G-quadruplex formation in RNA aptamers selected for binding to HIV-1 capsid.

IF 3.8 3区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY
Frontiers in Chemistry Pub Date : 2024-10-22 eCollection Date: 2024-01-01 DOI:10.3389/fchem.2024.1425515
Miles D Mayer, Margaret J Lange
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引用次数: 0

Abstract

HIV-1 capsid protein (CA) is essential for viral replication and interacts with numerous host factors to facilitate successful infection. Thus, CA is an integral target for the study of virus-host dynamics and therapeutic development. The multifaceted functions of CA stem from the ability of CA to assemble into distinct structural components that come together to form the mature capsid core. Each structural component, including monomers, pentamers, and hexamers, presents a variety of solvent-accessible surfaces. However, the structure-function relationships of these components that facilitate replication and virus-host interactions have yet to be fully elucidated. A major challenge is the genetic fragility of CA, which precludes the use of many common methods. To overcome these constraints, we identified CA-targeting aptamers with binding specificity for either the mature CA hexamer lattice alone or both the CA hexamer lattice and soluble CA hexamer. To enable utilization of these aptamers as molecular tools for the study of CA structure-function relationships in cells, understanding the higher-order structures of these aptamers is required. While our initial work on a subset of aptamers included predictive and qualitative biochemical characterizations that provided insight into aptamer secondary structures, these approaches were insufficient for determining more complex non-canonical architectures. Here, we further clarify aptamer structural motifs using focused, quantitative biophysical approaches, primarily through the use of multi-effective spectroscopic methods and thermodynamic analyses. Aptamer L15.20.1 displayed particularly strong, unambiguous indications of stable RNA G-quadruplex (rG4) formation under physiological conditions in a region of the aptamer also previously shown to be necessary for CA-aptamer interactions. Non-canonical structures, such as the rG4, have distinct chemical signatures and interfaces that may support downstream applications without the need for complex modifications or labels that may negatively affect aptamer folding. Thus, aptamer representative L15.20.1, containing a putative rG4 in a region likely required for aptamer binding to CA with probable function under cellular conditions, may be a particularly useful tool for the study of HIV-1 CA.

经挑选与 HIV-1 外壳结合的 RNA 合体中 G 型四叠体的形成。
HIV-1 帽状蛋白(CA)对病毒复制至关重要,并与多种宿主因子相互作用以促进成功感染。因此,CA 是研究病毒-宿主动态和开发疗法不可或缺的目标。CA 的多方面功能源于其组装成不同结构成分的能力,这些结构成分组合在一起形成成熟的囊核。每种结构成分,包括单体、五聚体和六聚体,都呈现出各种可溶解的表面。然而,这些成分在促进复制和病毒与宿主相互作用方面的结构功能关系尚未完全阐明。一个主要挑战是 CA 的遗传脆弱性,这使得许多常用方法无法使用。为了克服这些限制,我们发现了对成熟 CA 六聚体晶格或 CA 六聚体晶格和可溶性 CA 六聚体都具有结合特异性的 CA 靶向适配体。要利用这些适配体作为研究细胞中 CA 结构与功能关系的分子工具,就必须了解这些适配体的高阶结构。虽然我们最初对一部分适配体进行的工作包括预测性和定性生化表征,这些表征有助于深入了解适配体的二级结构,但这些方法不足以确定更复杂的非规范结构。在这里,我们主要通过使用多效光谱方法和热力学分析,采用重点突出的定量生物物理方法进一步阐明了适配体的结构模式。适配体 L15.20.1 在生理条件下显示出特别强烈、明确的稳定 RNA G-四叠体(rG4)形成迹象,该适配体的一个区域以前也被证明是 CA-适配体相互作用所必需的。rG4 等非规范结构具有独特的化学特征和界面,可以支持下游应用,而不需要复杂的修饰或标签,因为它们可能对适配体的折叠产生负面影响。因此,具有代表性的适配体 L15.20.1,在一个可能需要适配体与 CA 结合的区域含有一个推定的 rG4,在细胞条件下可能具有功能,可能是研究 HIV-1 CA 的一个特别有用的工具。
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
Frontiers in Chemistry
Frontiers in Chemistry Chemistry-General Chemistry
CiteScore
8.50
自引率
3.60%
发文量
1540
审稿时长
12 weeks
期刊介绍: Frontiers in Chemistry is a high visiblity and quality journal, publishing rigorously peer-reviewed research across the chemical sciences. Field Chief Editor Steve Suib at the University of Connecticut is supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to academics, industry leaders and the public worldwide. Chemistry is a branch of science that is linked to all other main fields of research. The omnipresence of Chemistry is apparent in our everyday lives from the electronic devices that we all use to communicate, to foods we eat, to our health and well-being, to the different forms of energy that we use. While there are many subtopics and specialties of Chemistry, the fundamental link in all these areas is how atoms, ions, and molecules come together and come apart in what some have come to call the “dance of life”. All specialty sections of Frontiers in Chemistry are open-access with the goal of publishing outstanding research publications, review articles, commentaries, and ideas about various aspects of Chemistry. The past forms of publication often have specific subdisciplines, most commonly of analytical, inorganic, organic and physical chemistries, but these days those lines and boxes are quite blurry and the silos of those disciplines appear to be eroding. Chemistry is important to both fundamental and applied areas of research and manufacturing, and indeed the outlines of academic versus industrial research are also often artificial. Collaborative research across all specialty areas of Chemistry is highly encouraged and supported as we move forward. These are exciting times and the field of Chemistry is an important and significant contributor to our collective knowledge.
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