通过表面等离子体共振结合参考减除技术定量分析 RNA-配体相互作用。

RNA-Ligand Interactions Quantified by Surface Plasmon Resonance with Reference Subtraction.

机构信息

Department of Chemistry, University of North Carolina, Chapel Hill, North Carolina 27599-3290, United States.

出版信息

Biochemistry. 2022 Aug 2;61(15):1625-1632. doi: 10.1021/acs.biochem.2c00177. Epub 2022 Jul 8.

DOI:10.1021/acs.biochem.2c00177

PMID:35802500

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9357220/

Abstract

Structured RNAs bind ligands and are attractive targets for small-molecule drugs. A wide variety of analytical methods have been used to characterize RNA-ligand interactions, but our experience is that most have significant limitations in terms of material requirements and applicability to complex RNAs. Surface plasmon resonance (SPR) potentially overcomes these limitations, but we find that the standard experimental framework measures notable nonspecific electrostatic-mediated interactions, frustrating analysis of weak RNA binders. SPR measurements are typically quantified relative to a non-target reference channel. Here, we show that referencing to a channel containing a non-binding control RNA enables subtraction of nonspecific binding contributions, allowing measurements of accurate and specific binding affinities. We validated this approach for small-molecule binders of two riboswitch RNAs with affinities ranging from nanomolar to millimolar, including low-molecular-mass fragment ligands. SPR implemented with reference subtraction reliably discriminates specific from nonspecific binding, uses RNA and ligand material efficiently, and enables rapid exploration of the ligand-binding landscape for RNA targets.

摘要

结构 RNA 可结合配体，是小分子药物的理想靶点。已经有许多分析方法被用于研究 RNA-配体的相互作用，但我们的经验表明，这些方法在材料要求和对复杂 RNA 的适用性方面都存在很大的局限性。表面等离子体共振（SPR）可能克服了这些限制，但我们发现标准的实验框架会显著测量到非特异性的静电介导的相互作用，从而阻碍了对弱 RNA 结合物的分析。SPR 测量通常相对于非靶参考通道进行定量。在这里，我们证明了参考包含非结合对照 RNA 的通道可以减去非特异性结合的贡献，从而可以测量准确和特定的结合亲和力。我们通过两种具有从纳摩尔到毫摩尔范围亲和力的核糖开关 RNA 的小分子配体验证了这种方法，包括低分子量的片段配体。采用参考减法的 SPR 能够可靠地区分特异性结合和非特异性结合，高效地使用 RNA 和配体材料，并能够快速探索 RNA 靶标的配体结合景观。

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