Project description:The recently proposed exozyme hypothesis posits that subunits of the RNA processing exosome assemble into structurally distinct protein complexes that function in disparate cellular compartments and RNA metabolic pathways. Here, in a genetic test of this hypothesis, we examine the role of Dis3 -- an essential polypeptide with endo- and 3' to 5' exo-ribonuclease activity -- in cell cycle progression. We present several lines of evidence that perturbation of DIS3 affects microtubule (MT) localization and structure in Saccharomyces cerevisiae. Cells with a DIS3 mutation: (i) accumulate anaphase and pre-anaphase mitotic spindles; (ii) exhibit spindles that are mis-oriented and displaced from the bud neck; (iii) harbor elongated spindle-associated astral MTs; (iv) have an increased G1 astral MT length and number; and (v) are hypersensitive to MT poisons. Mutations in the core exosome genes RRP4 and MTR3 and the exosome cofactor gene MTR4 -- but not other exosome subunit gene mutants -- also elicit MT phenotypes. RNA deep sequencing analysis (RNA-seq) shows broad changes in the levels of cell cycle- and microtubule-related transcripts in mutant strains. Collectively, the different mitotic phenotypes and distinct sets of mRNAs affected by the exosome subunit and cofactor mutants studied here suggest that Dis3 has a core exosome-independent role(s) in cell cycle progression. These observations are consistent with the predictions of the exozyme hypothesis and also suggest an evolutionarily conserved role for Dis3 in linking RNA metabolism, MTs, and mitotic progression.

Project description:The recently proposed exozyme hypothesis posits that subunits of the RNA processing exosome assemble into structurally distinct protein complexes that function in disparate cellular compartments and RNA metabolic pathways. Here, in a genetic test of this hypothesis, we examine the role of Dis3 -- an essential polypeptide with endo- and 3' to 5' exo-ribonuclease activity -- in cell cycle progression. We present several lines of evidence that perturbation of DIS3 affects microtubule (MT) localization and structure in Saccharomyces cerevisiae. Cells with a DIS3 mutation: (i) accumulate anaphase and pre-anaphase mitotic spindles; (ii) exhibit spindles that are mis-oriented and displaced from the bud neck; (iii) harbor elongated spindle-associated astral MTs; (iv) have an increased G1 astral MT length and number; and (v) are hypersensitive to MT poisons. Mutations in the core exosome genes RRP4 and MTR3 and the exosome cofactor gene MTR4 -- but not other exosome subunit gene mutants -- also elicit MT phenotypes. RNA deep sequencing analysis (RNA-seq) shows broad changes in the levels of cell cycle- and microtubule-related transcripts in mutant strains. Collectively, the different mitotic phenotypes and distinct sets of mRNAs affected by the exosome subunit and cofactor mutants studied here suggest that Dis3 has a core exosome-independent role(s) in cell cycle progression. These observations are consistent with the predictions of the exozyme hypothesis and also suggest an evolutionarily conserved role for Dis3 in linking RNA metabolism, MTs, and mitotic progression. RNA-seq analysis of total RNA harvested from WT, mtr3-1, mtr4-1, and Dis3^mtr (rrp44-1/mtr17-1) Saccharomyces cerevisiae strains after a temperature shift.

Project description:Cellular senescence is a stable arrest of proliferation and is considered a key component of processes associated with carcinogenesis and other ageing-related phenotypes. However, till now, biological markers that define senescence on a genome-wide scale have been limited. Here, we report a DNA methylomic analysis of actively dividing and deeply senescent normal human epithelial cells, identifying 3,852 senescence-associated differentially methylated positions (senDMPs). We find that this human senDMP signature is positively and significantly correlated with both cancer and ageing-associated methylomic dynamics. We also identify germline genetic variants, including those associated with the p16INK4A locus, that are associated with the presence of in vivo senDMP signatures. Importantly, we also demonstrate that the senDMP signature can be effectively reversed in a newly-developed protocol of transient cellular rejuvenation. The senDMP signature has significant potential for understanding some of the key (epi)genetic etiological factors that lead to cancer and age-related diseases in humans. Bisulphite converted DNA from the HMECs at early passage (EP), deep senescence (DS), deep senescence + p16 siRNA (DS+p16siRNA) at two different time points and FACS for cell cycle at EP were hybridised to the Illumina Infinium 450k Human Methylation Beadchip

Project description:Cellular senescence is a stable arrest of proliferation and is considered a key component of processes associated with carcinogenesis and other ageing-related phenotypes. However, till now, biological markers that define senescence on a genome-wide scale have been limited. Here, we report a DNA methylomic analysis of actively dividing and deeply senescent normal human epithelial cells, identifying 3,852 senescence-associated differentially methylated positions (senDMPs). We find that this human senDMP signature is positively and significantly correlated with both cancer and ageing-associated methylomic dynamics. We also identify germline genetic variants, including those associated with the p16INK4A locus, that are associated with the presence of in vivo senDMP signatures. Importantly, we also demonstrate that the senDMP signature can be effectively reversed in a newly-developed protocol of transient cellular rejuvenation. The senDMP signature has significant potential for understanding some of the key (epi)genetic etiological factors that lead to cancer and age-related diseases in humans. Bisulphite converted DNA from the HMECs at early passage (EP), deep senescence (DS), deep senescence + p16 siRNA (DS+p16siRNA) at two different time points and FACS for cell cycle at EP were hybridised to the Illumina Infinium 450k Human Methylation Beadchip

Project description:Cellular senescence is a stable arrest of proliferation and is considered a key component of processes associated with carcinogenesis and other ageing-related phenotypes. However, till now, biological markers that define senescence on a genome-wide scale have been limited. Here, we report a DNA methylomic analysis of actively dividing and deeply senescent normal human epithelial cells, identifying 3,852 senescence-associated differentially methylated positions (senDMPs). We find that this human senDMP signature is positively and significantly correlated with both cancer and ageing-associated methylomic dynamics. We also identify germline genetic variants, including those associated with the p16INK4A locus, that are associated with the presence of in vivo senDMP signatures. Importantly, we also demonstrate that the senDMP signature can be effectively reversed in a newly-developed protocol of transient cellular rejuvenation. The senDMP signature has significant potential for understanding some of the key (epi)genetic etiological factors that lead to cancer and age-related diseases in humans. Total RNA obtained from the HMECs at early passage (EP) and deep senescence (DS)

Project description:Among the different chemotherapies available, genotoxic drugs are widely used. In response to these drugs, particularly doxorubicin, tumor cells can enter into senescence. Chemotherapy-induced senescence (CIS) is a complex response. Long described as a definitive arrest of cell proliferation, we and various groups have shown that this state may not be complete and could allow certain cells to reproliferate. The mechanism could be due to the activation of new signaling pathways. In the laboratory, we study the proteins involved in these pathways and triggering cell proliferation. In this study, we determine a new role for Anterior Gradient protein 2 (AGR2) in vivo in patients and in vitro in a senescence escape model. We used proteomic studies of patients’ samples and cell lines, and also RNA interference to assess the implication of AGR2 in breast cancer and proliferation of senescent cells. First, we identified AGR2, and found that its concentration is higher in the serum of breast cancer patients and that this high concentration is associated with metastasis occurrence. We also observed an inverse correlation between intratumoral AGR2 expression and the senescence marker p16. This observation led us to study AGR2’s role in the CIS escape model. In this model, we found that AGR2 is overexpressed in cells during senescence escape and its loss considerably reduces that phenomenon. Furthermore, we showed that the extracellular form eAGR2 stimulated the reproliferation of senescent cells. The power of proteomic analysis based on the SWATH-MS approach allowed us to highlight the mTOR/AKT signaling pathway in the senescence escape mechanism mediated by AGR2. Analysis of the two signaling pathways revealed that AGR2 modulates RICTOR phosphorylation. All these results show that AGR2 is a breast cancer biomarker and regulates CIS escape via activation of the mTORC2/AKT signaling pathway.

Project description:The null pacman allele pcm[14] causes at lethaility pupariation. Lethality can be rescued by driving expression of wild-type pacman in somatic cells during development using the UAS-GAL4 system. Use of the driver arm-GAL4 allows adult flies to develop, but pacman is not expressed in the germline cells. RNA was prepared from null pacman testes from rescued flies, parental controls (UAS line and GAL4 line) and from a genetic background control for pcm[14] (a line generated by a neutral excision of the P-element used to induce the pcm[14] deletion). Total RNA was prepared from adult Drosophila testes. Sequencing of each genotype was replicated 3 times with a read depth of 12-15 million reads per replicate.

Project description:This SuperSeries is composed of the following subset Series: GSE35265: Analysis of global gene expression profiles of hPAF1 deficiency on unstimulated A549 cells GSE35266: Analysis of global gene expression profiles of hPAF1 deficient A549 cells during infection with H1N1 influenza A virus or vesicular stomatitis virus (VSV) GSE35267: Analysis of global gene expression profiles of hPAF1 deficient A549 cells during stimulation with PR8/?NS1 influenza virus, IFN?1 or Poly(I:C) Refer to individual Series

Project description:Viral infection is commonly associated with virus-driven hijacking of host proteins. We describe a novel mechanism by which influenza virus impacts host cells through the interaction of influenza NS1 protein with the infected cell epigenome. We show that the NS1 protein of influenza A H3N2 targets the transcription elongation PAF1 complex (hPAF1C). We demonstrate that binding of NS1 to hPAF1C results in suppression of hPAF1C-mediated transcriptional elongation. More importantly,in the following data sets, we show that hPAF1 plays a crucial role in the antiviral response. Loss of hPAF1C reduces antiviral gene expression and reduces inducible transcription of target genes after stimulation with viral RNA analogue poly(I:C), vesicular stomatitis virus (VSV), exogenous recombinant IFN(beta) and influenza virus (H1N1). This study underscores the importance of hPAF1C in controlling inducible antiviral gene expression. A549 cells were untreated (no siRNA) or treated with control siRNA-treated and hPAF1 siRNA. Total RNA was isolated with the Qiagen RNeasy mini kit. 200ng of total RNA per sample was used to prepare biotin-labeled RNA using MessageAmp™ Premier RNA Amplification Kit (Applied Biosystems) and hybridized to HumanHT-12 v4 Expression BeadChips (Illumina). Data analysis was performed using the GeneSpring GX11.0 software (Agilent Technologies). These samples were then used for comparisons with stimulated cells (See series 1) 3 biological replicates per condition

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series