Nature's selection of the contemporary nucleobases in RNA and DNA continues to intrigue the origin of life community. While the prebiotic synthesis of the N-glycosyl bond has historically been a central area of investigation, variations in hydrolytic stabilities among the N-glycosyl bonds may have presented an additional selection pressure that contributed to nucleobase and nucleoside evolution. To experimentally probe this hypothesis, a systematic kinetic analysis of the hydrolytic deglycosylation reactions of modified, alternative and native nucleosides was undertaken. Rate constants were measured as a function of temperature (at pH 1) to produce Arrhenius and Eyring plots for extrapolation to 37°C and determination of thermodynamic activation parameters. Rate enhancements based on the differences in reaction rates of deoxyribo- and ribo-glycosidic bonds were found to vary under the same conditions. Rate constants of deoxynucleosides were also measured across the pH range of 1 - 3 (at 50°C), which highlighted how simple changes to the heterocycle alone can lead to significant variation in deglycosylation rates. The contemporary nucleosides exhibited the slowest deglycosylation rates in comparison to the non-native/alternative nucleosides, which we suggest as experimental support for nature's selection of the fittest N-glycosyl bonds.
Keywords: Chemical evolution; Genetic alphabet; RNA world; hydrolysis; nucleoside; prebiotic chemistry.