The goal of our investigation was to explore the mechanism by which hypoxia regulates growth plate chondrocyte survival. At low O2 tension, chondrocytes were refractory to a staurosporine (i.e., apoptosis-inducing) challenge. To determine whether hypoxic survival was due to the expression of HIF-1, we evaluated the response of HIF silenced cells to staurosporine. Both, silenced cells and control chondrocytes were equally sensitive to the apoptogen challenge. To learn if resistance was mediated by the proteins of the autophagic pathway, we examined the expression of Beclin 1 and LC3. Both proteins were present in the growth plate as well as in N1511 chondrocytes. Moreover, silencing of Beclin 1 resulted in enhanced chondrocyte death. Thus, this gene served to maintain chondrocyte survival activity. Besides serving a cytoprotective role, it is known that autophagy can function in cell death. Accordingly, to ascertain if autophagy might also sensitize cells to apoptosis, we activated autophagy and examined viability following exposure to an apoptogen. Treatment with the autophagy inhibitor 3-methyladenine rendered the chondrocytes refractory to killing, suggesting that sustained autophagy promoted cell death. We next examined expression of BID and caspase-8. When autophagy was suppressed, chondrocytes promoted caspase-8 activation and activated BID. Finally, we explored the relationship between HIF-1 and Beclin 1. We noted a decrease in Beclin 1 expression and loss of caspase-8 activation in HIF silenced cells and Beclin 1-Bcl-2 association was maintained upon serum starvation. This study indicates that HIF-1 serves to regulate both autophagy and apoptosis.
The goal of the study is to examine the relationship between the sensor molecules, Hypoxia Inducible Factor-1 (HIF-1), AMP activated Protein Kinase (AMPK) and mammalian Target of Rapamycin (mTOR) in chondrocyte survival and autophagy. We showed that chondrocytes expressed the energy sensor AMPK-1 and that activation increased with maturation. In addition, we showed that thapsigargin treatment activated AMPK and autophagy in a HIF-1 dependent manner. Using serum-starved AMPK-silenced cells, we demonstrated that AMPK was required for the induction of the autophagic response. We also noted a change in chondrocyte sensitivity to apoptogens, due to activation of caspase-8 and cleavage and activation of the pro-apoptotic protein, BID. To test the hypothesis that AMPK signaling directly promoted autophagy, we inhibited AMPK activity in mTOR silenced cells and showed that while mTOR suppression induced autophagy, AMPK inhibition did not block this activity. Based on these findings, it is concluded that due to the micro-environmental changes experienced by the chondrocyte, autophagy is activated by AMPK in a HIF-1 dependent manner.
The overall goal of the investigation was to examine the activity and role of the PIM serine/threonine protein kinases in the growth plate. We showed for the first time that PIM-2 was highly expressed in epiphyseal chondrocytes and that the kinase was required for critical activities linked to cell survival. These activities were independent of those mediated by Akt-1. It was noted that PIM-2 protected chondrocytes from rapamycin sensitized (TOR inhibited) cell death. Since inhibition of mTOR caused autophagy, we examined the autophagic response of PIM-2 silenced cells. We showed that PIM-2 promoted expression and organization of autophagic proteins LC3, and Beclin-1 and enhanced lysosomal acidification. At the same time, PIM-2 modulated the activity of a key regulator of apoptosis, BAD. Since BAD inhibition and Beclin-1 expression activated autophagy, it is likely that induction of the autophagic pathway would serve to inhibit apoptosis and preserve the life of the terminally differentiated chondrocyte. We conclude that PIM-2 regulates a new intermediate stage in the differentiation pathway, the induction of autophagy.
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