The Role of Counterion Valence and Size in GAAA Tetraloop–Receptor Docking/Undocking Kinetics

For RNA to fold into compact, ordered structures, it must overcome electrostatic repulsion between negatively charged phosphate groups by counterion recruitment. A physical understanding of the counterion-assisted folding process requires addressing how cations kinetically and thermodynamically cont...

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Bibliographic Details
Published in:Journal of molecular biology 2012-10, Vol.423 (2), p.198-216
Main Authors: Fiore, Julie L., Holmstrom, Erik D., Fiegland, Larry R., Hodak, Jose H., Nesbitt, David J.
Format: Article
Language:English
Subjects:
calcium
Cations
cobalt
counterion condensation
electrostatic interactions
energy transfer
fluorescence
Fluorescence Resonance Energy Transfer
ions
Kinetics
magnesium
neutralization
Nucleic Acid Conformation
potassium
RNA
RNA - chemistry
RNA - metabolism
RNA folding
single‐molecule FRET
sodium
tetraloop–receptor
Thermodynamics
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Summary:For RNA to fold into compact, ordered structures, it must overcome electrostatic repulsion between negatively charged phosphate groups by counterion recruitment. A physical understanding of the counterion-assisted folding process requires addressing how cations kinetically and thermodynamically control the folding equilibrium for each tertiary interaction in a full‐length RNA. In this work, single-molecule FRET (fluorescence resonance energy transfer) techniques are exploited to isolate and explore the cation-concentration‐dependent kinetics for formation of a ubiquitous RNA tertiary interaction, that is, the docking/undocking of a GAAA tetraloop with its 11‐nt receptor. Rate constants for docking (kdock) and undocking (kundock) are obtained as a function of cation concentration, size, and valence, specifically for the series Na+, K+, Mg2+, Ca2+, Co(NH3)63+, and spermidine3+. Increasing cation concentration accelerateskdockdramatically but achieves only a slight decrease in kundock. These results can be kinetically modeled using parallel cation-dependent and cation‐independent docking pathways, which allows for isolation of the folding kinetics from the interaction energetics of the cations with the undocked and docked states, respectively. This analysis reveals a preferential interaction of the cations with the transition state and docked state as compared to the undocked RNA, with the ion–RNA interaction strength growing with cation valence. However, the corresponding number of cations that are taken up by the RNA upon folding decreases with charge density of the cation. The only exception to these behaviors is spermidine3+, whose weaker influence on the docking equilibria with respect to Co(NH3)63+ can be ascribed to steric effects preventing complete neutralization of the RNA phosphate groups. [Display omitted] ► Single-molecule FRET study of cation-induced RNA folding. ► Kinetics of tetraloop–receptor docking/undocking versus cation valence and size. ► Increasing cation concentration accelerates docking and decelerates undocking. ► Cation valence is the primary determinant of efficacy in promoting RNA folding. ► Critical kinetic and thermodynamic benchmarks for cation-mediated RNA folding.
ISSN:0022-2836
1089-8638
DOI:10.1016/j.jmb.2012.07.006