational method, DynaDom, for the prediction of TCR Vα/Vβ inter-domain and TCR/pMHC orientations in TCRpMHC complexes, which allows predicting the orientation of multiple protein-domains. In addition, we implemented a new approach to predict the correct orientation of the carboxamide endgroups in glutamine and asparagine residues, which can also be used as an external, independent tool.

The approach was evaluated for the remodeling of 75 and 53 experimental structures of TCR and TCRpMHC (class I) complexes, respectively. We show that the DynaDom method predicts the correct orientation of the TCR Vα/Vβ angles in 96 and 89% of the cases, for the poses with the best RMSD and best interaction energy, respectively. For the concurrent prediction of the TCR Vα/Vβ and pMHC orientations, the respective rates reached 74 and 72%. Through an exhaustive analysis, we could show that the pMHC placement can be further improved by a straightforward, yet very time intensive extension of the current approach.

The results obtained in the present remodeling study prove the suitability of our approach for interdomain-angle optimization. In addition, the high prediction rate obtained specifically for the energetically highest ranked poses further demonstrates that our method is a powerful candidate for blind prediction. Therefore it should be well suited as part of any accurate atomistic modeling pipeline for TCRpMHC complexes and potentially other large molecular assemblies.

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DynaDom:基于结构的T细胞受体结构域间和T细胞受体肽- mhc (I类)关联角预测
T细胞受体(TCR)分子参与适应性免疫反应,因为它们区分自身和外源肽,呈现在主要组织相容性复合体分子(pMHC)中。先前的研究表明,TCR可变结构域(Vα/Vβ)的结合角度在与pMHC复合物结合后会发生显著差异和变化。这些变化可以被描述为围绕一般旋转中心的结构域的旋转,其特征是两个高度保守的谷氨酰胺残基的相互作用。我们开发了一种计算方法DynaDom,用于预测TCR Vα/Vβ结构域间和TCR/pMHC复合物中的TCR/pMHC取向,该方法可以预测多个蛋白质结构域的取向。此外,我们实现了一种新的方法来预测谷氨酰胺和天冬酰胺残基中羧酰胺端基的正确取向,这也可以作为一种外部的,独立的工具。该方法分别对TCR和TCRpMHC (I类)配合物的75个和53个实验结构的重塑进行了评估。结果表明,对于RMSD最佳的位姿和相互作用能最佳的位姿,DynaDom方法分别在96%和89%的情况下预测了TCR Vα/Vβ角的正确方向。同时预测TCR Vα/Vβ和pMHC取向的正确率分别达到74%和72%。通过详尽的分析,我们可以表明,pMHC的安置可以进一步改善,通过一个简单的,但非常耗时的扩展目前的方法。本研究的结果证明了该方法在区域间角度优化中的适用性。此外,对能量排名最高的姿态的高预测率进一步证明了我们的方法是盲预测的有力候选。因此,它应该非常适合作为TCRpMHC复合物和潜在的其他大分子组装的任何精确原子建模管道的一部分。
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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%
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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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