Developing peptide-based fusion inhibitors as an antiviral strategy utilizing coronin 1 as a template.

IF 4.1 4区 医学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY RSC medicinal chemistry Pub Date : 2024-10-02 DOI:10.1039/d4md00523f
Manbit Subhadarsi Panda, Bushra Qazi, Vaishali Vishwakarma, Gourab Prasad Pattnaik, Sourav Haldar, Hirak Chakraborty
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Abstract

Enveloped viruses enter the host cells by endocytosis and subsequently fuse with the endosomal membranes, or fuse with the plasma membrane at the cell surface. The crucial stage of viral infection, regardless of the route taken to enter the host cell, is membrane fusion. The present work aims to develop a peptide-based fusion inhibitor that prevents membrane fusion by modifying the properties of the participating membranes, without targeting a protein. This would allow us to develop a fusion inhibitor that might work against a larger spectrum of enveloped viruses as it does not target any specific viral fusion protein. With this goal in mind, we have designed a novel peptide by modifying a native sequence derived from coronin 1, a phagosomal protein, that helps to avoid lysosomal degradation of mycobacterium-loaded phagosomes. The designed peptide, mTG-23, inhibits ∼30-40% fusion between small unilamellar vesicles containing varying amounts of cholesterol by modulating the biophysical properties of the participating bilayers. As a proof of principle, we have further demonstrated that the mTG-23 inhibits Influenza A virus infection in A549 and MDCK cells (with ∼EC50 of 20.45 μM and 21.55 μM, respectively), where viral envelope and endosomal membrane fusion is a crucial step. Through a gamut of biophysical and biochemical methods, we surmise that mTG-23 inhibits viral infection by inhibiting viral envelope and endosomal membrane fusion. We envisage that the proposed antiviral strategy can be extended to other viruses that employ a similar modus operandi, providing a novel pan-antiviral approach.

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以冠状病毒素 1 为模板,开发多肽融合抑制剂作为抗病毒策略。
包膜病毒通过内吞作用进入宿主细胞,随后与内体膜融合,或在细胞表面与质膜融合。无论通过哪种途径进入宿主细胞,膜融合都是病毒感染的关键阶段。目前的工作旨在开发一种基于多肽的融合抑制剂,这种抑制剂通过改变参与膜的特性来阻止膜融合,而不以蛋白质为目标。由于不针对任何特定的病毒融合蛋白,这将使我们开发的融合抑制剂可能对更多的包膜病毒有效。带着这一目标,我们设计了一种新型多肽,它修改了源自吞噬体蛋白冠状蛋白 1 的原生序列,有助于避免分枝杆菌负载的吞噬体被溶酶体降解。所设计的多肽 mTG-23 可通过调节参与双层膜的生物物理特性,抑制含有不同数量胆固醇的单层小囊泡之间 30% 至 40% 的融合。作为原理证明,我们进一步证实了 mTG-23 能抑制甲型流感病毒在 A549 和 MDCK 细胞中的感染(EC50 分别为 20.45 μM 和 21.55 μM),而病毒包膜和内体膜的融合是病毒感染的关键步骤。通过各种生物物理和生物化学方法,我们推测 mTG-23 是通过抑制病毒包膜和内体膜融合来抑制病毒感染的。我们设想所提出的抗病毒策略可以扩展到采用类似工作方式的其他病毒,从而提供一种新型的泛抗病毒方法。
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来源期刊
CiteScore
5.80
自引率
2.40%
发文量
129
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