Base Pairing and Functional Insights intoN3-methylcytidine (m3C) in RNA

Abstract

ABSTRACTN3-methylcytidine (m3C) is present in both eukaryotic tRNA and mRNA and plays critical roles in many biological processes. We report the synthesis of the m3C phosphoramidite building block and its containing RNA oligonucleotides. The base-pairing stability and specificity studies show that the m3C modification significantly disrupts the stability of the Watson-Crick C:G pair. Further m3C decreases the base pairing discrimination between C:G and the other mismatched C:A, C:U, and C:C pairs. Our molecular dynamic simulation study further reveals the detailed structural insights into the m3C:G base pairing pattern in an RNA duplex. More importantly, the biochemical investigation of m3C using reverse transcription shows thatN3-methylation specifies the C:A pair and induces a G to A mutation using HIV-1-RT, MMLV-RT and MutiScribe™-RT enzymes, all with relatively low replication fidelity. For other reverse transcriptases with higher fidelity like AMV-RT, the methylation could completely shut down DNA synthesis.