Kinetics of polynucleotide phosphorylase: comparison of enzymes from Streptomyces and Escherichia coli and effects of nucleoside diphosphates.

We examined the activity of polynucleotide phosphorylase (PNPase) from Streptomyces coelicolor, Streptomyces antibioticus, and Escherichia coli in phosphorolysis using substrates derived from the rpsO-pnp operon of S. coelicolor. The Streptomyces and E. coli enzymes were both able to digest a substrate with a 3' single-stranded tail although E. coli PNPase was more effective in digesting this substrate than were the Streptomyces enzymes. The kcat for the E. coli enzyme was ca. twofold higher than that observed with the S. coelicolor enzyme. S. coelicolor PNPase was more effective than its E. coli counterpart in digesting a substrate possessing a 3' stem-loop structure, and the Km for the E. coli enzyme was ca. twice that of the S. coelicolor enzyme. Electrophoretic mobility shift assays revealed an increased affinity of S. coelicolor PNPase for the substrate possessing a 3' stem-loop structure compared with the E. coli enzyme. We observed an effect of nucleoside diphosphates on the activity of the S. coelicolor PNPase but not the E. coli enzyme. In the presence of a mixture of 20 microM ADP, CDP, GDP, and UDP, the Km for the phosphorolysis of the substrate with the 3' stem-loop was some fivefold lower than the value observed in the absence of nucleoside diphosphates. No effect of nucleoside diphosphates on the phosphorolytic activity of E. coli PNPase was observed. To our knowledge, this is the first demonstration of an effect of nucleoside diphosphates, the normal substrates for polymerization by PNPase, on the phosphorolytic activity of that enzyme.

A phylogeny of bacterial RNA nucleotidyltransferases: Bacillus halodurans contains two tRNA nucleotidyltransferases.

We have analyzed the distribution of RNA nucleotidyltransferases from the family that includes poly(A) polymerases (PAP) and tRNA nucleotidyltransferases (TNT) in 43 bacterial species. Genes of several bacterial species encode only one member of the nucleotidyltransferase superfamily (NTSF), and if that protein functions as a TNT, those organisms may not contain a poly(A) polymerase I like that of Escherichia coli. The genomes of several of the species examined encode more than one member of the nucleotidyltransferase superfamily. The function of some of those proteins is known, but in most cases no biochemical activity has been assigned to the NTSF. The NTSF protein sequences were used to construct an unrooted phylogenetic tree. To learn more about the function of the NTSFs in species whose genomes encode more than one, we have examined Bacillus halodurans. We have demonstrated that B. halodurans adds poly(A) tails to the 3' ends of RNAs in vivo. We have shown that the genes for both of the NTSFs encoded by the B. halodurans genome are transcribed in vivo. We have cloned, overexpressed, and purified the two NTSFs and have shown that neither functions as poly(A) polymerase in vitro. Rather, the two proteins function as tRNA nucleotidyltransferases, and our data suggest that, like some of the deep branching bacterial species previously studied by others, B. halodurans possesses separate CC- and A-adding tRNA nucleotidyltransferases. These observations raise the interesting question of the identity of the enzyme responsible for RNA polyadenylation in Bacillus.

The absB gene encodes a double strand-specific endoribonuclease that cleaves the read-through transcript of the rpsO-pnp operon in Streptomyces coelicolor.

The absB locus of Streptomyces coelicolor encodes a homolog of bacterial RNase III. We cloned and overexpressed the absB gene product and purified a decahistidine-tagged version of the protein. We show here that AbsB is active against double-stranded RNA transcripts derived from synthetic DNAs but is inactive with single-stranded homopolymers. We thus designate the absB product RNase IIIS. Using T7 RNA polymerase and a cloned template containing the rpsO-pnp intergenic region, we synthesized an RNA substrate representing a portion of the read-through transcript normally produced in S. coelicolor. This transcript contains the sequences that form the putative rpsO terminator and those that form an intergenic stem-loop structure thought to be the site for RNase IIIS processing of the read-through transcript. We show that RNase IIIS does cleave that model transcript, with primary and secondary cleavage sites in an internal loop in the stem-loop structure. We have identified the primary and secondary cleavage sites by primer extension and demonstrate the further processing of the initial cleavage products. Thus, as is the case in Escherichia coli, the read-through transcript from rpsO-pnp is cleaved by RNase IIIS in S. coelicolor. However, the cleavage sites are different in the two systems. The positions of the cleavage sites in the stem-loop of the S. coelicolor transcript are more akin to those identified in the processing of bacteriophage T7 mRNAs. A kinetic assay for RNase IIIS was developed, and kinetic parameters for the reaction utilizing the model transcript from rpsO-pnp were determined.