Objective: Cellular senescence is a phenotypic state characterized by stable cell-cycle arrest, enhanced lysosomal activity, and the secretion of inflammatory molecules and matrix degrading enzymes. Senescence has been implicated in osteoarthritis (OA) pathophysiology; however, the mechanisms that drive senescence induction in cartilage and other joint tissues are unknown. While numerous physiological signals are capable of initiating the senescence phenotype, one emerging theme is that growth-arrested cells convert to senescence in response to sustained mitogenic stimulation. The goal of this study was to develop an in vitro articular cartilage explant model to investigate the mechanisms of senescence induction.Design: This study utilized healthy articular cartilage derived from cadaveric equine stifles and human ankles.Explants were irradiated or treated with palbociclib to initiate cell cycle arrest, and mitogenic stimulation was provided by serum-containing medium (horse) and the inclusion of growth factors (human). The primary readout of senescence was a quantitative flow cytometry assay to detect senescence-associated ꞵ galactosidase activity (SA-ꞵ-gal).Results: Irradiation of equine explants caused 25.39% of cells to express high levels of SA-ꞵ-gal, as compared to 3.82% in control explants (p=0.0031). For human cartilage, explants that received both mitogenic stimulation and cell cycle arrest showed increased rates of senescence induction as compared to baseline control (7.16% vs. 2.34% SA-ꞵ-gal high, p=0.0007).Conclusions: Treatment of cartilage explants with mitogenic stimuli in the context of cell-cycle arrest reliably induces high levels of SA-β gal activity, which provides a physiologically relevant model system to investigate the mechanisms of senescence induction. Introduction:Osteoarthritis (OA) is a disease characterized by joint pain and progressive degradation of articular cartilage and other tissues of the joint 1,2 . As the most common chronic disease of the articular joint, OA produces a substantial burden on society and the economy 3,4 . Despite increasing knowledge about factors contributing to the progression of OA, there are no approved disease-modifying therapies 5 , leading to high rates of total joint replacement 6 . Risk factors for OA include obesity, joint injury, and genetic predisposition, with the most dominant risk factor being aging 7,8 . Cellular senescence has been described as a key phenotype associated with aging 9 , and there is mounting evidence that the accumulation of senescent cells in the joint during both aging and in response to injury contributes to the development of OA 10-14 . Senescent chondrocytes likely contribute to tissue degradation by producing pro-inflammatory and matrix-degrading molecules known collectively as the senescence-associated secretory phenotype (SASP) 15,16 . Significant advances have begun to unravel the role of senescence in OA and the therapeutic implications of such findings, including the potential for senolytic therapy as a potential di...
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