Design of Artificial C-Peptides as Potential Anti-HIV-1 Inhibitors Based on 6-HB Formation Mechanism.

IF 1 4区生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Protein and Peptide Letters Pub Date : 2024-01-01 DOI:10.2174/0109298665312274240530060233

Hui Luo, Yan Zhao, Yuheng Ma, Guodong Liang, Lu Ga, Zhao Meng

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引用次数: 0

Abstract

Background: The six-helix bundle (6-HB) is a core structure formed during the membrane fusion process of viruses with the Class I envelope proteins. Peptide inhibitors, including the marketed Enfuvirtide, blocking the membrane fusion to exert inhibitory activity were designed based on the heptads repeat interactions in 6-HB. However, the drawbacks of Enfuvirtide, such as drug resistance and short half-life in vivo, have been confirmed in clinical applications. Therefore, novel design strategies are pivotal in the development of next-generation peptide-based fusion inhibitors.

Objective: The de novo design of α-helical peptides against MERS-CoV and IAVs has successfully expedited the development of fusion inhibitors. The reported sequences were completely nonhomologous with natural peptides, which can provide some inspirations for the antiviral design against other pathogenic viruses with class I fusion proteins. Here, we design a series of artificial C-peptides based on the similar mechanism of 6-HB formation and general rules of heptads repeat interaction.

Methods: The inhibitory activity of peptides against HIV-1 was assessed by HIV-1 Env-mediated cell-cell fusion assays. Interaction between artificial C-peptides and target peptides was evaluated by circular dichroism, polyacrylamide gel electrophoresis, size-exclusion chromatography, and sedimentation velocity analysis. Molecular docking studies were performed by using Schrödinger molecular modelling software.

Results: The best-performing artificial C-peptide, 1SR, was highly active against HIV-1 env-mediated cell-cell fusion. 1SR binds to the gp41 NHR region, assembling polymer to prevent endogenous 6-HB formation.

Conclusion: We have found an artificial C-lipopeptide lead compound with inhibitory activity against HIV-1. Also, this paper enriched both N- and C-teminal heptads repeat interaction rules in 6-HB and provided an effective idea for next-generation peptide-based fusion inhibitors against HIV-1.

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基于 6-HB 形成机制设计人工 C 肽作为潜在的抗 HIV-1 抑制剂

背景：六螺旋束（6-HB）是病毒与 I 类包膜蛋白膜融合过程中形成的核心结构。根据 6-HB 中的七元重复相互作用设计出了阻断膜融合以发挥抑制活性的肽抑制剂，包括已上市的恩夫韦肽。然而，恩夫韦肽的耐药性和体内半衰期短等缺点已在临床应用中得到证实。因此，新颖的设计策略对于开发基于多肽的下一代融合抑制剂至关重要：目的：针对 MERS-CoV 和 IAV 的 α 螺旋多肽的全新设计成功加快了融合抑制剂的开发。所报道的序列与天然肽完全非同源，这可以为针对其他具有 I 类融合蛋白的致病病毒的抗病毒设计提供一些启发。在此，我们根据 6-HB 形成的相似机制和七联重复相互作用的一般规则设计了一系列人工 C 肽：方法：通过 HIV-1 Env 介导的细胞-细胞融合试验评估肽对 HIV-1 的抑制活性。通过圆二色性、聚丙烯酰胺凝胶电泳、尺寸排阻色谱和沉降速度分析评估了人工 C 肽和目标肽之间的相互作用。使用薛定谔分子建模软件进行了分子对接研究：结果：性能最好的人工 C 肽 1SR 对 HIV-1 env 介导的细胞-细胞融合具有高度活性。1SR 与 gp41 NHR 区域结合，形成聚合物，阻止内源性 6-HB 的形成：结论：我们发现了一种具有抑制 HIV-1 活性的人工 C-脂肽先导化合物。结论：我们发现了一种对 HIV-1 具有抑制活性的人工 C 脂肽先导化合物，并丰富了 6-HB 中 N 端和 C 端七肽重复相互作用的规则，为下一代基于多肽的 HIV-1 融合抑制剂提供了有效的思路。

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来源期刊

Protein and Peptide Letters 生物-生化与分子生物学

CiteScore

2.90

自引率

0.00%

发文量

审稿时长

2 months

期刊介绍： Protein & Peptide Letters publishes letters, original research papers, mini-reviews and guest edited issues in all important aspects of protein and peptide research, including structural studies, advances in recombinant expression, function, synthesis, enzymology, immunology, molecular modeling, and drug design. Manuscripts must have a significant element of novelty, timeliness and urgency that merit rapid publication. Reports of crystallization and preliminary structure determination of biologically important proteins are considered only if they include significant new approaches or deal with proteins of immediate importance, and preliminary structure determinations of biologically important proteins. Purely theoretical/review papers should provide new insight into the principles of protein/peptide structure and function. Manuscripts describing computational work should include some experimental data to provide confirmation of the results of calculations. Protein & Peptide Letters focuses on: Structure Studies Advances in Recombinant Expression Drug Design Chemical Synthesis Function Pharmacology Enzymology Conformational Analysis Immunology Biotechnology Protein Engineering Protein Folding Sequencing Molecular Recognition Purification and Analysis