Kinetic studies of guanine recognition and a phosphate group subsite on ribonuclease T1 using substitution mutants at Glu46 and Lys41

pH-Dependent kinetic studies were performed with ribonuclease T-1 (RNase T-1) and its Glu46Ser, Lys41Met, and Lys41Thr mutants with GpC and polyinosinic acid (PolyI) as substrates. Plots of pH versus log(k(cat)/K-M) for both substrates had ascending slopes that were significantly greater for RNase T-1 compared with Glu46Ser-RNase T-1, which indicated that the gamma-carboxyl group of conserved Glu46 must be deprotonated (anionic) for maximal interaction with N(I)H and N(2)H of the guanine moiety of GpC or the N(1)H of the hypoxanthine moiety of PolyI. The involvement of the E-ammonium group of nonconserved Lys41 at the 2p subsite (i.e., for an RNA phosphate group two nucleotide positions 5'-upstream from the active site) was supported by comparisons of Lys41Met-RNase T-1 and Lys41Thr-RNase T-1 with wild-type. These mutants shared identical catalytic properties (i.e., k(cat) and Km) with wild-type using GpC as a substrate. However, k(cat)/K-M for both were identical with each other but lower than those for wild-type when PolyI was the substrate (PolyI has a phosphate group that could interact at a putative 2p site). The pH dependence of this latter difference can be interpreted as reflecting the loss of the 2p subsite interaction with the wild-type enzyme upon deprotonation of the F-ammonium group of Lys41. Subsite interactions for ribonucleases are shown to mainly increase k(cat) and result in an attenuated pH dependence of k(cat)/K-M. (C) 2002 Elsevier Science (USA). All rights reserved.