5 Efficient and high-fidelity copying of an RNA-like model prebiotic system

Abstract

Nonenzymatic RNA replication would provide an important bridge to the RNA world. However, the demonstration of efficient and high-fidelity copying chemistry remains a great experimental challenge. It requires an efficient mechanism that can lead to both a high rate of polymerization and a high degree of fidelity in the copying chemistry. Previous experiments concerning nonenzymatic template-directed synthesis of RNA with activated monomers have led to the copying of short RNA templates, but these reactions are generally slow (taking days to weeks) and highly error-prone. Therefore, the ability to efficiently and accurately copy arbitrary template sequences remains frustratingly out of reach. N3′-P5′-linked phosphoramidate DNA is a highly reactive model for self-replicating genetic materials and has been used for studies of nonenzymatic RNA self-replication. It is also an excellent RNA mimic, due to its similar overall duplex structure, rigidity, and level of hydration (Tereshko, Gryaznov, & Egli, 1998). Our experiments show that the high reactivity imparted by the presence of an amino nucleophile allows rapid and efficient copying of all four nucleobases on both homopolymeric and mixed templates. On the other hand, G:T wobble pairing leads to a high error rate. We have, therefore, investigated the use of the modified nucleobase, 2-thio T (Ts) (Sintim & Kool, 2006), to suppress formation of the G:T wobble base-pair. Our results illustrate that the 2-thio modification can both increase polymerization rate and enhance fidelity in this self-replicating N3′-P5′-DNA system. These results suggest that this simple nucleobase modification may have played a role in primordial RNA (or proto-RNA) replication. In addition to suppressing the G:T mismatch, an additional benefit gained from its stronger base-pairing with A is that it also reduces A:C mismatch formation. Thus, simple modifications of nucleobases might provide a means of suppressing mismatches to yield better fidelity. Taken together, our results show that a high rate of polymerization and a high degree of fidelity are not mutually exclusive, but can be achieved simultaneously in nonenzymatic copying of N3′-P5′-linked phosphoramidate DNA. The structural similarity of NP-DNA to RNA suggests that these results could be translated to an RNA-only system.