The rph-1-Encoded Truncated RNase PH Protein Inhibits RNase P Maturation of Pre-tRNAs with Short Leader Sequences in the Absence of RppH.

RNase PH, encoded by the rph gene, is a 3'→5' exoribonuclease that in E. coli participates primarily in the 3' maturation of pre-tRNAs and the degradation of rRNA in stationary-phase cells. Interestingly, the routinely used laboratory strains of MG1655 and W3110 have naturally acquired the rph-1 allele, encoding a truncated catalytically inactive RNase PH protein which is widely assumed to be benign. Contrary to this assumption, we show that the rph-1-encoded Rph-1 protein inhibits RNase P-mediated 5'-end maturation of primary pre-tRNAs with leaders of <5 nucleotides in the absence of RppH, an RNA pyrophosphohydrolase. In contrast, RppH is not required for 5'-end maturation of endonucleolytically generated pre-tRNAs in the rph-1 strain and for any tRNAs in Δrph mutant or rph+ strains. We propose that the Rph-1 protein bound to the 3' end of the substrate creates a steric hindrance that in the presence of a triphosphate at the 5' end reduces the ability of RNase P to bind to the pre-tRNA.IMPORTANCE In this paper, we demonstrate that the rph-1 mutation found in commonly used E. coli strains leads to the synthesis of a truncated functionally inactive RNase PH protein that interferes with the 5'-end maturation of specific tRNAs with short 5' leaders by RNase P in the absence of RppH, an RNA pyrophosphohydrolase that converts primary 5' triphosphates into 5' monophosphates. The data presented indicate that the presence of the triphosphate interferes with RNase P binding to the pre-tRNA.

Intragenic suppressors of temperature-sensitive rne mutations lead to the dissociation of RNase E activity on mRNA and tRNA substrates in Escherichia coli.

RNase E of Escherichia coli is an essential endoribonuclease that is involved in many aspects of RNA metabolism. Point mutations in the S1 RNA-binding domain of RNase E (rne-1 and rne-3071) lead to temperature-sensitive growth along with defects in 5S rRNA processing, mRNA decay and tRNA maturation. However, it is not clear whether RNase E acts similarly on all kinds of RNA substrates. Here we report the isolation and characterization of three independent intragenic second-site suppressors of the rne-1 and rne-3071 alleles that demonstrate for the first time the dissociation of the in vivo activity of RNase E on mRNA versus tRNA and rRNA substrates. Specifically, tRNA maturation and 9S rRNA processing were restored to wild-type levels in each of the three suppressor mutants (rne-1/172, rne-1/186 and rne-1/187), while mRNA decay and autoregulation of RNase E protein levels remained as defective as in the rne-1 single mutant. Each single amino acid substitution (Gly-->Ala at amino acid 172; Phe --> Cys at amino acid 186 and Arg --> Leu at amino acid 187) mapped within the 5' sensor region of the RNase E protein. Molecular models of RNase E suggest how suppression may occur.

RNase Z in Escherichia coli plays a significant role in mRNA decay.

Genetic and biochemical analysis of RNase Z in eukaryotes, such as Arabadopsis thaliana, and prokaryotes like Bacillus subtilis have demonstrated that this endoribonuclease is essential for the maturation of tRNA precursors that do not contain a chromosomally encoded CCA determinant. As all Escherichia coli tRNA transcripts have chromosomally encoded CCA determinants, the function of its putative RNase Z homologue, the product of the elaC gene, is not clear. Here we demonstrate that the E. coli ElaC protein (RNase Z) endonucleolytically processes B. subtilis tRNA precursors lacking a CCA determinant both in vivo and in vitro. More importantly, E. coli RNase Z plays a significant role in mRNA decay, a previously unidentified activity for the enzyme. The purified RNase Z protein cleaves the rpsT mRNA at locations distinct from those obtained with RNase E. As expected, under physiological conditions E. coli and B. subtilis tRNA precursors containing a CCA determinant are not substrates. These results suggest a potentially important new role for the RNase Z family of proteins in RNA metabolism, particularly in organisms lacking RNase E.

RNase G of Escherichia coli exhibits only limited functional overlap with its essential homologue, RNase E.

RNase G (rng) is an E. coli endoribonuclease that is homologous to the catalytic domain of RNase E (rne), an essential protein that is a major participant in tRNA maturation, mRNA decay, rRNA processing and M1 RNA processing. We demonstrate here that whereas RNase G inefficiently participates in the degradation of mRNAs and the processing of 9S rRNA, it is not involved in either tRNA or M1 RNA processing. This conclusion is supported by the fact that inactivation of RNase G alone does not affect 9S rRNA processing and only leads to minor changes in mRNA half-lives. However, in rng rne double mutants mRNA decay and 9S rRNA processing are more defective than in either single mutant. Conversely, increasing RNase G levels in an rne-1 rng::cat double mutant, proportionally increased the extent of 9S rRNA processing and decreased the half-lives of specific mRNAs. In contrast, variations in the amount of RNase G did not alter tRNA processing under any circumstances. Thus, the failure of RNase G to complement rne mutations, even when overproduced at high levels, apparently results from its inability to substitute for RNase E in the maturation of tRNAs.