SARS-CoV-2 变异影响 RBD 的构象动力学和 ACE2 的可及性。

Frontiers in Medical Technology Pub Date : 2022-10-05 eCollection Date: 2022-01-01 DOI:10.3389/fmedt.2022.1009451
Mariana Valério, Luís Borges-Araújo, Manuel N Melo, Diana Lousa, Cláudio M Soares
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引用次数: 0

摘要

由严重急性呼吸系统综合症冠状病毒 2(SARS-CoV-2)引起的冠状病毒病 2019(COVID-19)已造成 600 多万人死亡,并在全球范围内造成了破坏性的社会和经济影响。由于疫苗和自然免疫力的丧失以及传播性的增强,新变异株(VOCs)的出现是一项艰巨的挑战。所有 VOCs 都含有突变的尖峰糖蛋白,它介导病毒和宿主细胞膜之间的融合。尖峰糖蛋白通过其受体结合域(RBD)与血管紧张素转换酶 2(ACE2)结合,启动感染过程。为了了解 RBD 突变对 VOC 的影响,很多人关注 RBD 与 ACE2 的相互作用。然而,这类分析忽略了更多的间接影响,如 RBD 本身的构象动力学。观察到一些突变发生在与 ACE2 没有直接接触的残基上,我们假设它们可能会影响 RBD 的构象动力学。为了验证这一点,我们进行了长原子(AA)分子动力学(MD)模拟,以研究 wt RBD 和四种 VOC(Alpha、Beta、Delta 和 Omicron)的结构动力学。我们的结果表明,wt RBD 呈现出两种不同的构象:一种是 "开放 "构象,它可以自由地与 ACE2 结合;另一种是 "封闭 "构象,RBM 脊阻挡了结合表面。阿尔法和贝塔变体将开放/封闭平衡向开放构象移动了大约 20%,从而可能增加 ACE2 的结合亲和力。对 Delta 和 Omicron 变体的模拟显示出极端的结果,很少观察到封闭构象。德尔塔变体与其他变体也有很大不同,它在开放构象和另一种 "反向 "构象之间交替出现,RBM脊的方向发生了显著变化。这种交替构象可能会增加 ACE2 结合的可用性,并通过表位闭塞帮助抗体逃逸,从而提供体能优势。这些结果支持了这样的假设:VOCs,尤其是 Omicron 和 Delta 变体,会影响 RBD 的构象动力学,从而促进与 ACE2 的有效结合,而在 Delta 的情况下,可能有助于抗体的逃避。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

SARS-CoV-2 variants impact RBD conformational dynamics and ACE2 accessibility.

SARS-CoV-2 variants impact RBD conformational dynamics and ACE2 accessibility.

SARS-CoV-2 variants impact RBD conformational dynamics and ACE2 accessibility.

SARS-CoV-2 variants impact RBD conformational dynamics and ACE2 accessibility.

Coronavirus disease 2019 (COVID-19), caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has killed over 6 million people and is having a devastating social and economic impact around the world. The rise of new variants of concern (VOCs) represents a difficult challenge due to the loss of vaccine and natural immunity, as well as increased transmissibility. All VOCs contain mutations in the spike glycoprotein, which mediates fusion between the viral and host cell membranes. The spike glycoprotein binds to angiotensin-converting enzyme 2 (ACE2) via its receptor binding domain (RBD) initiating the infection process. Attempting to understand the effect of RBD mutations in VOCs, a lot of attention has been given to the RBD-ACE2 interaction. However, this type of analysis ignores more indirect effects, such as the conformational dynamics of the RBD itself. Observing that some mutations occur in residues that are not in direct contact with ACE2, we hypothesized that they could affect the RBD conformational dynamics. To test this, we performed long atomistic (AA) molecular dynamics (MD) simulations to investigate the structural dynamics of wt RBD, and that of four VOCs (Alpha, Beta, Delta, and Omicron). Our results show that the wt RBD presents two distinct conformations: an "open" conformation where it is free to bind ACE2; and a "closed" conformation, where the RBM ridge blocks the binding surface. The Alpha and Beta variants shift the open/closed equilibrium towards the open conformation by roughly 20%, likely increasing ACE2 binding affinity. Simulations of the Delta and Omicron variants showed extreme results, with the closed conformation being rarely observed. The Delta variant also differed substantially from the other variants, alternating between the open conformation and an alternative "reversed" one, with a significantly changed orientation of the RBM ridge. This alternate conformation could provide a fitness advantage due to increased availability for ACE2 binding, and by aiding antibody escape through epitope occlusion. These results support the hypothesis that VOCs, and particularly the Omicron and Delta variants, impact RBD conformational dynamics in a direction that promotes efficient binding to ACE2 and, in the case of Delta, may assist antibody escape.

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