Phosphorylation state of hsp27 and p38 MAPK during preconditioning and protein phosphatase inhibitor protection of rabbit cardiomyocytes.

Small heat shock proteins (hsp) have been implicated in mediation of classic preconditioning in the rabbit, Hsp27 is a terminal substrate of the p38 MAPK cascade. One and 2D gel electrophoresis and immunoblotting of cell fractions was used to determine p38 MAPK and hsp27 phosphorylation levels, respectively, during in vitro ischemia in control, calyculin A (Cal A)-treated (protein phosphatase inhibitor), SB203580-treated (p38MAPK inhibitor) and preconditioned (IPC) isolated adult rabbit cardiomyocytes. The dual phosphorylation of p38 MAPK was increased by early ischemia (30-60 min), after which there was a loss of total cytosolic p38 MAPK. The ischemic increase of p38 MAPK dual phosphorylation was enhanced by IPC. Cal A strongly activated dual phosphorylation of p38 MAPK in oxygenated cells and this was maintained into early ischemia, SB203580 inhibited the dual phosphorylation of p38 MAPK and attenuated the loss of total cytosolic p38 MAPK. In each protocol, ischemia translocated hsp27 from the cytosolic fraction to the cytoskeletal fraction at similar rates and extents, Hsp27 phosphorylation was quantitated as the fraction of diphosphorylated hsp27, based on IEF mobility shifts of hsp27 phosphorylation isoforms. In oxygenated control cells, cytosolic and cytoskeletal hsp27 was highly phosphorylated. After 90 min ischemia, cytoskeletal hsp27 was markedly dephosphorylated. Cal A slightly increased control cytoskeletal hsp27 phosphorylation. During ischemic incubation, Cal A blocked ischemic dephosphorylation, SB203580 accelerated ischemic hsp27 dephosphorylation and injury, IPC insignificantly decreased the initial rate of ischemic dephosphorylation of hsp27, but not the extent of dephosphorylation in later ischemia. Phosphorylation is regulated by both kinase and phosphatase activities. IPC protection was not correlated with a significant increase in cytosolic or cytoskeletal hsp27 phosphorylation levels during prolonged (> 60-90 min) ischemia.

Translocation of PKC, protein phosphatase inhibition and preconditioning of rabbit cardiomyocytes.

This study was designed to test the hypothesis that induction of the preconditioned state results in a sustained translocation of protein kinase C (PKC) which accounts for the memory associated with preconditioning. Isolated rabbit cardiomyocytes were subjected to established preconditioning protocols using either adenosine or transient ischemia. At timed intervals during induction of preconditioning (PC), post-incubation or final sustained ischemia, cells were harvested, subjected to digitonin lysis and separated into cytosolic and particulate fractions. Samples were evaluated by Western blot analysis with monoclonal antibodies to alpha, epsilon, zeta and gamma PKC isozymes, and bands were qualified by densitometry. Internal controls for each experiment included oxygenated cardiomyocytes and cell with PKC translocation evoked by treatment with phorbol 12-myristate 13-acetate (PMA). For control oxygenated cells, the particulate fraction contained about 30% of PKC epsilon, 5-10% of PKC alpha and 60-70% of PKC zeta. Preconditioning with adenosine (100 microM) or 10 min ischemia had no significant effect on these percentages. Furthermore, the relative amounts of PKC isozymes associated with the particulate fraction of control and preconditioned cells did not differ after a postincubation in oxygenated buffer or during a final ischemic incubation. PMA and ingenol completely translocated the epsilon and alpha isoforms, while thymeleatoxin totally translocated PKC alpha but only partially (50%) translocated PKC epsilon. The distribution of PKC zeta between fractions was not affected by any drug. The protein phosphatase inhibitor calyculin A protected cells mimicking preconditioning. This protection was blocked by preincubation with the selective PKC inhibitor calphostin C but was largely retained if calphostin C was added only during the final ischemic period. It is concluded that PKC activity is required for preconditioning, but a sustained translocation of PKC above basal levels is not necessary for protection of rabbit cardiomyocytes in vitro.