Project description:PUVA pretreatment leads to develop early senescence confirmed by p16, p21 and SA-β-GAL positivity which was completely normalised by longer gap. Indicating that PUVA pretreatment causes conditioning set of genes that led to a marked delay in psoriasis development.

Project description:Aortic aneurysms are dilations of the aorta that can rupture when left untreated. We used aneurysmal Fibulin-4R/R to further unravel the underlying mechanisms of aneurysm formation. RNA sequencing of 3-month-old Fibulin-4R/R aortas revealed significant upregulation of senescence-associated secretory phenotype (SASP) factors and key senescence factors, indicating involvement of senescence. Analysis of aorta histology and of vascular smooth muscle cells (VSMCs) in vitro confirmed the senescent phenotype of Fibulin-4R/R VSMCs by revealing increased SA-β-gal, p21 and p16 staining, increased IL-6 secretion, increased presence of DNA damage foci and increased nuclei size. Additionally, we found that p21 luminescence was increased in the dilated aorta of Fibulin-4R/R|p21-Luciferase mice. Our studies identify a cellular aging cascade in Fibulin-4 aneurysmal disease, by revealing that Fibulin-4R/R aortic VSMCs have a pronounced SASP and a senescent phenotype that may underlie aortic wall degeneration. Additionally, we demonstrated the therapeutic effect of JAK/STAT and TGF-β pathway inhibition as well as senolytic treatment on Fibulin-4R/R VSMCs in vitro. These findings can contribute to improved therapeutic options for aneurysmal disease aimed at reducing senescent cells.

Project description:Epigenetic mechanisms as DNA methylation can affect allograft outcome after kidney transplantation, accelerating renal aging. Complement system is the major player of ischemia reperfusion (I/R) injury and Renal Proximal Tubular Cells (RPTEC) are known to express C5a receptor (C5aR). However, little is known about the downstream effect of C5a-C5aR interaction. We performed a whole-genome DNA methylation analysis on C5a stimulated RPTEC and found several regions regulating genes involved in cell cycle control, DNA damage checkpoints and WNT signaling. These most represented genes were BCL9, CYP1B1 and CDK6. We showed that C5a induced-aberrant gene methylation significantly influences the expression of these genes. Moreover, the stimulation of RTEC by C5a led to senescence by up-regulating SA-β Gal positivity and increasing p53 gene and p21 protein level. IL-6, MCP-1, CTGF gene levels increase indicated the tubular SASP (Senescence associated Secretory Phenotype) acquirement. In accordance, in a swine model of I/R injury, we found that the increase expression of WNT4/βcatenin expression correlated with the augment in SA-β Gal, p21, p16 and IL-6 positivity after 24h from reperfusion. The treatment with C1-INH, a complement inhibitor, efficiently antagonized SASP restoring SA-β Gal, p21, p16, IL-6 expression at basal level and abrogating the WNT4/βcatenin activation. Thus, C5a affects the DNA methylation of genes involved in tubular senescence leading to a persistent, low-grade, inflammatory state called inflammaging. Targeting epigenetic programs may offer novels strategies to protect tubular cells from aging and promote kidney repair and recovery.

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.

Project description:We found that Ripk3 signaling selectively regulates both the number and function of hematopoietic stem cells (HSCs) during stress conditions and inhibits ionizing radiation (IR)-induced leukemia development in mice. During serial transplantation, which stimulates a chronic Ripk3 activation in HSCs, Ripk3 promotes the loss of HSCs via Mlkl-mediated necroptosis and impairs HSC function by inducing ROS-p38-p16 mediated senescence. In response to 6Gy of IR, which induces the activation of p53-p21-mediated cell cycle arrest/senescence in HSCs, Ripk3 is required for the activation of NF-κB and permits the survival of the senescent cells. However, in response to multiple low doses of IR (1.75 × 4), Ripk3 signaling inhibits leukemia development by inducing ROS-p38-p16-mediated senescence and repressing Ire1α-Xbp1-Dnajb8 UPR fitness in pre-leukemic stem cells (pre-LSCs) and also inducing Mlkl-dependent clearance of pre-LSCs. Mlkl deletion prevents IR-induced loss of HSCs and slightly accelerates leukemia development in mice, while Ripk3 deletion represses both necroptotic and senescence signals in pre-LSCs and significantly accelerates IR-induced leukemia development. Our study suggests that immediately after high dose IR, temporal inhibition of Ripk3-NF-κB signaling might help to prevent long-term residual damage (LT-RDs) in bone marrow by eliminating the IR-induced senescent HSCs. However, in response to low dose radiation, induced activation of Ripk3 signaling at the pre-leukemia stage might help to prevent the accumulation of mutant HSCs and the development of leukemia.

Project description:Cells expressing features of cellular senescence, including upregulation of p21 and p16, appear transiently following tissue injury, yet the properties of these cells or how they contrast with age-induced senescent cells remains unclear. Using skeletal fracture as a model of acute injury, we identified rapidly-appearing senescent-like cells, marked by p21 expression, that negatively affected fracture healing. p21+ callus cells, which consisted predominantly of neutrophils and osteochondroprogenitors, existed as transient cells specific to injury and expressed high levels of senescence-associated factors known to impair bone formation and induce paracrine senescence. Targeted genetic clearance of p21+ cells suppressed senescence-associated signatures within the fracture callus and accelerated fracture healing. By contrast, p21+ cell clearance did not alter bone loss due to aging; conversely, p16+ cell clearance, known to alleviate skeletal aging, did not affect fracture healing. Together, our findings establish contextual roles of senescent/senescent-like cells that may be leveraged for therapeutic opportunities.

Project description:Cellular senescence is a program of irreversible cell cycle arrest that normal cells undergo in response to progressive shortening of telomeres, changes in telomeric structure, oncogene activation or oxidative stress. The underlying signalling pathways, potentially of major clinicopathological relevance, are unknown. A major stumbling block to studying senescence has been the absence of suitable model systems because of the asynchrony of this process in heterogeneous cell populations. To simplify this process many investigators study oncogene-induced senescence due to expression of activated oncogenes where senescence occurs prematurely without telomere attrition and can be induced acutely in a variety of cell types. We have taken a different approach by making use of the finding that reconstitution of telomerase activity by introduction of the catalytic subunit of human telomerase alone is incapable of immortalising all human somatic cells, but inactivation of the p16-pRB and p53-p21 pathways are required in addition. The ability of SV40 large T antigen to inactivate the p16-pRB and p53-p21 pathways has enabled us to use a thermolabile mutant of LT antigen, in conjunction with hTERT, to develop conditionally immortalised human (HMF3A) fibroblasts that are immortal but undergo an irreversible growth arrest when the thermolabile LT antigen is inactivated leading to activation of pRB and p53. When these cells cease dividing, senescence-associated- b-galactosidase activity is induced and the growth-arrested cells have morphological features and express genes in common with senescent cells. Since these cells growth arrest in a synchronous manner they are an excellent starting point for dissecting the pathways that underlie cellular senescence and act downstream of p16-pRB and p53-p21 pathways. We have combined genome-wide expression profiling with genetic complementation to undertake identification of genes that are differentially expressed when these conditionally immortalised human fibroblasts undergo senescence upon activation of the p16-pRB and p53-p21 tumour suppressor pathways. Genes differentially expressed upon senescence will be identified by comparing arrays from growing versus senescent cells. Changes in gene expression due to the temperature shift will be eliminated by comparing with array data from the non-conditional HMF3S cells grown at 34°C ±0.5°C and 38°C ±0.5°C. To determine if the changes in gene expression upon senescence are specific and reversible, the set of differential genes will then be overlaid with array data from cells in which senescence has been bypassed by inactivation of the p16-pRB and p53-p21 tumour suppressor pathways

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:Recently, senescence has been suggested as a defense mechanism to block sporadic induction of cancer cells. Radiation treatment induces proliferating cancer cells to turn into non-proliferating senescent cells in vitro. To characterize transcriptional reprogramming after radiation treatment, we measured the gene expression profiles of MCF7 at different time points after treatment. In these experiments, we found that IR induced premature senescence in MCF7 cells, and IR treatment resulted in significant changes in the expression of 305 marker genes (less than 1% FDR), which were strongly correlated (|r|>0.9) with IR treatment in a time-dependent manner. Functional analysis of these markers indicated that the dynamics of cytoskeletal structure and lysosomal activity gradually increased. The expression of marker genes for modulator proteins, that were responsible for the dynamics of actin stress fibers and focal adhesion, displayed a particularly strong positive correlation with senescence-associated (SA) morphological changes through time. We also observed a strong induction of genes related to lysosomal metabolic activity, which was accompanied by an increase in the number of SA-beta-Gal positive cells. However, the expression of genes for the cell cycle progression, the post-transcription and the translation activities gradually decreased after radiation treatment. Especially, we observed clear cell cycle arrest specifically at the S and G2/M phases with consistent down-regulation of genes for microtubule assembly/disassembly or spindle biogenesis. Gene expression profiles were obtained from human MCF7 cells after ionizing radiation (6 Gy) at day 0 (no ionizing radiation), day 1 (after ionizing radiation), day 2, day 3, and day 4.

Project description:Senescence, a stable state of growth arrest, affects many physiological and pathophysiological processes, especially aging. Previous work has indicated that transcription factors (TFs) play a role in regulating senescence. However, a systematic study of regulatory TFs during replicative senescence (RS) using multi-omics analysis is still lacking. Here, we generated time-resolved RNA-seq, reduced representation bisulfite sequencing (RRBS) and ATAC-seq datasets during RS of mouse skin fibroblasts, which demonstrated that an enhanced inflammatory response and reduced proliferative capacity were the main characteristics of RS in both the transcriptome and epigenome. Through integrative analysis and genetic manipulation, we found that transcription factors E2F4, TEAD1 and AP-1 are key regulators of RS. Overexpression of E2f4 improved cellular proliferative capacity, attenuated SA-β-Gal activity and changed RS-associated differentially methylated sites (DMSs). Moreover, knockdown of Tead1 attenuated SA-β-Gal activity and partially altered the RS-associated transcriptome. In addition, knockdown of Atf3, one member of AP-1 superfamily TFs, reduced Cdkn2a (P16) expression in pre-senescent fibroblasts. Taken together, results of this study identified transcription factors regulating the senescence program through multi-omics analysis, providing potential therapeutic targets for anti-aging.