THIOL REDUCING AGENTS MODULATE INDUCED APOPTOSIS IN PORCINE ENDOTHELIAL CELLS

Abstract

When cultured porcine endothelial cells are exposed first to endotoxin (lipopolysaccharide (LPS)) followed by standard inducers of the heat shock response in vitro (heat or sodium arsenite), these cells aberrantly execute programmed cell death. This cell death is dependent upon two distinct events: the LPS-priming step and the heat shock-induced activation step. Prior work demonstrated that the LPS-priming step could be blocked by the prior application of cell-permeable hydroxyl radical scavengers, suggesting a role for this reactive oxygen species as an important intracellular signal mediating the first step. In these present experiments, we evaluated the potential role of reduction-oxidation mechanisms in the heat shock activation step. The thiol reducing agents reduced glutathione (GSH), n-acetylcysteine (NAC), and dithiothreitol (DTT) were evaluated for their ability to block programmed cell death in LPS-primed porcine aortic endothelial cells. Both DTT and NAC, agents that augment intracellular reduced glutathione levels, were protective against cell death when applied prior to heat shock induction with sodium arsenite (As) in endothelial cells treated previously with LPS. The less cell permeable agent GSH was not protective. Delayed application of DTT or NAC could block progression to cell death for up to 1.5 h after initiation of the heat shock response with As. These data show that heat shock-induced programmed cell death in LPS-primed endothelial cells can be arrested, at least in its early stages, by agents that augment or stabilize the reducing potential of the cell. Moreover, these data suggest that the LPS-priming step and the heat shock-activation step are mechanistically distinct components in the induction of programmed endothelial cell death.