Is the secondary putative RNA-RNA interaction site relevant to GcvB mediated regulation of oppA mRNA in Escherichia coli?

GcvB is a non-coding RNA that regulates oppA mRNA in different bacterial species by binding a GcvB GU-rich region named R1 to oppA mRNA. A secondary putative interaction site (PS1) was identified in this study that is able to form a second nearly perfect 10 base-pair duplex between these two RNAs in Escherichia coli. In this work, we have studied whether the formation of a second interaction site could help stabilize the previously reported GcvB/oppA complex. Several mutations and the full deletion of PS1 were engineered. None of these modifications affected the ability of GcvB to control OppA expression. Therefore the second, putative, interaction site appears to be unnecessary for the regulatory function of GcvB with regard to its oppA target mRNA.

Hfq affects mRNA levels independently of degradation.

BACKGROUND: The bacterial Lsm protein, Hfq, is an RNA chaperone involved in many reactions related to RNA metabolism, such as replication and stability, control of small RNA activity and polyadenylation. Despite this wide spectrum of known functions, the global role of Hfq is almost certainly undervalued; its capacity to bind DNA and to interact with many other proteins are only now beginning to be taken into account. RESULTS: The role of Hfq in the maturation and degradation of the rpsO mRNA of E. coli was investigated in vivo. The data revealed a decrease in rpsO mRNA abundance concomitant to an increase in its stability when Hfq is absent. This indicates that the change in mRNA levels in hfq mutants does not result from its modification of RNA stability. Moreover, a series of independent experiments have revealed that the decrease in mRNA level is not a consequence of a reduction of translation efficiency and that Hfq is not directly implicated in translational control of rpsO expression. Reduced steady-state mRNA levels in the absence of Hfq were also shown for rpsT, rpsB and rpsB-tsf, but not for lpp, pnp or tRNA transcripts. The abundance of chimeric transcripts rpsO-lacZ and rpsB-lacZ, whose expression was driven by rpsO and rpsB promoters, respectively, was also lower in the hfq null-mutants, while the beta-galactosidase yield remained about the same as in the parent wild-type strain. CONCLUSIONS: The data obtained suggest that alteration of rpsO, rpsT and rpsB-tsf transcript levels observed under conditions of Hfq deficiency is not caused by the post-transcriptional events, such as mRNA destabilization or changes in translation control, and may rather result from changes in transcriptional activity. So far, how Hfq affects transcription remains unclear. We propose that one of the likely mechanisms of Hfq-mediated modulation of transcription might operate early in the elongation step, when interaction of Hfq with a nascent transcript would help to overcome transcription pauses and to prevent preliminary transcript release.

Auto-assembly of E. coli DsrA small noncoding RNA: Molecular characteristics and functional consequences.

RNA molecules are important factors involved in different cellular processes and have a multitude of roles in the cell. These roles include serving as a temporary copy of genes used for protein synthesis or functions in translational machinery. Interestingly, RNA is so far the only biological molecule that serves both as a catalyst (like proteins) and as information storage (like DNA). However, in contrast to proteins well known to be able to self-associate in order to maintain the architecture of the cell, such RNA polymers are not prevalent in cells and are usually not favored by the flexibility of this molecule. In this work, we present evidence that such a polymer of a natural RNA, the DsrA RNA, exists in the bacterial cell. DsrA is a small noncoding RNA (87 nucleotides) of Escherichia coli that acts by base-pairing to mRNA in order to control the translation and the turnover of some mRNA, including rpoS mRNA, which encodes the sigma(s) RNA polymerase subunit involved in bacterial stress response. A putative model is proposed for the structure of this RNA polymer. Although the function of this polymerization is not known completely, we propose that the formation of such a structure could be involved in the regulation of DsrA ncRNA concentration in vivo or in a quality control mechanism used by the cell to eliminate misfolded RNAs.

Polyadenylation of a functional mRNA controls gene expression in Escherichia coli.

Although usually implicated in the stabilization of mRNAs in eukaryotes, polyadenylation was initially shown to destabilize RNA in bacteria. All the data are consistent with polyadenylation being part of a quality control process targeting folded RNA fragments and non-functional RNA molecules to degradation. We report here an example in Escherichia coli, where polyadenylation directly controls the level of expression of a gene by modulating the stability of a functional transcript. Inactivation of poly(A)polymerase I causes overexpression of glucosamine-6-phosphate synthase (GlmS) and both the accumulation and stabilization of the glmS transcript. Moreover, we show that the glmS mRNA results from the processing of the glmU-glmS cotranscript by RNase E. Interestingly, the glmU-glmS cotranscript and the mRNA fragment encoding GlmU only slightly accumulated in the absence of poly(A)polymerase, suggesting that the endonucleolytically generated glmS mRNA harbouring a 5' monophosphate and a 3' stable hairpin is highly susceptible to poly(A)-dependent degradation.

Fate of mRNA extremities generated by intrinsic termination: detailed analysis of reactions catalyzed by ribonuclease II and poly(A) polymerase.

In all living cells 3' ends of RNA are posttranscriptionally elongated or shortened by nucleotidyl transferases and ribonucleases. The detailed analysis of the rpsO mRNA of Escherichia coli presented here demonstrates that transcription terminates in vivo at two sites located seven and eight nucleotides downstream from the GC-rich hairpin of the intrinsic terminator and that primary transcripts can be shortened by RNase II. The shortest RNA identified in the cell result from nibbling of primary transcripts. Primary transcripts and nibbled molecules can also be adenylated by poly(A) polymerase I (PAP I). In addition, kinetics of decay performed in vitro demonstrate that RNase II rapidly degrades poly(A) tails longer than 7-8 As processively while it slowly nibbles shorter tails and non adenylated RNAs distributively. Comparison of the kinetics of nibbling of oligoadenylated rpsO mRNA in vivo and in vitro lead us to conclude that the rates of shortening and elongation of the oligo(A) tails detected in vivo are very slow: about 0.5-7 nucleotides per min. We finally speculate that the slowness of oligo(A) synthesis may explain why polyadenylation does not affect the stability of mRNAs whose degradation is controlled by RNase E.

Inactivation of the decay pathway initiated at an internal site by RNase E promotes poly(A)-dependent degradation of the rpsO mRNA in Escherichia coli.

In Escherichia coli, RNA degradation is mediated by endonucleolytic processes, frequently mediated by RNase E, and also by a poly(A)-dependent mechanism. The dominant pathway of decay of the rpsO transcripts is initiated by an RNase E cleavage occurring at a preferential site named M2. We demonstrate that mutations which prevent this cleavage slow down degradation by RNase E. All these mutations reduce the single-stranded character of nucleotides surrounding the cleavage site. Moreover, we identify two other cleavage sites which probably account for the slow RNase E-mediated degradation of the mutated mRNAs. Failure to stabilize the rpsO transcript by appending a 5' hairpin indicates that RNase E is not recruited by the 5' end of mRNA. The fact that nucleotide substitutions which prevent cleavage at M2 facilitate the poly(A)-dependent degradation of the rpsO transcripts suggest an interplay between the two mechanisms of decay. In the discussion, we speculate that a structural feature located in the vicinity of M2 could be an internal degradosome entry site promoting both RNase E cleavages and poly(A)-dependent degradation of the rpsO mRNA. We also discuss the role of poly(A)-dependent decay in mRNA metabolism.

Hfq affects the length and the frequency of short oligo(A) tails at the 3' end of Escherichia coli rpsO mRNAs.

Polyadenylation plays an important role in RNA degradation in bacterial cells. In Escherichia coli, exoribonucleases, mostly RNase II and polynucleotide phosphorylase, antagonize the synthesis of poly(A) tails by poly(A) polymerase I (PAP I). In accordance with earlier observations showing that only a small fraction of bacterial RNA is polyadenylated, we demonstrate here that approximately 10% of rpsO mRNA harbors short oligo(A) tails ranging from one to five A residues in wild-type cells. We also compared the length, frequency and distribution of poly(A) tails at the 3'-end of rpsO transcripts in vivo in the presence and absence of Hfq, a host factor that in vitro stimulates the activity of PAP I, and found that Hfq affects all three parameters. In the hfq(+) strain the average length of oligo(A) tails and frequency of polyadenylated transcripts was higher than in the hfq(-) strain and a smaller proportion of tails was found at the 3' end of transcripts terminated at the Rho- independent terminator. Our data led us to the conclusion that Hfq is involved in the recognition of 3' RNA extremities by PAP I.