RNase E-based degradosome modulates polyadenylation of mRNAs after Rho-independent transcription terminators in Escherichia coli.

Here we demonstrate that the RNase E-based degradosome is required for poly(A) polymerase I (PAP I)-dependent polyadenylation after Rho-independent transcription terminators for both mono- and polycistronic transcripts. Disruption of degradosome assembly in mutants lacking the polynucleotide phosphorylase (PNPase) binding domain led to a significant increase in the level of PNPase synthesized polynucleotide tails in the rpsJ and rpsM polycistronic transcripts and the lpp monocistronic transcript. The polynucleotide tails were mostly located within the coding sequences in the degradosome mutants compared to the wild type control where the majority of the PAP I synthesized poly(A) tails were after the Rho-independent transcription terminators. For the Rho terminated metNIQ operon, the tails for all three mRNAs were predominately polynucleotide and were located within the coding sequences in both wild type and degradosome mutant strains. Furthermore, by employing a pnp-R100D point mutant that encodes a catalytically inactive PNPase protein that still forms intact degradosomes, we show that a catalytically active PNPase is required for normal mRNA polyadenylation by PAP I. Our data suggest that polyadenylation requires a functional degradosome to maintain an equilibrium between free PNPase and the PAP I polyadenylation complex.

Polyadenylation helps regulate functional tRNA levels in Escherichia coli.

Here we demonstrate a new regulatory mechanism for tRNA processing in Escherichia coli whereby RNase T and RNase PH, the two primary 3' → 5' exonucleases involved in the final step of 3'-end maturation, compete with poly(A) polymerase I (PAP I) for tRNA precursors in wild-type cells. In the absence of both RNase T and RNase PH, there is a >30-fold increase of PAP I-dependent poly(A) tails that are ≤10 nt in length coupled with a 2.3- to 4.2-fold decrease in the level of aminoacylated tRNAs and a >2-fold decrease in growth rate. Only 7 out of 86 tRNAs are not regulated by this mechanism and are also not substrates for RNase T, RNase PH or PAP I. Surprisingly, neither PNPase nor RNase II has any effect on tRNA poly(A) tail length. Our data suggest that the polyadenylation of tRNAs by PAP I likely proceeds in a distributive fashion unlike what is observed with mRNAs.

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.

Analysis of RNA decay, processing, and polyadenylation in Escherichia coli and other prokaryotes.

This chapter provides detailed methodologies for isolating total RNA and polyadenylated RNA from E. coli and other prokaryotes, along with the procedures necessary to analyze the processing and decay of specific transcripts and determine their 3'- and 5'-ends. The RNA isolation methods described here facilitate isolating good-quality RNA in a very cost-effective way compared to the commercially available RNA isolation kits, without employing phenol and/or alcohol precipitation. We also discuss the limits associated with polyacrylamide and agarose gels for the separation of small and large RNAs. Methods useful for the analysis of post-transcriptionally modified transcripts and the processing of very large polycistronic transcripts are also presented.

The Sm-like protein Hfq regulates polyadenylation dependent mRNA decay in Escherichia coli.

In Escherichia coli, the post-transcriptional addition of poly(A) tails by poly(A) polymerase I (PAP I, pcnB) plays a significant role in cellular RNA metabolism. However, many important features of this system, including its regulation and the selection of polyadenylation sites, are still poorly understood. Here we show that the inactivation of Hfq (hfq), an abundant RNA-binding protein, leads to the reduction in the ability of PAP I to add poly(A) tails at the 3' termini of mRNAs containing Rho-independent transcription terminators even though PAP I protein levels remain unchanged. Those poly(A) tails that are synthesized in the absence of Hfq are shorter in length, even in the absence of polynucleotide phosphorylase (PNPase), RNase II and RNase E. In fact, the biosynthetic activity of PNPase in the hfq single mutant is enhanced and it becomes the primary polynucleotide polymerase, adding heteropolymeric tails almost exclusively to 3' truncated mRNAs. Surprisingly, both PNPase and Hfq co-purified with His-tagged PAP I under native conditions indicating a potential complex among these proteins. Immunoprecipitation experiments using PNPase- and Hfq-specific antibodies confirmed the protein-protein interactions among PAP I, PNPase and Hfq. Analysis of mRNA half-lives in hfq, deltapcnB and hfq deltapcnB mutants suggests that Hfq and PAP I function in the same mRNA decay pathway.

RNase E levels in Escherichia coli are controlled by a complex regulatory system that involves transcription of the rne gene from three promoters.

The rne gene of Escherichia coli encodes RNase E, an essential endoribonuclease that is involved in both mRNA decay and rRNA processing. Here we present evidence that the gene is transcribed from three promoters: p1, p2 and p3. The p2 and p3 promoters map 34 and 145 nt upstream from the previously characterized rne promoter, p1, generating unusually long 5' UTRs of 395 and 506 nt respectively. Based on promoter-lacZ transcriptional fusions, p1 is a more efficient promoter than either p2 or p3. Low copy number or single copy number vectors carrying rne transcribed from either p1, p2 or p3 alone complement the rne 1018::bla deletion mutation at 30 degrees C, 37 degrees C and 44 degrees C. However, normal autoregulation requires the presence of all three promoters. A comparison among intracellular levels of RNase E, the half-lives of the rpsO, rpsT and rne mRNAs, and growth rates, indicates that the cell contains a considerable excess of RNase E protein. In addition, when the rne transcript is stabilized at low RNase E levels, it is not efficiently translated.