Department of Structural and Molecular Biology, Division of Biosciences, London, United Kingdom; Department of Engineering, Faculty of Natural, Mathematical and Engineering Sciences, King's College London, London, United Kingdom; The Francis Crick Institute, London, United Kingdom.
Department of Structural and Molecular Biology, Division of Biosciences, London, United Kingdom; The Francis Crick Institute, London, United Kingdom.
Biophys J. 2024 Nov 5;123(21):3798-3811. doi: 10.1016/j.bpj.2024.09.028. Epub 2024 Sep 27.
Intrinsically disordered proteins (IDPs) often contain proline residues that undergo cis/trans isomerization. While molecular dynamics (MD) simulations have the potential to fully characterize the proline cis and trans subensembles, they are limited by the slow timescales of isomerization and force field inaccuracies. NMR spectroscopy can report on ensemble-averaged observables for both the cis-proline and trans-proline states, but a full atomistic characterization of these conformers is challenging. Given the importance of proline cis/trans isomerization for influencing the conformational sampling of disordered proteins, we employed a combination of all-atom MD simulations with enhanced sampling (metadynamics), NMR, and small-angle x-ray scattering (SAXS) to characterize the two subensembles of the ORF6 C-terminal region (ORF6) from SARS-CoV-2 corresponding to the proline-57 (P57) cis and trans states. We performed MD simulations in three distinct force fields: AMBER03ws, AMBER99SB-disp, and CHARMM36m, which are all optimized for disordered proteins. Each simulation was run for an accumulated time of 180-220 μs until convergence was reached, as assessed by blocking analysis. A good agreement between the cis-P57 populations predicted from metadynamic simulations in AMBER03ws was observed with populations obtained from experimental NMR data. Moreover, we observed good agreement between the radius of gyration predicted from the metadynamic simulations in AMBER03ws and that measured using SAXS. Our findings suggest that both the cis-P57 and trans-P57 conformations of ORF6 are extremely dynamic and that interdisciplinary approaches combining both multiscale computations and experiments offer avenues to explore highly dynamic states that cannot be reliably characterized by either approach in isolation.
无规则蛋白质(IDP)通常含有脯氨酸残基,这些残基会发生顺/反式异构化。虽然分子动力学(MD)模拟有潜力充分描述脯氨酸的顺式和反式亚基,但它们受到异构化和力场不准确性的慢时间尺度的限制。NMR 光谱可以报告顺式脯氨酸和反式脯氨酸状态的总体平均可观测值,但这些构象的全原子描述具有挑战性。鉴于脯氨酸顺/反式异构化对影响无序蛋白质构象采样的重要性,我们采用全原子 MD 模拟与增强采样(元动力学)、NMR 和小角 X 射线散射(SAXS)相结合的方法,对 SARS-CoV-2 的 ORF6 端区域(ORF6)的两个亚基进行了表征,这两个亚基对应于脯氨酸-57(P57)的顺式和反式状态。我们在三种不同的力场中进行了 MD 模拟:AMBER03ws、AMBER99SB-disp 和 CHARMM36m,这些力场都是针对无序蛋白质进行优化的。每个模拟的累计运行时间为 180-220μs,直到达到收敛状态,这是通过阻塞分析来评估的。在 AMBER03ws 中进行的元动力学模拟预测的顺式-P57 群体与实验 NMR 数据获得的群体之间观察到良好的一致性。此外,我们观察到 AMBER03ws 中元动力学模拟预测的回转半径与 SAXS 测量的回转半径之间的良好一致性。我们的研究结果表明,ORF6 的顺式-P57 和反式-P57 构象都非常动态,并且结合多尺度计算和实验的跨学科方法为探索高度动态的状态提供了途径,这些状态不能仅通过任一种方法可靠地描述。
