Effect of Protein Environment on the Shape Resonances of RNA Nucleobases: Insights from a Model System

We have investigated the effect of amino acid environment on the nucleobase-centered anionic shape resonances in RNA by employing uracil as a model system. Uracil-glycine complexes have been used to model the RNA-protein interactions, and with glycine to model the proximity of amino acid residues to RNA nucleobases. The resonance positions and widths of the complexes have been simulated using the equation of motion coupled cluster method coupled with resonance via Pad\'e approach. The amino acid stabilizes the nucleobase-centered resonances through hydrogen bonding, increasing their lifetime. At the same time, the amino acid-centered resonances strongly couple with the nucleobase-centered resonances, thereby scavenging the electron density away from the nucleobase. At the micro-solvation level, amino acids have a greater influence on nucleobase-centered resonances than that displayed by the aqueous environment.