Upstream subsite interactions for oligonucleotide binding with ribonuclease T1

Addressing the Challenge of Changing the Specificity of RNase T1 with Rational and Evolutionary Approaches

Although ribonuclease T1 (RNase T1) is one of the best-characterized proteins with respect to structure and enzymatic action, numerous attempts at altering the specificity of the enzyme to cleave single-stranded RNA at the 3'-side of adenylic instead of guanylic residues by rational approaches have failed so far. Recently we generated and characterized the RNase T1 variant RV with a 7200-fold increase in adenylyl-3',5'-cytidine (ApC)/guanylyl-3',5'-cytidine (GpC) preference, with the guanine-binding loop changed from 41-KYNNYE-46 (wt) to 41-EFRNWN-46. Now we have introduced the asparagine residue at position 46 of the wild-type enzyme as a single-point mutation in variant E46N and in combination with the Y45W exchange also occurring in RV. Both variants show an improved ApC/GpC preference with a 1450-fold increase for E46N and a 2100-fold increase for Y45W/E46N in comparison to wild-type activity. We also addressed the challenge of altering enzyme specificity with an evolutionary approach. We have randomly introduced point mutations into the RNase T1 wild-type gene and into the gene of the variant RV with different mutation rates. Altogether we have screened about 100,000 individual clones for activity on RNase indicator plates; 533 of these clones were active. A significant change in substrate specificity towards an ApC preference could not be observed for any of these active variants; this demonstrated the magnitude of the challenge to alter the specificity of this evolutionary perfected enzyme.

Determination of platinated purines in oligoribonucleotides by limited digestion with ribonucleases T1 and U2

Platinum complexes which are known to react preferentially with guanine (G) and adenine (A) bases of oligonucleotides can be used as tools to analyze their tertiary structures and eventually to cross-link them. However, this requires efficient methods to allow the identification and quantification of the corresponding adducts which have so far been developed only for oligodeoxyribonucleotides. Maxam-Gilbert type digestions cannot be used for RNAs and HPLC techniques would require too large amounts of expensive material for separation and further characterization. We report a method to determine platination sites on oligoribonucleotides based on the cleavage activity of ribonucleases T1 and U2. To test the method, these enzymes were first used under conditions of limited digestion on 5-mer oligoribonucleotides platinated at a single defined purine. The phosphodiester bond on the 3' side of platinated G or A appeared fully resistant to cleavage by ribonuclease T1 or U2, respectively. An inhibitory effect was also observed due to neighboring platinated purines, which decreases with their distance (-2, -1, +1, +2) from the cleavage site and with the enzyme concentration. The method allowed the identification and quantification of the platination sites of a 17-mer oligoribonucleotide, based on the analysis of the mixture of monoplatinated adducts.

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 T1 (RNase T1) 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 T1 compared with Glu46Ser-RNase T1, which indicated that the gamma-carboxyl group of conserved Glu46 must be deprotonated (anionic) for maximal interaction with N1H and N2H of the guanine moiety of GpC or the N1H of the hypoxanthine moiety of PolyI. The involvement of the epsilon -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 T1 and Lys41Thr-RNase T1 with wild-type. These mutants shared identical catalytic properties (i.e., k(cat) and K(M)) 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 epsilon -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).

Binding patterns and kinetics of RNase a interaction with RNA

Kinetics and binding studies of RNase A and its natural polymeric substrate (RNA), as well as the natural mixture of free 3'-ribonucleotides, were performed by difference spectrophotometry. The obtained kinetic saturation curve, with an anomalous nonhyperbolic shape and a distinct transition point, showed the interchange between the two conformational forms of the enzyme. This occurred in a narrow range of substrate concentration. At low substrate concentration, in spite of the existence of one catalytic cleft, RNase A behaves as a cooperative system, perhaps due to the interactions among the four cooperative binding subsites in the active cleft. At high substrate concentration, the conformational change did occur and was accompanied by a decrease in cooperativity and increment of the catalytic constant. The multiphasic shape of the binding curve, which, in the presence of the enzyme, produced 3'-ribonucleotides (as the ligand molecules), shows four binding subsites. The first three subsites are specific for the attachment of phosphate, ribose, and base moieties belonging to the first bound 3'-ribonucleotide in the direction of 3'-phosphate --> ribose --> base-5'. The fourth subsite relates to the second phosphate group of the second bound 3'-ribonucleotide. The binding direction also converts to 5'-phosphate --> ribose --> base-3' for the ribonucleotide monomers in the RNA structure.