Project description:RNase E is involved in the post-transcriptional gene regulation of a broad spectrom of RNA species involving in different biological processes. Frequently RNase E cooperates with other protein components to form a RNA degradosome to regulate gene expression. Here, we aim to study the impact of RNA degradosome formation on E. coli gene expression by comparing the whole transcriptiome isolate from wildtype Rne strain and Rne C-terminal truncated strain that deleting the RNA degradosome binding domain. We choose to study the bacterial growth conditions in soft-agar culture because it is a condition more silimar to that in the gut of warm-blooded organism compared to merely liquid culture condition.Here we found different groups of transcript that was affected by Rne C-termianl truncation mutant. Altogether, our data give insight into the complex regulation of RNase E/RNA degradosome in transcripts involved in different biological processes of soft-agar growing system.

Project description:Effect of different N-terminal catalytic activity of RNase E compared to full-length RNase E on whole transcriptome expression profile of E. coli soft-agar plate culture

Project description:The RNA degradosome, a multi-protein complex regulating mRNA levels in bacteria, assembles in Pseudomonadota (Proteobacteria) on the RNase E C-terminal domain (CTD) via short linear motifs (SLiMs) that bind other RNA degradosome components and RNA. The composition of Pseudomonas aeruginosa RNA degradosome remains unknown, and its RNase E CTD shows limited similarity to those in well-studied Proteobacteria models like Escherichia coli or Caulobacter crescentus. Our study identified and characterized the SLiMs in P. aeruginosa RNase E, revealing a large duplicated sequence termed the 'REER-repeats' region. This region, along with AR1 and AR4 SLiMs, mediates RNase E CTD RNA binding and is necessary for the subcellular localization of the RNA degradosome in foci. Pull-down and bacterial two-hybrid assays identified PNPase and RhlB as RNase E-interacting proteins. We confirmed through protein-protein binding assays that PNPase and RhlB directly interact with RNase E, and additionally show that the interactions are mediated by the NDPR and AR1 SLiMs, respectively. Additionally, we confirm that the RhlE2 RNA helicase interacts with RNase E, but this interaction involves RNase E N-terminal domain. Finally, we show that RNase E CTD truncations are impaired in growth on cold and mutations affecting CTD RNA binding impaired twitching motility and virulence in a Galleria mellonella infection model. This study elucidates and highlights the critical role of RNase E CTD-mediated RNA binding and RNA degradosome assembly in the virulence and adaptability of P. aeruginosa.

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:Abstract: Ribonuclease E (RNase E) has a key role in mRNA degradation and the processing of catalytic and structural RNAs in E. coli. We report the discovery of an evolutionarily conserved 17.4 kDa protein, here named RraA (regulator of ribonuclease activity A) that binds to RNase E and inhibits RNase E endonucleolytic cleavages without altering cleavage site specificity or interacting detectably with substrate RNAs. Overexpression of RraA circumvents the effects of an autoregulatory mechanism that normally maintains the RNase E cellular level within a narrow range, resulting in the genome-wide accumulation of RNase E-targeted transcripts. While not required for RraA action, the C-terminal RNase E region that serves as a scaffold for formation of a multiprotein degradosome complex modulates the inhibition of RNase E catalytic activity by RraA. Our results reveal a possible mechanism for the dynamic regulation of RNA decay and processing by inhibitory RNase binding proteins. This SuperSeries is composed of the SubSeries listed below.

Project description:This SuperSeries is composed of the following subset Series: GSE3869: Effects of rraA deletion on transcription GSE3870: Effects of rraA overexpression on transcription Abstract: Ribonuclease E (RNase E) has a key role in mRNA degradation and the processing of catalytic and structural RNAs in E. coli. We report the discovery of an evolutionarily conserved 17.4 kDa protein, here named RraA (regulator of ribonuclease activity A) that binds to RNase E and inhibits RNase E endonucleolytic cleavages without altering cleavage site specificity or interacting detectably with substrate RNAs. Overexpression of RraA circumvents the effects of an autoregulatory mechanism that normally maintains the RNase E cellular level within a narrow range, resulting in the genome-wide accumulation of RNase E-targeted transcripts. While not required for RraA action, the C-terminal RNase E region that serves as a scaffold for formation of a multiprotein degradosome complex modulates the inhibition of RNase E catalytic activity by RraA. Our results reveal a possible mechanism for the dynamic regulation of RNA decay and processing by inhibitory RNase binding proteins. Refer to individual Series

Project description:Effect of RNase E mutations on whole transcriptome expression profile of E. coli soft-agar plate culture

Project description:In Helicobacter pylori, the major actor in post-transcriptional regulation is an RNA degradosome assembly composed of the essential ribonuclease RNase J and the DEAD-box RNA helicase RhpA. Here, we describe the oligomeric state and post-translational modifications of this protein complex. Our crystal structure of RNase J at 2.75 Å resolution reveals a homotetrameric quaternary state, and solution studies show that purified RNase J forms monomers and dimers, that RhpA is a monomer, and that the two proteins interact to form a stable complex with a 1:1 stoichiometry. Using mass spectrometry, we observed that RNase J is acetylated on multiple residues, one of which, K649, is important for RNase J oligomerization. Mutations targeting this residue and others affect the dimerization and in vitro activity of RNase J, suggesting that the dimer is the active form. In H. pylori, we observed that several of the identified acetylated residues impact on cell morphology, suggesting their importance for RNase J cellular function. Using H. pylori mutants, we found that several pathways contribute to RNase J acetylation. We propose acetylation as a regulatory level controlling RNase J properties and as a consequence the activity of the H. pylori RNA degradosome.

Project description:Many bacteria and archaea use CRISPR-Cas systems, which provide RNA-based, adaptive, and inheritable immune defenses against invading viruses and other foreign genetic elements. The proper processing of CRISPR guide RNAs (crRNAs) is a crucial step in the maturation of the defense complexes and is frequently performed by specialized ribonucleases encoded by cas genes. However, some systems employ enzymes associated with degradosome or housekeeping functions, such as RNase III or the endoribonuclease RNase E. Here, the endo- and 5´-exoribonuclease RNase J was identified as additional enzyme involved in crRNA maturation, acting jointly with RNase E in the crRNA maturation of a type III-Bv CRISPR-Cas system, and possibly together with a further RNase. Co-IP experiments revealed a small set of proteins that were co-enriched with RNase J, among them PNPase. Despite a measured, strong 3’ exonucleolytic activity of the recombinant enzyme, PNPase was not confirmed to contribute to crRNA maturation. However, the co-IP results indicate that PNPase is a component of the cyanobacterial degradosome that can recruit either RNase E or RNase J, together with additional enriched proteins.

Project description:The impact of RNase E C-terminal truncation mutant compared with wildtype RNase E on whole transcriptome expression profile of E. coli soft-agar plate culture