Joshua M. Blose

Contribution of the Closing Base Pair to Exceptional Stability in RNA Tetraloops: Roles for Molecular Mimicry and Electrostatic Factors

Hairpins are common RNA secondary structures that play multiple roles in nature. Tetraloops are the most frequent RNA hairpin loops and are often phylogenetically conserved. For both the UNCG and GNRA families, CG closing base pairs (cbps) confer exceptional thermodynamic stability but the molecular basis for this has remained unclear. We propose that, despite having very different overall folds, these two tetraloop families achieve stability by presenting the same functionalities to the major groove edge of the CG cbp. Thermodynamic contributions of this molecular mimicry were investigated using substitutions at the nucleobase and functional group levels. By either interrupting or deleting loop-cbp electrostatic interactions, which were identified by solving the nonlinear Poisson-Boltzmann (NLPB) equation, stability changed in a manner consistent with molecular mimicry. We also observed a linear relationship between DeltaG(o)(37) and log[Na(+)] for both families, and loops with a CG cbp had a decreased dependence of stability on salt. NLPB calculations revealed that, for both UUCG and GAAA tetraloops, the GC cbp form has a higher surface charge density, although it arises from changes in loop compaction for UUCG and changes in loop configuration for GAAA. Higher surface charge density leads to stronger interactions of GC cbp loops with solvent and salt, which explains the correlation between experimental and calculated trends of free energy with salt. Molecular mimicry as evidenced in these two stable but otherwise unrelated tetraloops may underlie common functional roles in other RNA and DNA motifs.

Effects of a Protecting Osmolyte on The Ion Atmosphere Surrounding DNA Duplexes

Osmolytes are small, chemically diverse, organic solutes that function as an essential component of cellular stress response. Protecting osmolytes enhance protein stability via preferential exclusion, and nonprotecting osmolytes, such as urea, destabilize protein structures. Although much is known about osmolyte effects on proteins, less is understood about osmolyte effects on nucleic acids and their counterion atmospheres. Nonprotecting osmolytes destabilize nucleic acid structures, but effects of protecting osmolytes depend on numerous factors including the type of nucleic acid and the complexity of the functional fold. To begin quantifying protecting osmolyte effects on nucleic acid interactions, we used small-angle X-ray scattering (SAXS) techniques to monitor DNA duplexes in the presence of sucrose. This protecting osmolyte is a commonly used contrast matching agent in SAXS studies of protein-nucleic acid complexes; thus, it is important to characterize interaction changes induced by sucrose. Measurements of interactions between duplexes showed no dependence on the presence of up to 30% sucrose, except under high Mg(2+) conditions where stacking interactions were disfavored. The number of excess ions associated with DNA duplexes, reported by anomalous small-angle X-ray scattering (ASAXS) experiments, was sucrose independent. Although protecting osmolytes can destabilize secondary structures, our results suggest that ion atmospheres of individual duplexes remain unperturbed by sucrose.

Portability of the GN(R)A Hairpin Loop Motif between RNA and DNA

Hairpins are common nucleic acid secondary structures that serve many structural and functional roles. Recently, we reported that r(UNCG) and r(GNRA) hairpin families use molecular mimicry and electrostatic factors to attain exceptional thermodynamic stability with a CG closing base pair (cbp). Despite having very different overall folds, these tetraloops present the same functionalities and partial charges to the major groove edge of the CG cbp to achieve stability. Herein, we compare the r(GNRA) tetraloop family to the DNA triloop family d(GNA), which is also exceptionally stable with a CG cbp and possesses the same base pairing between the first and last positions of the loop. Nucleobase and functional group modifications were used to investigate interactions of d(GNA) loops with the cbp, which provided for comparison with similar substitutions in r(GNRA) hairpins. Interruption or deletion of loop-cbp interactions in d(GNA) was consistent with electrostatic interactions identified through nonlinear Poisson-Boltzmann (NLPB) calculations, and loop stability changed in a manner consistent with similar loop-cbp interactions for d(GNA) and r(GNRA) loops. We also compared the relationship of DeltaG degrees (37) and log[Na+] for d(GNA) and r(GNRA) loops and found a decreased dependence of stability on salt for both loop families when a CG cbp was present. The similarity of the loop-cbp interactions shows portability of this loop-cbp motif across polymer type and loop size and indicates convergence on similar molecular solutions for stability in RNA and DNA.

The Influence of Osmolytes on Electrostatic Interactions Among DNA Duplexes

Osmolytes, which function as a vital component of the cellular stress response, are small, chemically diverse, intracellular organic solutes. Protecting osmolytes enhance protein stability via preferential exclusion, where denaturation of the protein in the presence of the osmolyte is less favorable than in an aqueous environment. Thus, the correct ratios of protecting to non-protecting osmolytes and protecting osmolytes to ions are critical to maintain protein structure and protein-nucleic acid interactions. In contrast to the effects of osmolytes on protein stability, structure, and function, there is much less understood concerning the effects of osmolytes on nucleic acids. Although non-protecting osmolytes can destabilize both protein and nucleic acid structures, protecting osmolytes have different effects depending on the complexity of the nucleic acid structure. Furthermore, the influence of osmolytes on the ion atmosphere surrounding nucleic acids is not well understood. As a first step in quantifying the effects of osmolytes on nucleic acid electrostatics we used small angle x-ray scattering (SAXS) techniques to monitor 25-bp DNA duplexes and their interactions in the presence and absence of sucrose, a protecting osmolyte and important contrast matching agent in SAXS studies of protein-nucleic acid complexes. Results will be discussed.