Project description:Gas exchange in the mammalian lung occurs in the alveolar sacs lined by epithelial cells that form a barrier allowing effective oxygen diffusion. Telomere syndromes have their most common manifestation in degenerative disease of the alveoli, both pulmonary fibrosis and emphysema. We tested the role of telomere dysfunction by inducing deletion of the telomere binding protein Trf2 in type 2 alveolar epithelial cells (AEC2s) that both express the gene encoding surfactant protein C and constitute the regenerative compartment of the alveolar epithelium. Acquired telomere dysfunction in these cells preferentially induced cellular senescence, and mouse lungs were marked by an inflammatory response even though the telomere dysfunction was restricted to the epithelium. Senescent AECs had altered gene expression that differentially fell in inflammatory cell signaling pathways. Bleomycin challenge was uniformly fatal, and Trf2-depleted cells failed to generate clonal alveolar colonies in vitro. The telomere dysfunction response in AEC2s was in part p53-dependent, and we found evidence of a p53-mediated paracrine survival signal to the mesenchyme. These data indicate that telomere dysfunction in the alveolar epithelium limits its regenerative capacity and is sufficient to induce inflammation. It may thus be a primary driving event in telomere-mediated lung disease. Efforts to restore epithelial regenerative capacity may be an effective approach in a subset of fibrosis and emphysema patients. We studied the gene expression changes in adult type II pneumocytes 7 days after deleting Trf2. Mice carried floxed allele of Trf2 and mTmG reporter allele. Type II pneumocytes were collected by FACs sorting GFP+ cells from lungs 7 days after administering tamoxifen. 6 total samples were analysed. Three were from control samples that were heterozygous for Trf2 and three samples had Trf2 deleted.

Project description:Gas exchange in the mammalian lung occurs in the alveolar sacs lined by epithelial cells that form a barrier allowing effective oxygen diffusion. Telomere syndromes have their most common manifestation in degenerative disease of the alveoli, both pulmonary fibrosis and emphysema. We tested the role of telomere dysfunction by inducing deletion of the telomere binding protein Trf2 in type 2 alveolar epithelial cells (AEC2s) that both express the gene encoding surfactant protein C and constitute the regenerative compartment of the alveolar epithelium. Acquired telomere dysfunction in these cells preferentially induced cellular senescence, and mouse lungs were marked by an inflammatory response even though the telomere dysfunction was restricted to the epithelium. Senescent AECs had altered gene expression that differentially fell in inflammatory cell signaling pathways. Bleomycin challenge was uniformly fatal, and Trf2-depleted cells failed to generate clonal alveolar colonies in vitro. The telomere dysfunction response in AEC2s was in part p53-dependent, and we found evidence of a p53-mediated paracrine survival signal to the mesenchyme. These data indicate that telomere dysfunction in the alveolar epithelium limits its regenerative capacity and is sufficient to induce inflammation. It may thus be a primary driving event in telomere-mediated lung disease. Efforts to restore epithelial regenerative capacity may be an effective approach in a subset of fibrosis and emphysema patients. We studied the gene expression changes in adult type II pneumocytes 7 days after deleting Trf2. Mice carried floxed allele of Trf2 and mTmG reporter allele. Type II pneumocytes were collected by FACs sorting GFP+ cells from lungs 7 days after administering tamoxifen.

Project description:Molecular distinctions between the stasis and telomere attrition senescence barriers in cultured human mammary epithelial cells Normal human epithelial cells in culture have generally shown a limited proliferative potential of ~10-40 population doublings before encountering a stress-associated senescence barrier (stasis) associated with elevated levels of cyclin-dependent kinase inhibitors p16 and/or p21. We now show that simple changes in media composition can expand the proliferative potential of human mammary epithelial cells (HMEC) initiated as primary cultures to 50-60 population doublings, followed by p16(+), senescence-associated b-galactosidase(+) stasis. We compared the properties of growing and senescent pre-stasis HMEC with growing and senescent post-selection HMEC, i.e., cells grown in a serum-free medium that overcame stasis via silencing of p16 expression and that display senescence associated with telomere dysfunction. Cultured pre-stasis populations contained cells expressing markers associated with luminal and myoepithelial HMEC lineages in vivo, in contrast to the basal-like phenotype of the post-selection HMEC. Gene transcript and protein expression, DNA damage-associated markers, mean TRF length, and genomic stability, differed significantly between HMEC populations at the stasis vs. telomere attrition senescence barriers. Senescent isogenic fibroblasts showed greater similarity to HMEC at stasis than at telomere attrition, although their gene transcript profile was distinct from HMEC at both senescence barriers. These studies support our model of the senescence barriers encountered by cultured HMEC in which the first barrier, stasis, is Rb-mediated and independent of telomere length, while a second barrier (agonescence or crisis) results from telomere attrition leading to telomere dysfunction. Additionally, the ability to maintain long-term growth of genomically stable multi-lineage pre-stasis HMEC populations can greatly enhance experimentation with normal HMEC. 48 samples from Human Mammary Epithelial cells which includes samples from four different individuals at different passage levels which includes prestasis,intermediate,post selection and agonesence stages of cell cycle.

Project description:Telomere dysfunction is the most common identifiable cause of pulmonary fibrosis. Cellular senescence of epithlial cells is thought to play a signfiicant role in disease pathogensis. We established a model of cellular senescence using a human alveolar epithelilial-like cell lines (A549) and profiled the transcriptional changes that occur in response to telomere dyfunction. Telomere dysfunction was induced by expressing a dominant-negative form TRF2, the shelterin binding protein.

Project description:Molecular distinctions between the stasis and telomere attrition senescence barriers in cultured human mammary epithelial cells Normal human epithelial cells in culture have generally shown a limited proliferative potential of ~10-40 population doublings before encountering a stress-associated senescence barrier (stasis) associated with elevated levels of cyclin-dependent kinase inhibitors p16 and/or p21. We now show that simple changes in media composition can expand the proliferative potential of human mammary epithelial cells (HMEC) initiated as primary cultures to 50-60 population doublings, followed by p16(+), senescence-associated b-galactosidase(+) stasis. We compared the properties of growing and senescent pre-stasis HMEC with growing and senescent post-selection HMEC, i.e., cells grown in a serum-free medium that overcame stasis via silencing of p16 expression and that display senescence associated with telomere dysfunction. Cultured pre-stasis populations contained cells expressing markers associated with luminal and myoepithelial HMEC lineages in vivo, in contrast to the basal-like phenotype of the post-selection HMEC. Gene transcript and protein expression, DNA damage-associated markers, mean TRF length, and genomic stability, differed significantly between HMEC populations at the stasis vs. telomere attrition senescence barriers. Senescent isogenic fibroblasts showed greater similarity to HMEC at stasis than at telomere attrition, although their gene transcript profile was distinct from HMEC at both senescence barriers. These studies support our model of the senescence barriers encountered by cultured HMEC in which the first barrier, stasis, is Rb-mediated and independent of telomere length, while a second barrier (agonescence or crisis) results from telomere attrition leading to telomere dysfunction. Additionally, the ability to maintain long-term growth of genomically stable multi-lineage pre-stasis HMEC populations can greatly enhance experimentation with normal HMEC.

Project description:Oncogene-induced senescence provides a barrier against malignant transformation. Senescent cells secrete pro-inflammatory cytokines, chemokines and growth factors collectively known as the senescence-associated secretory phenotype (SASP). Paradoxically, the SASP can also negatively impact the neighbouring tissues through inducing an inflammatory environment that promotes tumorigenesis and aged-related pathologies. We have previously shown that the lncRNA MIR31HG is overexpressed and located in the cytoplasm during BRAF-induced senescence. In young proliferating cells, nuclear MIR31HG inhibits p16/CDKN2A expression through interaction with polycomb repressor complexes (PRC1/2). Here, we show that MIR31HG regulates the expression and secretion of a subset of SASP components during BRAF-induced senescence. The SASP secreted from senescent cells depleted for MIR31HG fails to induce paracrine invasion without affecting the growth inhibitory effect. Mechanistically, MIR31HG interacts with the translation factor YBX1 facilitating its phosphorylation at serine 102 (p-YBX1S102) by the kinase RSK. p-YBX1S102 induces IL1A translation which acts as upstream regulator inducing the transcription of the other SASP mRNAs. Our results suggest a dual role for MIR31HG in senescence depending on its cellular localization and place the lncRNA as a potential therapeutic target in the treatment of senescence-related pathologies.

Project description:Cellular senescence is a stress or damage response that causes a permanent proliferative arrest and secretion of numerous factors with potent biological activities. This senescence-associated secretory phenotype (SASP) has been characterized largely for secreted proteins that participate in embryogenesis, wound healing, inflammation and many age-related pathologies. By contrast, lipid components of the SASP are understudied. We show that senescent cells activate the biosynthesis of several oxylipins that promote segments of the SASP and reinforce the proliferative arrest. Notably, senescent cells synthesize and accumulate an unstudied intracellular prostaglandin, 1a,1b-dihomo-15-deoxy-delta-12,14-prostaglandin J2. Released 15-deoxy-delta-12,14-prostaglandin J2 is a biomarker of senolysis in culture and in vivo. This and other prostaglandin D2-related lipids promote the senescence arrest and SASP by activating RAS signaling. These data identify an important aspect of cellular senescence and a method to detect senolysis

Project description:Oncogene-induced senescence (OIS) and therapy-induced senescence (TIS), while tumor-suppressive, also promote procarcinogenic effects by activating the DNA damage response (DDR), which in turn induces inflammation. This inflammatory response prominently includes an array of cytokines known as the senescence-associated secretory phenotype (SASP). Previous observations link the transcription-associated methyltransferase and oncoprotein MLL1 to the DDR, leading us to investigate the role of MLL1 in SASP expression. Our findings reveal direct MLL1 epigenetic control over proproliferative cell cycle genes: MLL1 inhibition represses expression of proproliferative cell cycle regulators required for DNA replication and DDR activation, thus disabling SASP expression. Strikingly, however, these effects of MLL1 inhibition on SASP gene expression do not impair OIS and, furthermore, abolish the ability of the SASP to enhance cancer cell proliferation. More broadly, MLL1 inhibition also reduces “SASP-like” inflammatory gene expression from cancer cells in vitro and in vivo independently of senescence. Taken together, these data demonstrate that MLL1 inhibition may be a powerful and effective strategy for inducing cancerous growth arrest through the direct epigenetic regulation of proliferation-promoting genes and the avoidance of deleterious OIS- or TIS-related tumor secretomes, which can promote both drug resistance and tumor progression. This study consists of a single replicate of RNA-seq from oncogene-induced senescent (or control) IMR90 cells in a MLL1 knockdown (or WT) background, for a total of four samples

Project description:Epithelial senescence, specifically in the bronchiolized regions of the fibrotic lung, is apparent in IPF but not control tissue. In order to better understand the phenotype of these senescent cells we generated a in vitro culture model of senescence utillizing primary normal human bronchial epithelial cells. Cultures were treated with doxorubicin to induce senescence and the transcriptional phenotype of the senescent cultures was compared to DMSO-treated control cultures.

Project description:Evidence is accumulating that senescence drives cure in various murine and human malignancies. We demonstrate that metronomic, repetitive low-dose topotecan treatment leads to tumor cell senescence in vitro and in vivo and long-term cure in a model for the aggressive childhood cancer neuroblastoma. By using the senescence-associated secretory phenotype (SASP) as a discriminator for beneficial versus adverse effects of senescence, we identified topotecan as inducer of a favorable SASP. Senescent tumor cells are growth arrested and act growth inhibitory on co-cultured non-senescent tumor cells. MYCN oncogene amplification and expression, hallmarks of aggressive neuroblastoma, are significantly reduced, supporting an initial transition to a more favorable phenotype. These new aspects of metronomic drug treatment are clinically relevant and might apply to other tumor entities. Keywords: stress response, therapy induced senescence, cellular response, cancer treatment, neuroblastoma