Project description:Plasma membrane damage-dependent senescence is a novel senescence subtype. Here, we compare the time-resolved proteomic profiles of plasma membrane damage-dependent senescence, DNA damage-dependent senescence, and replicative senescence to find the major differences between the senescence subtypes.

Project description:The accumulation of senescent cells (SEN) with aging produces a chronic inflammatory state that accelerates age-related diseases. Eliminating SEN has been shown to delay, prevent, and in some cases reverse aging in animal disease models and extend lifespan. There is thus an unmet clinical need to identify and target SEN while sparing healthy cells. Here, we show that Lysosomal-Associated Membrane Protein 1 (LAMP1) is a membrane-specific biomarker of cellular senescence. We have validated selective LAMP1 upregulation in SEN in human and mouse cells. Lamp1+ cells express high levels of prototypical senescence markers p16, p21, Glb1, and have low Lmnb1 expression as compared to Lamp1- cells. The percentage of Lamp1+ cells is increased with age and in mice with fibrotic lungs due to bleomycin instillation. The RNA-Seq. analysis of the Lamp1-enriched populations in sham and BLM mice lung tissue revealed enrichment of several senescence-related genes in both groups when compared to the SenMayo gene set derived from transcriptomic profiling of senescence markers in Mayo Clinic research datasets. Finally, we use a dual antibody-drug conjugate (ADC) strategy to eliminate senescent cells in cell culture assay.

Project description:To investigate the comparison of senescence progression in plasma membrane damage-, calcium influx-, DNA damage- and telomere shortening-induced senescence in the normal human fibroblast cells.

Project description:Cellular senescence disables the proliferation of damaged cells and it is relevant for cancer and aging. Here, we show that cellular senescence occurs during mammalian embryonic development. Specifically, we have focused on the mouse regressing mesonephros and the endolymphatic sac of the inner ear. Senescence is characterized by SAM-NM-2G activity, heterochromatinization, and proliferative arrest. Mechanistically, developmentally-programmed senescence at the mesonephros and endolymphatic sac is strictly dependent on p21, but independent of DNA damage, p53 or other cell cycle inhibitors, and it is regulated by the TGFM-NM-2/SMAD and PI3K/FOXO pathways. Developmentally-programmed senescence is followed by macrophage infiltration and clearance of senescent cells. Abrogation of senescence by p21 deletion is only partially compensated by apoptosis and originates detectable developmental abnormalities. Importantly, high levels of p21 are also associated to the regressing mesonephros and endolymphatic sac in human embryos. These findings place cellular senescence as a relevant morphogenic process during embryonic development. We microdissected mesonephric tubules from senescent (WT) and non-senescent (p21-null) embryos to get information about this new senescence that occurs during embryogenesis.

Project description:Cellular senescence is a stress-induced permanent cell cycle arrest typically accompanied by expression of the cyclin-dependent kinase inhibitor p16. Recent studies have suggested that p16-expressing senescent cells accumulate in the body with age and play a causative role in aging. Various stresses, such as telomere shortening and oncogene activation, induce cellular senescence by generating DNA damage. However, how DNA damage leads to p16 expression is incompletely understood. We identified BNIP3 in a genome-wide siRNA screen for genes involved in p16 expression upon DNA damage. Mass spectrometric analysis of BNIP3-binding proteins yielded the DDR kinase ATM and components of the mitochondrial contact site and cristae organizing system (MICOS) complex. We found that BNIP3 increases the number of mitochondrial cristae upon DNA damage by electron microscopy. Metabolomic analysis linked BNIP3 to altered acetyl-CoA metabolism during DNA damage-induced senescence. We found that BNIP3 facilitates the oxidation of fatty acids to acetyl-CoA, an acetyl group donor, and promotes histone acetylation around the p16 gene and associated p16 expression. Our findings suggest that DDR signaling to mitochondria via BNIP3 promotes p16 expression through fatty acid oxidation and histone acetylation.

Project description:In this study, we have addressed how cellular senescence influences the immunomodulatory potential of human mesenchymal stem cells (hMSCs). We induced cell senescence in a panel of bone marrow-derived hMSC samples by means of gamma-irradiation, and performed both gene expression and miRNA microarray analyses on the untreated and senescent samples. We also compared the gene expression profile of untreated and senescent hMSCs with those obtained from several hMSCs samples used in an ongoing allogeneic clinical study of Graft Versus Host Disease (GVHD), of which their therapeutic efficacy is known. We have identified several genes (PLEC, C8orf48, TRPC4, and ZNF14) differentially expressed in senescent hMSCs that are similarly regulated in hMSC samples that did not show a therapeutic effect in the GVHD study. These genes might be useful as markers to evaluate the therapeutic potential of hMSCs used in future clinical studies. We compared the gene and miRNA expression profiles of untreated (WT) control bone marrow-derived hMSCs with the same primary cell lines 10 days after gamma-irradiation (SEN) and with several hMSCs samples used in a clinical stydy of GVHD. The samples used in the clinical study were classified in two groups, depending on whether they elicited a therapeutic response (G1) or not (G2). A total of four independent samples (biological replicates) were used for WT and SEN conditions. For the samples used in the clinical study, a total of five samples were used for the G1 group, and three samples for the G2 group.

Project description:Senescent cells are a major cause of organismal aging and a key target for anti-aging therapies. Persistent DNA damage signaling is a primary driver of the induction and maintenance of cellular senescence. However, many DNA damaging stimuli that induce senescence, such as irradiation or transient exposure to genotoxic drugs, are transient. The mechanisms underlying persistent damage signaling in senescent cells, and why senescent cells fail to repair damaged DNA, remain unknown. Here, we were able to assess the mechanisms underlying persistence of DNA damage and senescence maintenance by designing a precisely controllable senescence system that does not require potent stressors to induce senescence. We demonstrate that sustained mTORC1 signaling in senescent cells causes gradually accumulating DNA damage and an inflammatory response that maintains cell-cycle arrest. Markedly, activation of E2F transcription, which promotes expression of DNA repair proteins, can reverse accumulated DNA damage. Thus, persistent DNA damage signaling arises in senescent cells by uncoupling of mTORC1 and E2F signaling, whereby prolonged mTORC1 activity causes gradually increasing DNA damage that cannot be sufficiently repaired without induction of protective E2F target genes.

Project description:Dysfunction of vascular endothelium is characteristic of many aging-related diseases, including Alzheimers disease (AD) and AD-related dementias (ADRD). While it is widely posited that endothelial cell dysfunction contributes to the pathogenesis and/or progression of AD/ADRD, it is not clear how. A plausible hypothesis is that intercellular trafficking of extracellular vesicles (EVs) from senescent vascular endothelial cells promotes vascular endothelial cell dysfunction. To test this hypothesis, we compared the expression of proteins and miRNAs in EVs isolated from early passage (EP) vs. senescent (SEN) primary human coronary artery endothelial cells (HCAECs) from the same donor. Proteomics and miRNA libraries constructed from these EV isolates were evaluated using FunRich gene ontology analysis to compare functional enrichment between EP and SEN endothelial cell EVs (ECEVs). Replicative senescence was associated with altered EV abundance and contents independent of changes in EV size. Unique sets of miRNAs and proteins were differentially expressed in SEN-ECEVs, including molecules related to cell adhesion, barrier integrity, receptor signaling, endothelial-mesenchymal transition and cell senescence. miR-181a-5p was the most upregulated miRNA in SEN-ECEVs, increasing >5-fold. SEN-ECEV proteomes supported involvement in several pro-inflammatory pathways consistent with senescence and the senescence-associated secretory phenotype (SASP). These data indicate that SEN-ECEVs are enriched in bioactive molecules implicated in senescence-associated vascular dysfunction, blood-brain barrier impairment, and AD/ADRD pathology. These observations suggest involvement of SEN-ECEVs in the pathogenesis of vascular dysfunction associated with AD/ADRD.

Project description:Human endothelial cellular models are useful to disentangle the pathophysiological role of dysfunctional endothelium in the development of cardiovascular (CV) disease and organ damage in T2D. Here, we performed a RNAseq of human umbilical vein endothelial cells (HUVECs) undergoing replicative senescence and exposed to high glucose (25 mM) to investigate the combined effects of replicative senescence and high glucose on the transcriptional landscape of these cells. To gain insight into the molecular mechanisms driving the acquisition of a senescent phenotype following exposure to HG, we performed a RNA-seq assay on control (Ctr) and replicative senescent (Sen) HUVECs cultivated in presence/absence of HG culture medium (total number of samples = 12; number of samples in each cell type-medium condition group = 3) using the NovaSeq 6000 Illumina system. Differential expression analysis was performed in R environment (version 4.2.2) using the limma and edgeR Bioconductor R packages.

Project description:Time-resolved miRNA-mRNA integrated analysis reveals the miRNA-mRNA networks underlying plasma membrane damage-dependent senescence and DNA damage response-dependent senescence in WI-38 normal human fibroblasts