Impact of subtype C-specific amino acid variants on HIV-1 Tat-TAR interaction: insights from molecular modelling and dynamics.

IF 4 3区医学 Q2 VIROLOGY Virology Journal Pub Date : 2024-06-25 DOI:10.1186/s12985-024-02419-6

Piwai T Gotora, Keaghan Brown, Darius R Martin, Rencia van der Sluis, Ruben Cloete, Monray E Williams

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Abstract

Background: HIV-1 produces Tat, a crucial protein for transcription, viral replication, and CNS neurotoxicity. Tat interacts with TAR, enhancing HIV reverse transcription. Subtype C Tat variants (C31S, R57S, Q63E) are associated with reduced transactivation and neurovirulence compared to subtype B. However, their precise impact on Tat-TAR binding is unclear. This study investigates how these substitutions affect Tat-TAR interaction.

Methods: We utilized molecular modelling techniques, including MODELLER, to produce precise three-dimensional structures of HIV-1 Tat protein variants. We utilized Tat subtype B as the reference or wild type, and generated Tat variants to mirror those amino acid variants found in Tat subtype C. Subtype C-specific amino acid substitutions were selected based on their role in the neuropathogenesis of HIV-1. Subsequently, we conducted molecular docking of each Tat protein variant to TAR using HDOCK, followed by molecular dynamic simulations.

Results: Molecular docking results indicated that Tat subtype B (TatWt) showed the highest affinity for the TAR element (-262.07), followed by TatC31S (-261.61), TatQ63E (-256.43), TatC31S/R57S/Q63E (-238.92), and TatR57S (-222.24). However, binding free energy analysis showed higher affinities for single variants TatQ63E (-349.2 ± 10.4 kcal/mol) and TatR57S (-290.0 ± 9.6 kcal/mol) compared to TatWt (-247.9 ± 27.7 kcal/mol), while TatC31S and TatC31S/R57SQ/63E showed lower values. Interactions over the protein trajectory were also higher for TatQ63E and TatR57S compared to TatWt, TatC31S, and TatC31S/R57SQ/63E, suggesting that modifying amino acids within the Arginine/Glutamine-rich region notably affects TAR interaction. Single amino acid mutations TatR57S and TatQ63E had a significant impact, while TatC31S had minimal effect. Introducing single amino acid variants from TatWt to a more representative Tat subtype C (TatC31S/R57SQ/63E) resulted in lower predicted binding affinity, consistent with previous findings.

Conclusions: These identified amino acid positions likely contribute significantly to Tat-TAR interaction and the differential pathogenesis and neuropathogenesis observed between subtype B and subtype C. Additional experimental investigations should prioritize exploring the influence of these amino acid signatures on TAR binding to gain a comprehensive understanding of their impact on viral transactivation, potentially identifying them as therapeutic targets.

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C 亚型特异性氨基酸变体对 HIV-1 Tat-TAR 相互作用的影响：分子建模和动力学的启示。

背景：HIV-1 产生 Tat，这是一种对转录、病毒复制和中枢神经系统神经毒性至关重要的蛋白质。Tat 与 TAR 相互作用，增强了 HIV 的逆转录。与 B 亚型相比，C 亚型 Tat 变异（C31S、R57S、Q63E）与转录活性降低和神经毒性降低有关。本研究调查了这些取代如何影响 Tat-TAR 的相互作用：我们利用分子建模技术（包括 MODELLER）制作了 HIV-1 Tat 蛋白变体的精确三维结构。我们利用 B 亚型 Tat 作为参考或野生型，并生成了 Tat 变体，以反映 C 亚型 Tat 中发现的氨基酸变体。C 亚型特异性氨基酸取代是根据它们在 HIV-1 神经发病机制中的作用而选择的。随后，我们使用 HDOCK 对每个 Tat 蛋白变体与 TAR 进行了分子对接，然后进行了分子动力学模拟：分子对接结果表明，Tat B亚型（TatWt）与TAR元件的亲和力最高（-262.07），其次是TatC31S（-261.61）、TatQ63E（-256.43）、TatC31S/R57S/Q63E（-238.92）和TatR57S（-222.24）。然而，结合自由能分析表明，与 TatWt（-247.9 ± 27.7 kcal/mol）相比，单一变体 TatQ63E（-349.2 ± 10.4 kcal/mol）和 TatR57S（-290.0 ± 9.6 kcal/mol）的亲和力较高，而 TatC31S 和 TatC31S/R57SQ/63E 的亲和力值较低。与 TatWt、TatC31S 和 TatC31S/R57SQ/63E 相比，TatQ63E 和 TatR57S 在蛋白质轨迹上的相互作用也更高，这表明修饰精氨酸/谷氨酰胺富集区内的氨基酸会显著影响 TAR 的相互作用。单个氨基酸突变 TatR57S 和 TatQ63E 有显著影响，而 TatC31S 影响甚微。将 TatWt 的单个氨基酸变异引入更具代表性的 Tat 亚型 C（TatC31S/R57SQ/63E）会导致预测的结合亲和力降低，这与之前的研究结果一致：其他实验研究应优先探索这些氨基酸特征对 TAR 结合的影响，以全面了解它们对病毒反式激活的影响，并有可能将它们确定为治疗靶点。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Virology Journal 医学-病毒学

CiteScore

7.40

自引率

2.10%

发文量

186

审稿时长

1 months

期刊介绍： Virology Journal is an open access, peer reviewed journal that considers articles on all aspects of virology, including research on the viruses of animals, plants and microbes. The journal welcomes basic research as well as pre-clinical and clinical studies of novel diagnostic tools, vaccines and anti-viral therapies. The Editorial policy of Virology Journal is to publish all research which is assessed by peer reviewers to be a coherent and sound addition to the scientific literature, and puts less emphasis on interest levels or perceived impact.