Abstract

The Chili RNA aptamer is a 52 nt long fluorogen-activating RNA aptamer (FLAP) that confers fluorescence to structurally diverse derivatives of fluorescent protein chromophores. A key feature of Chili is the formation of highly stable complexes with different ligands, which exhibit bright, highly Stokes-shifted fluorescence emission. In this work, we have analyzed the interactions between the Chili RNA and a family of conditionally fluorescent ligands using a variety of spectroscopic, calorimetric and biochemical techniques to reveal key structure–fluorescence activation relationships (SFARs). The ligands under investigation form two categories with emission maxima of ∼540 or ∼590 nm, respectively, and bind with affinities in the nanomolar to low-micromolar range. Isothermal titration calorimetry was used to elucidate the enthalpic and entropic contributions to binding affinity for a cationic ligand that is unique to the Chili aptamer. In addition to fluorescence activation, ligand binding was also observed by NMR spectroscopy, revealing characteristic signals for the formation of a G-quadruplex only upon ligand binding. These data shed light on the molecular features required and responsible for the large Stokes shift and the strong fluorescence enhancement of red and green emitting RNA–chromophore complexes.

Highlights

  • In the wake of the seminal report of the Spinach RNA aptamer [1], fluorogen-activating aptamers (FLAPs) have found their footing as biochemical tools for studying RNA in vitro and in cells

  • The fluorogenic RNA aptamer Chili was investigated for its ability to activate the fluorescence of thirty-six differently substituted HBI chromophores

  • The dye structures were inspired by chromophores found in fluorescent proteins, and were synthetically obtained using a cycloaddition-based strategy, which in most cases gave more reliable results than the Erlenmeyer azlactone route

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Summary

Introduction

In the wake of the seminal report of the Spinach RNA aptamer [1], fluorogen-activating aptamers (FLAPs) have found their footing as biochemical tools for studying RNA in vitro and in cells. Spinach contains a U–A–U base triple on top of a G-quartet with the ligand intercalated in between the two layers [24,27,28] Such a base triple is absent in Corn, which forms a homodimer that encloses the ligand at the interface of the two individual quadruplexes [29]. In both aptamers a confined environment is created that decreases the nonradiative deactivation rate of bound photoexcited HBI and results in a significant fluorescence turn-on

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