Project description:PNPase, one of the major enzymes with 3ʹ-to-5ʹ single-stranded RNA (ssRNA) degradation and processing activities, can interact with the RNA helicase RhlB independent of RNA degradosome formation in E. coli. Here we report that loss of interaction between RhlB and PNPase impacts cysteine homeostasis in E. coli. By random mutagenesis, we identified a mutant RhlBP238L that loses 75% of its ability to interact with PNPase, but retains normal interaction with RNase E and RNA in addition to exhibiting normal helicase activity. Applying microarray analyses to an E. coli strain with impaired RNA degradosome formation, we investigated the biological consequences of a weakened interaction between RhlB and PNPase.

Project description:The dataset accompanying a publication describing the RNA degradosome components in Mycobacterium tuberculosis (Mtb). Individual RNA degradosome components from Mtb (PNPase, RNase E, RNase J, RhlE and Enolase) were tagged with eGFP and used as baits to pull-down their interaction partners. The protein-complexes were purified by affinity chromatography, using previously published protocols, and submitted to LC-MS analysis.

Project description:RNA-Seq results accompanying submission of a manuscript describing roles of RNA degradosome components PNPase, RNase E and RNase J in shaping the transcriptome of the H37Rv Mycobacterium tuberculosis. Next generation sequenicing results are provided for three independent biological replicates for the wild type control, genetic knockout of RNase J and CRISPR/Cas9 (DNA cleavage defiecient) regulated knockdowns of PNPase and RNase E along with a control strain expressing solely the Cas9 enzyme, not the target sgRNA. We have found that removal of RNase J had little effect on the transcriptional profile of investigated strain, while depletion of PNPase or RNase E altered about a quarter of the entire transcriptome, including changes to non-coding RNA.

Project description:8-oxo-7,8-dihydroguanine (8-oxoG) is a common RNA oxidation that has been implicated in carcinogenesis, neurodegeneration, and aging. Some? Many? RNA-binding proteins have shown binding preference for 8-oxoG modified RNA; such binding? can protect cells from oxidative stress. To date, the presence of specific 8-oxoG-recognizing proteins is only known in model organisms, but, how these proteins cooperate is still unclear. Here, we use RNA affinity chromatography and mass spectrometry to search for proteins that specifically bind 8-oxoG-modified RNA in Deinococcus radiodurans, an extremophilic bacterium with extraordinary resistance to oxidative stresses. We identified four proteins that selectively bind to oxidized RNA: polynucleotide phosphorylase (DR_2063/PNPase), ATP-dependent DEAD-box RNA helicase (DR_0335/RhlB), ribosomal protein S1 (DR_1983/RpsA), and transcriptional termination factor (DR_1338/Rho). The knockout of PNPase and RhlB in D. radiodurans caused increased sensitivity to hydrogen peroxide and a significant accumulation of 8-oxoG modified RNA. Importantly, PNPase directly interacts with RhlB in D. radiodurans; however, no additional phenotypic effect was observed for the double deletion of pnp and rhlB compared to the individual single deletions. Overall, our findings suggest a role of the PNPase-RhlB complex in targeting 8-oxoG-modified RNAs for rapid degradation and thereby constitutes an important component of D. radiodurans resistance to oxidative stress.

Project description:8-oxo-7,8-dihydroguanine (8-oxoG) is a common RNA oxidation that has been implicated in carcinogenesis, neurodegeneration, and aging. Some? Many? RNA-binding proteins have shown binding preference for 8-oxoG modified RNA; such binding? can protect cells from oxidative stress. To date, the presence of specific 8-oxoG-recognizing proteins is only known in model organisms, but, how these proteins cooperate is still unclear. Here, we use RNA affinity chromatography and mass spectrometry to search for proteins that specifically bind 8-oxoG-modified RNA in Deinococcus radiodurans, an extremophilic bacterium with extraordinary resistance to oxidative stresses. We identified four proteins that selectively bind to oxidized RNA: polynucleotide phosphorylase (DR_2063/PNPase), ATP-dependent DEAD-box RNA helicase (DR_0335/RhlB), ribosomal protein S1 (DR_1983/RpsA), and transcriptional termination factor (DR_1338/Rho). The knockout of PNPase and RhlB in D. radiodurans caused increased sensitivity to hydrogen peroxide and a significant accumulation of 8-oxoG modified RNA. Importantly, PNPase directly interacts with RhlB in D. radiodurans; however, no additional phenotypic effect was observed for the double deletion of pnp and rhlB compared to the individual single deletions. Overall, our findings suggest a role of the PNPase-RhlB complex in targeting 8-oxoG-modified RNAs for rapid degradation and thereby constitutes an important component of D. radiodurans resistance to oxidative stress.

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:mRNA decay in E. Coli degradosome mutants and their parental strains following transcriptional arrest with rifampicin. Abstract: RNase E, an essential endoribonuclease of Escherichia coli, interacts through its C-terminal region with multiple other proteins to form a complex termed the RNA degradosome. To investigate the degradosome's proposed role as an RNA decay machine, we used DNA microarrays to globally assess alterations in the steady-state abundance and decay of 4,289 E. coli mRNAs at single-gene resolution in bacteria carrying mutations in the degradosome constituents RNase E, polynucleotide phosphorylase, RhlB helicase, and enolase. Our results show that the functions of all four of these proteins are necessary for normal mRNA turnover. We identified specific transcripts and functionally distinguishable transcript classes whose half-life and abundance were affected congruently by multiple degradosome proteins, affected differentially by mutations in degradosome constituents, or not detectably altered by degradosome mutations. Our results, which argue that decay of some E. coli mRNAs in vivo depends on the action of assembled degradosomes, whereas others are acted on by degradosome proteins functioning independently of the complex, imply the existence of structural features or biochemical factors that target specific classes of mRNAs for decay by degradosomes. An RNA stablity experiment design type examines stability and/or decay of RNA transcripts. User Defined

Project description:This SuperSeries is composed of the following subset Series: GSE3977: Comparative Transcript Abundance in E. Coli Degradosome Mutants and their Parental Strains GSE3978: mRNA Decay in E. Coli Degradosome Mutants and their Parental Strains Abstract: RNase E, an essential endoribonuclease of Escherichia coli, interacts through its C-terminal region with multiple other proteins to form a complex termed the RNA degradosome. To investigate the degradosome's proposed role as an RNA decay machine, we used DNA microarrays to globally assess alterations in the steady-state abundance and decay of 4,289 E. coli mRNAs at single-gene resolution in bacteria carrying mutations in the degradosome constituents RNase E, polynucleotide phosphorylase, RhlB helicase, and enolase. Our results show that the functions of all four of these proteins are necessary for normal mRNA turnover. We identified specific transcripts and functionally distinguishable transcript classes whose half-life and abundance were affected congruently by multiple degradosome proteins, affected differentially by mutations in degradosome constituents, or not detectably altered by degradosome mutations. Our results, which argue that decay of some E. coli mRNAs in vivo depends on the action of assembled degradosomes, whereas others are acted on by degradosome proteins functioning independently of the complex, imply the existence of structural features or biochemical factors that target specific classes of mRNAs for decay by degradosomes Refer to individual Series

Project description:mRNA decay in E. Coli degradosome mutants and their parental strains following transcriptional arrest with rifampicin. Abstract: RNase E, an essential endoribonuclease of Escherichia coli, interacts through its C-terminal region with multiple other proteins to form a complex termed the RNA degradosome. To investigate the degradosome's proposed role as an RNA decay machine, we used DNA microarrays to globally assess alterations in the steady-state abundance and decay of 4,289 E. coli mRNAs at single-gene resolution in bacteria carrying mutations in the degradosome constituents RNase E, polynucleotide phosphorylase, RhlB helicase, and enolase. Our results show that the functions of all four of these proteins are necessary for normal mRNA turnover. We identified specific transcripts and functionally distinguishable transcript classes whose half-life and abundance were affected congruently by multiple degradosome proteins, affected differentially by mutations in degradosome constituents, or not detectably altered by degradosome mutations. Our results, which argue that decay of some E. coli mRNAs in vivo depends on the action of assembled degradosomes, whereas others are acted on by degradosome proteins functioning independently of the complex, imply the existence of structural features or biochemical factors that target specific classes of mRNAs for decay by degradosomes. An RNA stablity experiment design type examines stability and/or decay of RNA transcripts. Keywords: RNA_stability_design

Project description:Localization of RNase E to the inner membrane in Escherichia coli is well documented, but the functional consequences of this localization are largely unknown. Here we characterize the rne∆MTS strain, which expresses cytoplasmic RNase E (cRNase E). CsrB and CsrC regulatory RNAs are stabilized in the rne∆MTS strain resulting in leaky glycogen expression. There is a small but significant global slowdown in mRNA degradation with no bias considering function or localization of encoded proteins. RNase E is a stable protein, but cRNase E is unstable with a half-life equal to the doubling time of exponentially growing cells. cRNase E instability is compensated by increased synthesis. Co-purification experiments show that cRNase E associates with RhlB, enolase and PNPase to form a cytoplasmic RNA degradosome. Measurements in multiple turnover assays show that there is no difference in Km or kcat between cRNase E and RNase E. In contrast to the global slowdown of mRNA degradation, the inactivation of a ribosome-free lacZ transcript is faster in the rne∆MTS strain. We discuss how the association of RNase E with the inner cytoplasmic membrane is important for carbon storage regulation, degradation of polyribosomal mRNA, protection of ribosome-free transcripts from inactivation and stability of RNase E.