Project description:The Bacillus subtilis genome encodes four 3’ exoribonucleases: polynucleotide phosphorylase (PNPase), RNase R, RNase PH, and YhaM. Previous work showed that PNPase, encoded by the pnpA gene, is the major 3’ exonuclease involved in mRNA turnover; in a pnpA deletion strain, numerous mRNA decay intermediates accumulate. Whether B. subtilis mRNA decay occurs in the context of a degradosome complex is controversial. In this study, global mapping of mRNA decay intermediate 3’ ends within coding sequences was performed in strains that were either deleted for, or had an inactivating point mutation in, the pnpA gene. The pattern of 3’ end accumulation in these strains was highly similar, suggesting that mRNA decay was not occurring in the context of a degradosome, whose structure would be affected by the absence of PNPase. A comparison with mapped 3’ ends in a strain lacking CshA, the major RNA helicase, indicated that different mRNAs may require both PNPase and CshA for efficient decay. RNA-seq analysis of strains lacking RNase R suggested that this enzyme did not play a major role in mRNA turnover in the wild-type strain. Strains were constructed that contained only one of the four known 3’ exoribonucleases. When RNase R was the only 3’ exonuclease present, it was able to degrade a model mRNA efficiently, showing processive decay even through a strong stem-loop structure that inhibits PNPase processivity. Strains containing only RNase PH or only YhaM were also insensitive to this RNA secondary structure, suggesting the existence of another, as-yet unidentified, 3’ exoribonuclease.

Project description:The transition between exponential and stationary phase is a natural phenomenon for all bacteria and requires a massive readjustment of the bacterial transcriptome. Exoribonucleases are key enzymes in the transition between the two growth phases. PNPase, RNase R and RNase II are the major degradative exoribonucleases in Escherichia coli. We analysed the whole transcriptome of exponential and stationary phases from the WT and mutants lacking these exoribonucleases (Δpnp, Δrnr, Δrnb, and ΔrnbΔrnr). When comparing the cells from exponential phase with the cells from stationary phase more than 1000 transcripts were differentially expressed, but only 491 core transcripts were common to all strains. There were some differences in the number and transcripts affected depending on the strain, suggesting that exoribonucleases influence the transition between these two growth phases differently. Interestingly, we found that the double mutant RNase II/RNase R is similar to the RNase R single mutant in exponential phase while in stationary phase it seems to be closer to the RNase II single mutant. This is the first global transcriptomic work comparing the roles of exoribonucleases in the transition between exponential and stationary phase.

Project description:Exoribonucleases are crucial for RNA degradation in Escherichia coli but the roles of RNase R and PNPase and their potential overlap in stationary phase are not well characterized. Here, we used a genome-wide approach to determine how RNase R and PNPase affect the mRNA half-lives compared to wild type (stabilome) in the stationary phase. The stabilome is an original dynamic transcriptome-based analysis to measure the rates of mRNA degradation at the genome scale. We have combined the analysis of stabilome with the steady state concentrations of mRNAs (transcriptome) to provide an integrated overview of the in vivo activity of these exoribonucleases at the genome-scale. The stabilome demonstrated that the mRNAs are very stable in the stationary phase and that the deletion of RNase R or PNPase caused only a limited mRNA stabilization. Intriguingly the absence of PNPase provoked also the destabilization of many mRNAs. These changes in mRNA half-lives in the PNPase deletion strain were associated with a massive reorganization of mRNA levels and also variation in several ncRNA concentrations. Finally, the in vivo activity of the degradation machinery was found frequently saturated by mRNAs in the PNPase mutant unlike in the RNase R mutant, suggesting that the degradation activity is limited by the deletion of PNPase but not by the deletion of RNase R. This work allowed the roles of RNase R and PNPase in coordinating E. coli RNA metabolism to be discussed and PNPase to be identified as a central player of the degradation machinery in stationary phase.

Project description:Exoribonucleases are crucial for RNA degradation in Escherichia coli but the roles of RNase R and PNPase and their potential overlap in stationary phase are not well characterized. Here, we used a genome-wide approach to determine how RNase R and PNPase affect the mRNA half-lives compared to wild type (stabilome) in the stationary phase. The stabilome is an original dynamic transcriptome-based analysis to measure the rates of mRNA degradation at the genome scale. We have combined the analysis of stabilome with the steady state concentrations of mRNAs (transcriptome) to provide an integrated overview of the in vivo activity of these exoribonucleases at the genome-scale. The stabilome demonstrated that the mRNAs are very stable in the stationary phase and that the deletion of RNase R or PNPase caused only a limited mRNA stabilization. Intriguingly the absence of PNPase provoked also the destabilization of many mRNAs. These changes in mRNA half-lives in the PNPase deletion strain were associated with a massive reorganization of mRNA levels and also variation in several ncRNA concentrations. Finally, the in vivo activity of the degradation machinery was found frequently saturated by mRNAs in the PNPase mutant unlike in the RNase R mutant, suggesting that the degradation activity is limited by the deletion of PNPase but not by the deletion of RNase R. This work allowed the roles of RNase R and PNPase in coordinating E. coli RNA metabolism to be discussed and PNPase to be identified as a central player of the degradation machinery in stationary phase.

Project description:RNases perform indispensable functions in regulating gene expression in many bacterial pathogens by processing and/or degrading RNAs. Despite the pivotal role of RNases in regulating bacterial virulence factors, the functions of RNases have not yet been studied in the major human respiratory pathogen Streptococcus pneumoniae (pneumococcus). Here, we sought to determine the impact of two conserved RNases, the endoribonuclease RNase Y and exoribonuclease polynucleotide phosphorylase (PNPase), on the physiology and virulence of S. pneumoniae serotype 2 strain D39. We report that RNase Y and PNPase are essential for pneumococcal pathogenesis as both deletion mutants showed strong attenuation of virulence in murine models of invasive pneumonia. Genome-wide transcriptomic analysis revealed that nearly 200 mRNA transcripts were significantly up-regulated, whereas the abundance of several pneumococcal sRNAs, including the Ccn (CiaR Controlled Noncoding RNA) sRNAs, were altered in the ∆rny mutant relative to the wild-type strain. Additionally, lack of RNase Y resulted in pleiotropic phenotypes that included defects in pneumococcal cell morphology and growth in vitro. In contrast, Dpnp mutants showed no growth defect in vitro, but differentially expressed a total of 40 transcripts including the tryptophan biosynthesis operon genes and numerous 5’-cis-acting regulatory RNAs, a majority of which were previously shown to impact pneumococcal disease progression in mice using the serotype 4 strain TIGR4. Altogether our data suggest that RNase Y exerts a global impact on pneumococcal physiology, while PNPase-mediates virulence phenotypes, likely through sRNA regulation.

Project description:In many gram-negative and some gram-positive bacteria small regulatory RNAs (sRNAs) that bind the RNA chaperone Hfq have a pivotal role in modulating virulence, stress responses, metabolism, and biofilm formation. These sRNAs recognize transcripts through base-pairing, and sRNA-mRNA annealing consequently alters the translation and/or stability of transcripts leading to changes in gene expression. We have previously found that the highly conserved 3'-to-5' exoribonuclease polynucleotide phosphorylase (PNPase) has an indispensable role in paradoxically stabilizing Hfq-bound sRNAs and promoting their function in gene regulation in Escherichia coli. Here, we report that PNPase uniquely contributes to the degradation of specific mRNA cleavage products, the majority of which bind Hfq and are derived from targets of sRNAs. Specifically, we found that these mRNA-derived fragments accumulate in the absence of PNPase or its exoribonuclease activity and interact with PNPase. Additionally, we show that mutations in hfq or in the seed pairing region of a sRNA eliminated the requirement of PNPase for sRNA stability. Altogether, our results are consistent with a model that PNPase degrades mRNA-derived fragments that could otherwise deplete cells of Hfq-binding sRNAs through pairing mediated decay.

Project description:Bacterial competence is a genetically programmed process that is triggered as a response to environmental stimuli. DNA uptake from the extracellular milieu by competence requires the expression of a complex machinery composed of a competence pseudopilus and a DNA translocase. In L. pneumophila, it has been reported that microaerophilic conditions and genetic alteration of the competence repressors ComR and ProQ result in competence. We have analyzed the gene expression profiles of the proQ and comR mutants using the L. pneumophila Philadelphia-1 microarray. Many competence genes were found to be induced in the comR and proQ mutants and represent a defined, regulon. The gene expression profiling of the proQ and comR mutants was part of a study aimed at understanding the function of the processive 3'-5' exoribonuclease RNase R (rnr gene) in L. pneumophila. We found that the gene expression profile of the rnr mutant shares similarities with the gene expression profiles of the comR and proQ mutants and that loss of the exoribonuclease activity of RNase R was sufficient to induce competence development. RNase R is a processive 3'-5' exoribonuclease with a high degree of conservation in prokaryotes. Although some bacteria possess additional hydrolytic 3´-5-exoribonucleases such as RNase II, RNase R was found to be the only one predicted in the Legionella pneumophila genome. This provided a unique opportunity to study the role of RNase R in the absence of an additional RNase with similar enzymatic activity. We investigated the role of RNase R in the biology of Legionella pneumophila under various conditions and performed gene expression profiling using microarrays. At optimal growth temperature, loss of RNase R had no major consequence on bacterial growth and had a moderate impact on normal gene regulation. However, at lower temperatures loss of RNase R has a significant impact on bacterial growth and resulted in the accumulation of structured RNA degradation products. Concurrently, gene regulation was affected and specifically resulted in increased expression of the competence regulon. Loss of the exoribonuclease activity of RNase R was sufficient to induce competence development, a genetically-programmed process normally triggered as a response to environmental stimuli. Temperature-dependent expression of competence genes in the rnr mutant was found to be independent of the previously identified competence regulators comR and ProQ.

Project description:Bacterial competence is a genetically programmed process that is triggered as a response to environmental stimuli. DNA uptake from the extracellular milieu by competence requires the expression of a complex machinery composed of a competence pseudopilus and a DNA translocase. In L. pneumophila, it has been reported that microaerophilic conditions and genetic alteration of the competence repressors ComR and ProQ result in competence. We have analyzed the gene expression profiles of the proQ and comR mutants using the L. pneumophila Philadelphia-1 microarray. Many competence genes were found to be induced in the comR and proQ mutants and represent a defined, regulon. The gene expression profiling of the proQ and comR mutants was part of a study aimed at understanding the function of the processive 3'-5' exoribonuclease RNase R (rnr gene) in L. pneumophila. We found that the gene expression profile of the rnr mutant shares similarities with the gene expression profiles of the comR and proQ mutants and that loss of the exoribonuclease activity of RNase R was sufficient to induce competence development. RNase R is a processive 3'-5' exoribonuclease with a high degree of conservation in prokaryotes. Although some bacteria possess additional hydrolytic 3´-5-exoribonucleases such as RNase II, RNase R was found to be the only one predicted in the Legionella pneumophila genome. This provided a unique opportunity to study the role of RNase R in the absence of an additional RNase with similar enzymatic activity. We investigated the role of RNase R in the biology of Legionella pneumophila under various conditions and performed gene expression profiling using microarrays. At optimal growth temperature, loss of RNase R had no major consequence on bacterial growth and had a moderate impact on normal gene regulation. However, at lower temperatures loss of RNase R has a significant impact on bacterial growth and resulted in the accumulation of structured RNA degradation products. Concurrently, gene regulation was affected and specifically resulted in increased expression of the competence regulon. Loss of the exoribonuclease activity of RNase R was sufficient to induce competence development, a genetically-programmed process normally triggered as a response to environmental stimuli. Temperature-dependent expression of competence genes in the rnr mutant was found to be independent of the previously identified competence regulators comR and ProQ. comR: Three test samples and three reference samples were analyzed. The test sample being the strain KS79, a comR mutant of L. pneumophila strain JR32 which is used as a reference. proQ: Three test samples and three reference samples were analyzed. The test sample being the strain LELA3825, a proQ mutant of L. pneumophila strain JR32 which is used as a reference. rnr: Six test samples and six reference samples grown at 30°C or 37°C were analyzed. The test sample being the strain LELA559, a rnr mutant of L. pneumophila strain JR32 which is used as a reference.

Project description:A comparative RNA-seq approach between R. sphaeroides 2.4.1 wild type and an RNase J deletion strain 2.4.1∆rnj revealed the accumulation of different mRNA fragments in the mutant. The structural characteristics of these RNA fragments suggest that RNase J is responsible for the decay of degradation intermediates that cannot serve as substrates for the 3´-to-5´ exoribonucleases.

Project description:In all bacterial species examined thusfar, small regulatory RNAs (sRNAs) contribute to intricate patterns of genetic regulation. Many of the actions of these nucleic acids are mediated by chaperones such as the Hfq protein, and genetic screens have identified the exoribonuclease polynucleotide phosphorylase (PNPase) as a stabilizer and facilitator of sRNAs in vivo. We observe that the protective and facilitating effects of PNPase in vivo require the RNA-binding KH and S1 domains and the catalytic site, suggesting a requirement for physical interation of the ribonuclease with either the sRNA itself or other RNAs acting upstream of the process. Although purified PNPase can readily degrade sRNAs in vitro, those same substrates, as well as numerous other sRNAs and transcripts, can be co-purified from cells by immunoprecipitation with neither degradation nor modification to the 3’ end. Our results indicate that PNPase can bind RNA in two modes in vivo – either destructive or stabilizing, and that there is active flux of RNAs on PNPase so that the stable molecules do not accumulate. In the presence of Hfq, PNPase and sRNA form a ternary complex in which the enzyme plays a non-destructive, structural role, but the complex does not confer protection against the action of RNase E in vitro. Taken together, our results indicate that PNPase, Hfq and additional factors form a protective ribonucleoprotein assembly that stabilizes certain sRNAs and facilitates their activities. Using cells from the same original culture, immunoprecipitiations using the anti-FLAG M2 resin were performed in the presence or absence of tungstate. Total RNA and immunoprecipitated RNA were sequenced from two independent biological replicates. The number of normalized reads (RPKM) were compared between the total RNA (input) and the immunoprecipitated RNA (output).