预灌注特异性抗体衍生肽三价呈现在dna纳米支架上,作为一种抗RSV进入的创新策略

IF 2 Q4 VIROLOGY
Leila Issmail, C. Möser, Christian Jäger, Basma Altattan, D. Ramsbeck, M. Kleinschmidt, Mirko Buchholz, David Smith, T. Grunwald
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引用次数: 1

摘要

人呼吸道合胞病毒(RSV)是全球儿童和老年人急性下呼吸道感染的主要原因,目前尚无疫苗或有效疗法获批准。RSV进入宿主细胞是通过表面RSV融合(RSV- f)糖蛋白的逐步结构变化介导的。RSV-F糖蛋白结构和功能研究的最新进展揭示了构象依赖性中和表位,这些表位已成为疫苗和治疗开发的有吸引力的靶点。由于RSV-F以三聚体形式存在于病毒表面,候选融合抑制剂与三种单体上各自的表位之间的三价结合相互作用有望以比单价或二价抑制剂更高的效力预防病毒感染。在这里,我们展示了一种新的RSV进入抑制方法,通过实施三聚体DNA纳米结构作为模板,显示多达三个线性肽片段,同时靶向预融合RSV- f蛋白表面的表位。为了设计可以与DNA纳米结构偶联的合成结合肽,我们选择了rsv - f特异性单克隆抗体(D25)。互补决定区3 (CDR3)衍生的肽经过截断和丙氨酸扫描诱变分析,然后使用非规范氨基酸进行系统的序列修饰。最有效的候选肽被用作DNA纳米结构功能化的结合片段。所设计的DNA肽结构能够比单体肽更有效地阻断细胞上的RSV感染,然而,在感染小鼠的肺部观察到鼻内应用后病毒载量的更适度减少,可能是由于肺部细胞对潜在DNA结构的解离或吸收。综上所述,我们的研究结果指出了一种新的基于三聚体dna肽的方法对RSV的抑制潜力,并为将该平台应用于其他病毒感染打开了可能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Prefusion-specific antibody-derived peptides trivalently presented on DNA-nanoscaffolds as an innovative strategy against RSV entry
Human respiratory syncytial virus (RSV) is the primary cause of acute lower respiratory tract infections in children and the elderly worldwide, for which neither a vaccine nor an effective therapy is approved. The entry of RSV into the host cell is mediated by stepwise structural changes in the surface RSV fusion (RSV-F) glycoprotein. Recent progress in structural and functional studies of RSV-F glycoprotein revealed conformation-dependent neutralizing epitopes which have become attractive targets for vaccine and therapeutic development. As RSV-F is present on viral surface in a trimeric form, a trivalent binding interaction between a candidate fusion inhibitor and the respective epitopes on each of the three monomers is expected to prevent viral infection at higher potency than a monovalent or bivalent inhibitor. Here we demonstrate a novel RSV entry inhibitory approach by implementing a trimeric DNA nanostructure as a template to display up to three linear peptide moieties that simultaneously target an epitope on the surface of the prefusion RSV-F protein. In order to design synthetic binding peptides that can be coupled to the DNA nanostructure, the prefusion RSV-F-specific monoclonal antibody (D25) was selected. Complementarity-determining region 3 (CDR3) derived peptides underwent truncation and alanine-scanning mutagenesis analysis, followed by systematic sequence modifications using non-canonical amino acids. The most effective peptide candidate was used as a binding moiety to functionalize the DNA nanostructure. The designed DNA-peptide construct was able to block RSV infection on cells more efficiently than the monomeric peptides, however a more moderate reduction of viral load was observed in the lungs of infected mice upon intranasal application, likely due to dissociation or absorption of the underlying DNA structure by cells in the lungs. Taken together, our results point towards the inhibitory potential of a novel trimeric DNA-peptide based approach against RSV and open the possibility to apply this platform to target other viral infections.
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