Direct metal ion coordination to phosphate oxygens is not essential for hairpin ribozyme catalysis and metal-bound hydroxide does not serve as the general base in this catalysis. Several models might account for the unusual pH and metal ion independence: hairpin cleavage and ligation might be limited by a slow conformational change; a pH-independent or metal-cation-independent chemical step, such as breaking the 5' oxygen-phosphorus bond, might be rate determining; or finally, functional groups within the ribozyme might participate directly in catalytic chemistry. Whichever the case, the hairpin ribozyme appears to employ a unique strategy for RNA catalysis.
The hairpin ribozyme, derived from the negative strand of the satellite RNA of tobacco ringspot virus, belongs to the class of small catalytic RNAs that cleave RNA to generate 2',3'-cyclic phosphate and 5'hydroxyl termini and ligate these termini in the reverse reaction to form 3',5'-phosphodiesters. Rate and equilibrium constants for binding, dissociation, cleavage, and ligation steps in the kinetic mechanism were determined using a series of hairpin ribozyme/substrate pairs that differed in the sequence and length of the intermolecular base-paired helices. All hairpin variants cleaved with rate constants of approximately 0.3 min-1 at pH 7.5 in 10 nM MgCl2 at 25 degrees C, regardless of the length or sequence of the intermolecular helices. A rate constant of approximately 3 min-1 was determined for an intermolecular ligation reaction in which both cleavage products were supplied to the ribozyme in trans. Thus, the hairpin favored ligation over cleavage by 10-fold when the ribozyme was saturated with cleavage products. Binding rate constants for cleavage substrates and products were comparable to values reported for other catalytic RNAs but were somewhat slower than binding rates typical of small RNA helices. Substrate dissociation rate constants were much slower than cleavage rate constants for all substrates. Because virtually every substrate that was bound was cleaved before it could dissociate, KMS values were not the same as KdS values. Instead, KMS reflected the ratio of cleavage and substrate binding rate constants and had the same value of approximately 30 nM for all substrates. Calculations based on empirically determined free energy parameters for simple RNA helices indicated that complexes between ribozymes and 5'-cleavage products were slightly less stable than simple helices with the same sequences. In contrast, affinities between ribozymes and cleavage substrates and between ribozymes and 3'-cleavage products were stronger than expected for simple duplexes by about -2.5 kcal/mol, evidence of stabilizing interactions in addition to those contributed by helical base pairs. This kinetic and thermodynamic study demonstrates that the kinetic mechanism of the hairpin ribozyme is distinct from the kinetic mechanisms of other well-characterized ribozymes and provides a foundation for further exploration of the hairpin structure and catalytic mechanism.
Individual species of tRNA from Escherichia coli were treated with hydrazine/3 M NaCl to modify cytidine residues. The chemically modified tRNAs were used as substrate for ATP/CTP: tRNA nucleotidyltransferases from E. coli and yeast, with [alpha-32P]ATP as cosubstrate. tRNAs that were labeled were analyzed for their content of modified cytidines. Cytidines at positions 74 and 75 were found to be required chemically intact for interaction with both enzymes. C56 was also required intact by the E. coli enzyme in all tRNAs, and by the yeast enzyme in several instances. C61 was found to be important in seven of 14 tRNAs with the E. coli enzyme but only in four of 13 tRNAs with that from yeast. Our results support a model in which nucleotidyltransferase extends from the 3' end of its tRNA substrate across the top of the stacked array of bases in the accepter- and psi-stems to the corner of the molecule where the D- and psi-loops are juxtaposed.
Recognition of tRNA and tRNA-like substrates by the enzyme ATP/CTP:tRNA nucleotidyltransferase requires chemically intact nucleotides within the T-loop, especially at positions 57 and 58, which are invariant purines among naturally occurring tRNAs. To test the effects of base substitutions at these positions, which are distant from the site of catalysis, we synthesized mutant tRNA(Glu) molecules. These in vitro-synthesized RNAs also contained an extra 33 bases at the 5' end and lacked post-transcriptionally modified bases. The precursor tRNAs were used as substrates for nucleotidyltransferases from Escherichia coli and yeast. Substitution of cytidines at either position 57 or 58 had dramatic inhibitory effects on recognition by both enzymes, including raising the apparent Km and lowering the apparent Vmax.; substitution of an adenosine at position 57 or a uridine at position 58 inhibited the reaction only slightly by comparison. Our results demonstrate that the identities of nucleotides at positions 57 and 58 are relevant to recognition by nucleotidyltransferase, and that a purine is required at position 57. The extra bases at the 5' end and the lack of post-transcriptionally modified bases did not substantially inhibit interaction with the enzyme, as judged by the wild-type precursor tRNA(Glu) acting as an effective substrate for both enzymes in the presence of equal concentrations of appropriate tRNA substrates isolated from E. coli.
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