Paige R. Gruenke, Miles D. Mayer, Rachna Aneja, William J. Schulze, Zhenwei Song, Donald H. Burke, Xiao Heng and Margaret J. Lange*,
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引用次数: 0
摘要
HIV-1 的帽状蛋白(CA)在复制过程中呈现出不同的结构形式,每种结构形式都呈现出独特的、可溶解的表面,从而促进了多方面的功能和宿主因子的相互作用。然而,由于对 CA 的评估存在若干技术难题,因此个别 CA 结构的功能贡献仍不清楚。为了填补这一知识空白,我们利用先前选定的能结合 CA 六聚体晶格的适配体文库,通过分支 SELEX 方法鉴定出了具有不同结构特异性的 CA 靶向适配体。这些子集要么对 CA 晶格具有高度特异性,要么同时与 CA 晶格和 CA 六聚体结合。然后,我们评估了四种代表物,揭示了结合所需的适配体区域,突出了有趣的结构特征和确定适配体结构所面临的挑战。此外,我们还展示了与生物学相关的 CA 结构形式的结合,以及在不对病毒或宿主进行修饰的情况下,由适配体介导的从细胞裂解液中亲和性纯化 CA 的过程,从而支持了结构形式特异性适配体的发展,使其成为研究 CA 的令人兴奋的新工具。
A Branched SELEX Approach Identifies RNA Aptamers That Bind Distinct HIV-1 Capsid Structural Components
The HIV-1 capsid protein (CA) assumes distinct structural forms during replication, each presenting unique, solvent-accessible surfaces that facilitate multifaceted functions and host factor interactions. However, functional contributions of individual CA structures remain unclear, as evaluation of CA presents several technical challenges. To address this knowledge gap, we identified CA-targeting aptamers with different structural specificities, which emerged through a branched SELEX approach using an aptamer library previously selected to bind the CA hexamer lattice. Subsets were either highly specific for the CA lattice or bound both the CA lattice and CA hexamer. We then evaluated four representatives to reveal aptamer regions required for binding, highlighting interesting structural features and challenges in aptamer structure determination. Further, we demonstrate binding to biologically relevant CA structural forms and aptamer-mediated affinity purification of CA from cell lysates without virus or host modification, supporting the development of structural form-specific aptamers as exciting new tools for the study of CA.
期刊介绍:
ACS Infectious Diseases will be the first journal to highlight chemistry and its role in this multidisciplinary and collaborative research area. The journal will cover a diverse array of topics including, but not limited to:
* Discovery and development of new antimicrobial agents — identified through target- or phenotypic-based approaches as well as compounds that induce synergy with antimicrobials.
* Characterization and validation of drug target or pathways — use of single target and genome-wide knockdown and knockouts, biochemical studies, structural biology, new technologies to facilitate characterization and prioritization of potential drug targets.
* Mechanism of drug resistance — fundamental research that advances our understanding of resistance; strategies to prevent resistance.
* Mechanisms of action — use of genetic, metabolomic, and activity- and affinity-based protein profiling to elucidate the mechanism of action of clinical and experimental antimicrobial agents.
* Host-pathogen interactions — tools for studying host-pathogen interactions, cellular biochemistry of hosts and pathogens, and molecular interactions of pathogens with host microbiota.
* Small molecule vaccine adjuvants for infectious disease.
* Viral and bacterial biochemistry and molecular biology.
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