Abstract
In this work an improved stable isotope labeling protocol for nucleic acids is introduced. The novel building blocks eliminate/minimize homonuclear 13C and 1H scalar couplings thus allowing proton relaxation dispersion (RD) experiments to report accurately on the chemical exchange of nucleic acids. Using site‐specific 2H and 13C labeling, spin topologies are introduced into DNA and RNA that make 1H relaxation dispersion experiments applicable in a straightforward manner. The novel RNA/DNA building blocks were successfully incorporated into two nucleic acids. The A‐site RNA was previously shown to undergo a two site exchange process in the micro‐ to millisecond time regime. Using proton relaxation dispersion experiments the exchange parameters determined earlier could be recapitulated, thus validating the proposed approach. We further investigated the dynamics of the cTAR DNA, a DNA transcript that is involved in the viral replication cycle of HIV‐1. Again, an exchange process could be characterized and quantified. This shows the general applicablility of the novel labeling scheme for 1H RD experiments of nucleic acids.
Highlights
Michael Andreas Juen+, Christoph Hermann Wunderlich+, Felix Nußbaumer, Martin Tollinger, Georg Kontaxis, Robert Konrat, D
Using site-specific 2H and 13C labeling, spin topologies are introduced into DNA and RNA that make 1H relaxation dispersion experiments applicable in a straightforward manner
The novel RNA/DNA building blocks were successfully incorporated into two nucleic acids
Summary
Michael Andreas Juen+, Christoph Hermann Wunderlich+, Felix Nußbaumer, Martin Tollinger, Georg Kontaxis, Robert Konrat, D. The novel building blocks eliminate/minimize homonuclear 13C and 1H scalar couplings allowing proton relaxation dispersion (RD) experiments to report accurately on the chemical exchange of nucleic acids.
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