Project description:EGFR inhibitor Erlotinib treatment can induce NHBE into profound cell cycle arrest that include senescence and quiescence. Because senescent cells feature high senescence assocaited-beta-galactosidase(SA-β-gal) activty, which has been used as marker for FACS based collection of senescent and quiescent cells, respectively.

Project description:The reactivation of quiescent cells to proliferate is fundamental to tissue repair and homeostasis in the body. Often referred to as the G0 state, quiescence is however not a uniform state but with graded depth. Shallow quiescent cells exhibit a higher tendency to revert to proliferation than deep quiescent cells, while deep quiescent cells are still fully reversible under physiological conditions, distinct from senescent cells. Cellular mechanisms underlying the control of quiescence depth and the connection between quiescence and senescence are poorly characterized, representing a missing link in our understanding of tissue homeostasis and regeneration. Here we measured transcriptome changes as rat embryonic fibroblasts moved from shallow to deep quiescence over time in the absence of growth signals. We found that lysosomal gene expression was significantly upregulated in deep quiescence, and partially compensated for gradually reduced autophagy flux. Reducing lysosomal function drove cells progressively deeper into quiescence and eventually into a senescence-like irreversibly arrested state; increasing lysosomal function, by lowering oxidative stress, progressively pushed cells into shallower quiescence. That is, lysosomal function modulates graded quiescence depth between proliferation and senescence as a dimmer switch. Lastly, we found that a gene expression signature developed by comparing deep and shallow quiescence in fibroblasts can correctly classify a wide array of senescent and aging cell types in vitro and in vivo, suggesting that while quiescence is generally considered to protect cells from irreversible arrest of senescence, quiescence deepening likely represents a common transition path from cell proliferation to senescence, related to aging.

Project description:Cellular senescence is a tumor-suppressive program that involves chromatin reorganization and specific changes in gene expression that trigger an irreversible cell-cycle arrest. We combined quantitative mass spectrometry and ChIP deep-sequencing to identify changes in histone modification occurring during cellular senescence. ChIP-seq was carried out using H3K4me3-specific antibodies in growing, quiescent, senescent, or senescent with shRB targeting Rb, IMR90 cells. The control mock data (ChIP-seq using anti-mouse IgG antibody) is available in GEO Sample GSM497500 (Series GSE19898).

Project description:Senescence is a state of stable cell cycle exit that has important implications for development, physiology and disease. It is distinct from quiescence in which cells can be induced to re-enter the cell cycle. Although it is well known that there are massive changes in the heterochromatin of senescent cells, the molecular mechanisms underpinning the transition from reversible quiescence into irreversible senescence have remained elusive. Here, we demonstrate that the chromatin-remodeling enzyme ATRX is required for senescence. ATRX accumulates in nuclear foci during both replicative and cellular senescence. Using ChIP-seq and RNA-seq we identified HRAS as part of an ATRX regulated gene expression program associated with senescence. Repression of HRAS is sufficient to promote the transition of quiescent cells into senescence. Thus we conclude that the repression of HRAS is likely a direct consequence of ATRX binding and critical to how it mediates its role in senescence.

Project description:Senescence is a state of stable cell cycle exit that has important implications for development, physiology and disease. It is distinct from quiescence in which cells can be induced to re-enter the cell cycle. Although it is well known that there are massive changes in the heterochromatin of senescent cells, the molecular mechanisms underpinning the transition from reversible quiescence into irreversible senescence have remained elusive. Here, we demonstrate that the chromatin-remodeling enzyme ATRX is required for senescence. ATRX accumulates in nuclear foci during both replicative and cellular senescence. Using ChIP-seq and RNA-seq we identified HRAS as part of an ATRX regulated gene expression program associated with senescence. Repression of HRAS is sufficient to promote the transition of quiescent cells into senescence. Thus we conclude that the repression of HRAS is likely a direct consequence of ATRX binding and critical to how it mediates its role in senescence.

Project description:Treatment-induced senescence (TIS) is a DNA damage-triggered stress-response program, resulting in terminal arrest of affected cells. TIS plays an important role in cancer therapy, as many tumor cells would undergo TIS instead of apoptosis when exposed to standard chemotherapy regimens. The contribution of TIS to overall disease outcome is, however, unclear. To address this, we use lymphoma cells with conditional expression of the senescence-essential factor Suv39h1 (regulatable by 4-hydroxi-tamoxifen). Only cells with active Suv39h1 would undergo TIS in response to chemotherapy. Suv39h1 inactivation during the chemo-treatment would prevent TIS induction, while inactivation in fully senescent cells would allow outgrowth from the TIS cell cycle arrest. Such post-senescent cells (PS) show very different biological behavior than the cells growing in senescence-incompetent setting - never senescent (NS). The molecular characteristics of each of these treatment conditions are analyzed here by assessing global transcriptome data. We used global gene expression profiling by microarrays to gain insight in the molecular programme underlying the chemotherapy response in primary Emu-myc transgenic B-cell lymphomas.

Project description:We applied in parallel RNA-Seq and Ribosome-profiling analyses to immortalized human primary BJ fibroblast cells under the following conditions: normal proliferation, quiescence (induced by serum depletion), senescence (induced by activation of the oncogenic RASG12V gene, and examined at early (5 days; pre-senescent state) and late (14 days; fully senescent state) time points), and neoplastic transformation (induced by RASG12V in the background of stable p53 and p16INK4A knockdowns and SV40 small-T expression. RNA-seq, using Illumina HiSeq 2000, was applied to BJ cells under 5 conditions: proliferation, quiescence, pre-senescence, full-senescence, and transfomed. Ribosome profiling, using Illumina HiSeq 2000, was applied to BJ cells under 5 conditions: proliferation, quiescence, pre-senescence, full-senescence, and transfomed.

Project description:In mammalian females, quiescent primordial follicles serve as the ovarian reserve and sustain normal ovarian function and egg production via folliculogenesis. The loss of primordial follicles causes ovarian aging. Cellular senescence, characterized by cell cycle arrest and production of the senescence-associated secretory phenotype (SASP), is associated with tissue aging. In the present study, we report that some quiescent primary oocytes in primordial follicles become senescent in adult mouse ovaries. The senescent primary oocytes share senescence markers characterized in senescent somatic cells. The senescent primary oocytes were observed in young adult mouse ovaries, remained at approximately 15% of the total primary oocytes during ovarian aging from 6 months to 12 months, and accumulated in aged ovaries. Administration of a senolytic drug ABT263 to 3-month-old mice reduced the percentage of senescent primary oocytes and the transcription of the SASP cytokines in the ovary. In addition, led to increased numbers of primordial and total follicles and a higher rate of oocyte maturation and female fertility. Our study provides experimental evidence that primary oocytes, a germline cell type that is arrested in meiosis, become senescent in adult mouse ovaries and that senescent cell clearance reduced primordial follicle loss and mitigated ovarian aging phenotypes.

Project description:Background: Although quiescence—reversible cell-cycle arrest—is a key part in the life history and fate of many mammalian cell types, the mechanisms of gene regulation in quiescent cells are poorly understood. We sought to clarify the role of microRNAs as regulators of the cellular functions of quiescent human fibroblasts. Results: Using microarrays, we discovered that the expression of the majority of profiled microRNAs differed between proliferating and quiescent fibroblasts. Fibroblasts induced into quiescence by contact inhibition or serum starvation had similar microRNA profiles, indicating common changes induced by distinct quiescence signals. By analyzing the gene expression patterns of microRNA target genes with quiescence, we discovered a strong regulatory function for miR-29, which is downregulated with quiescence. Using microarrays and immunoblotting, we confirmed that miR-29 targets genes encoding collagen and other extracellular matrix proteins and that those target genes are induced in quiescence. In addition, overexpression of miR-29 resulted in more rapid cell cycle re-entry from quiescence. We also found that let-7 and miR-125 were upregulated in quiescent cells. Overexpression of either one alone resulted in slower cell cycle re-entry from quiescence, while the combination of both together slowed cell cycle re-entry even further. Conclusions: microRNAs regulate key aspects of fibroblast quiescence including the proliferative state of the cells as well as their gene expression profiles, in particular, the induction of extracellular matrix proteins in quiescent fibroblasts. microRNAs in human neonatal dermal fibroblasts in 3 cell cycle conditions (proliferating, 4 days serum starved, 7 days contact inhibited) were analyzed by one color microarray. 3 separate fibroblast cell lines from different human donors were analyzed for each condition, with two separate labeling and hybridization samples for each cell line. In total, 18 samples were hybridized to the microRNA microarray.

Project description:As normal cells approach their proliferative limit, they arrest to undergo replicative senescence, displaying large cell size, flat morphology and activation of senescence-associated beta-galactosidase (SA-b-Gal). A subset of normal or tumor cells exposed in vitro or in vivo to chemotherapy agents such as etoposide perform a related response with a similar cellular phenotype dubbed therapy-induced senescence (TIS). High cellular heterogeneity in samples including TIS cells can impede confident determination of senescence-specific factors, frustrating discovery of markers and targets for functional analysis. As a TIS study model, we treated murine melanoma cells with the chemotherapeutic etoposide, applied a live-cell fluorescent SA-b-Gal senescence assay, and utilized fluorescence-activated cell sorting (FACS) to enrich TIS cells. Enriched senescent cell samples were subjected to mass spectrometry and label-free quantitative proteomics analysis, alongside proliferating and quiescent cell samples. Systems biology analysis revealed that senescent cells overexpress proteins and pathways regulating glycolipid processing, lipid metabolism, and lipid peroxidation. Senescence-associated activation of numerous glycosidases was observed, along with elevated cell surface expression of several major lipid regulatory proteins. Senescent cells were found to contain abundant lipid droplets and to import various types of extracellular lipids in correlation with extent of SA-b-Gal expression, and tumor cells were observed to spontaneously senesce in the presence of excess ceramide or triglycerides. Redox-induced lipid peroxidation, resulting in accumulation of cellular reactive aldehydes and consequent expression of aldehyde detoxification enzymes, was observed to be a key feature of TIS induced by three DNA-damaging chemotherapeutics.