A 2′-methyl or 2′-methylene group at G+1 in precursor tRNA interferes with Mg2+ binding at the enzyme-substrate interface in E-S complexes of E. coli RNase P

Abstract

We analyzed processing of precursor tRNAs carrying a single 2'-deoxy, 2'-OCH(3), or locked nucleic acid (LNA) modification at G+1 by Escherichia coli RNase P RNA in the absence and presence of its protein cofactor. The extra methyl or methylene group caused a substrate binding defect, which was rescued at higher divalent metal ion (M(2+)) concentrations (more efficiently with Mn(2+) than Mg(2+)), and had a minor effect on cleavage chemistry at saturating M(2+) concentrations. The 2'-OCH(3) and LNA modification at G+1 resulted in higher metal ion cooperativity for substrate binding to RNase P RNA without affecting cleavage site selection. This indicates disruption of an M(2+) binding site in enzyme-substrate complexes, which is compensated for by occupation of alternative M(2+) binding sites of lower affinity. The 2'-deoxy modification at G+1 caused at most a two-fold decrease in the cleavage rate; this mild defect relative to 2'-OCH(3) and LNA at G+1 indicates that the defect caused by the latter two is steric in nature. We propose that the 2'-hydroxyl at G+1 in the substrate is in the immediate vicinity of the M(2+) cluster at the phosphates of A67 to U69 in helix P4 of E. coli RNase P RNA.