Project description:Cooperation of GRSF1 and the mitochondrial degradosome (hSuv3-PNPase complex) in degradation of mitochondrial RNA

Project description:The human mitochondrial degradosome is a complex of the ribonuclease PNPase (Q8TCS8, encoded by PNPT1 gene) and RNA helicase SUV3 (Q8IYB8, encoded by SUPV3L1 gene). The aim of the project was to identify proteins which co-purify with both subunits of the degradosome. To this end we used human 293 cells stably expressing hSuv3 or PNPase with a C-terminal TAP tag or TAP tag fused to a mitochondria targeting sequence (control bait) (cell lines are described in details in (PMID: 19864255). Mitochondria were isolated from the cells, lysed and the protein extracts were subjected to affinity chromatography. Co-purified proteins were identified by mass spectrometry and their amounts were quantified by a label-free approach (MaxQuant). These experiments are part of the project “Dedicated surveillance mechanism controls G-quadruplex forming non-coding RNAs in human mitochondria”.

Project description:Protein kinase RNA-activated (PKR) induces immune response by sensing viral double-stranded RNAs (dsRNAs). However, growing evidence suggests that PKR can also be activated by endogenously expressed dsRNAs. Here, we capture these dsRNAs by formaldehyde-mediated crosslinking and immunoprecipitation-sequencing and find that various noncoding RNAs interact with PKR. Surprisingly, the majority of the PKR-interacting RNA repertoire is occupied by mitochondrial RNAs (mtRNAs). MtRNAs can form intermolecular dsRNAs owing to bidirectional transcription of mitochondrial genome and regulate PKR and eIF2α phosphorylation to control cell signaling and translation. Moreover, PKR activation by mtRNAs is counteracted by PKR phosphatases, disruption of which causes apoptosis from PKR overactivation even in uninfected cells. Our work unveils dynamic regulation of PKR even without infection and establishes PKR as a sensor for nuclear and mitochondrial signaling cues in regulating cellular metabolism.

Project description: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 This SuperSeries is composed of the SubSeries listed below.

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:UV-crosslining of protein-RNA complexes was employed to capture sRNA-mRNA interactions occuring on the RNA degradosome protein, RNase E, in enterohaemorhaggic E. coli. Abstract from associated mansucript: In many organisms small regulatory RNAs (sRNA) play important roles in the regulation of gene expression by base-pairing to specific target mRNAs. In enterohaemorrhagic E. coli (EHEC), sRNAs are encoded by both the “core” genome and in numerous horizontally acquired pathogenicity islands. To identify functionally important sRNA-target RNA interactions we applied crosslinking and sequencing of hybrids (CLASH) to the core degradosome component RNase E in EHEC. RNase E was shown to bind to many classes of RNA, confirming the wide distribution of degradosome targets. These included several hundred sRNA-mRNA duplexes, and the distribution of non-templated oligo(A) tails indicated that the sRNA target RNase E-mediated cleavage at these interaction sites. Functional repression of target mRNAs was confirmed for the core sRNA RyhB, and the pathogenicity-associated sRNA Esr41. In the case of Esr41, three confirmed target mRNAs participate in iron accumulation and the ∆esr41 strain showed increased growth under conditions of iron limitation. We conclude that CLASH can be used to identify functional targets for bacterial sRNAs.

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: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:Comparative transcript abundance 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. A genetic modification design type is where an organism(s) has had genetic material removed, rearranged, mutagenized or added, such as knock out. Keywords: genetic_modification_design