Heat shock. A new approach for myocardial preservation in cardiac surgery

BACKGROUND

Recent studies have indicated that heat shock (HS) induces protective genes and HS protein (HSP) expression, which enhances cellular tolerance to ischemic injury. The present study sought to determine if 42 degrees C blood cardioplegia could be used to induce HSP expression and improved myocardial salvage after 2 hours of cardioplegic arrest.

METHODS AND RESULTS

To study this, pig hearts (n = 6) on cardiopulmonary bypass were subjected to HS by continuous infusion to the globally arrested heart of warm blood cardioplegia (K+ = 30 meq/l) at 42 degrees C for 15 minutes followed by 2 hours of intermittent hypothermic (4-6 degrees C) hyperkalemic (30 meq/l) crystalloid cardioplegic arrest and 1 hour of reperfusion (heat shock group). The control group (n = 6) was subjected to only 2 hours of hypothermic crystalloid cardioplegic arrest followed by 1 hour of reperfusion without HS. Left ventricular performance, coronary blood flow, and creatine kinase release were determined before arrest and during reperfusion. Prearrest control biopsies were taken in a separate group of pigs (n = 6) for both HSP and superoxide dismutase activity. Additional biopsies were taken for the same measurements in both control and HS groups at the completion of reperfusion. In a single additional pig in both the control and HS groups, biopsies were taken during the study to estimate changes in HSP expression. The cytosolic protein of ventricular tissue was subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and the HSP70 family protein was examined by Western blot analysis using monoclonal antibodies. HSP was found to be increasingly expressed from control levels after 15 minutes of HS pretreatment, increasing progressively to a level significantly above the non-HS group. Associated with this increased expression of HSP was a significant increase in superoxide dismutase activity in the HS animals and significant improvement in both global and regional functions and reduced creatine kinase release.

CONCLUSIONS

The results show that preconditioning the heart with HS improves postischemic ventricular performance and attenuates cellular injury. HS induces a change in cellular metabolism, prompting the expression of HSP and improving antioxidant activity, leading to improved function and reduced tissue injury during ischemia and reperfusion.

Phospholipase D signaling in ischemic heart

Phospholipase D (PLD) activity was found to be present in the membrane fraction of rat myocardial cells by in vitro assays (36.7 +/- 4.1 nmol/mg protein per h against 1-palmitoyl-2-arachidonoyl- phosphatidylcholine) and demonstrated in intact cells by the specific transphosphatidylation reaction (in the presence of 0.02% ethanol) quantitated using n-[1-14C]butanol (201.16 +/- 7.1 pmol/min per g dry weight in the whole heart). Both methods showed a significant increase in PLD activity (by 62 and 44%, respectively) in hearts subjected to reversible (30 min) global normothermic ischemia followed by reperfusion (30 min). In hearts prelabeled with [1-14C]arachidonic acid, ischemia/reperfusion induced a significant increase in the amount of radiolabel incorporated into phosphatidic acid (PtdOH) (by 49.6%) and diacylglycerol (DG) (by 259%). DG kinase inhibition by 100 microM dioctanoylethylene glycol did not affect the ischemia/reperfusion DG and PtdOH levels while PtdOH phosphohydrolase inhibition with 40 microM propranolol produced a further increase in PtdOH (to 2.36-fold the baseline level) and a reduction in DG (to only 145% over the baseline levels). Put together, all these results suggest an activation of PLD during myocardial ischemia/reperfusion generating intracellular PtdOH, part of which is converted by PtdOH phosphohydrolase to DG. We further investigated the possible pathophysiological significance of the observed PLD activation. Stimulation of PLD with sodium oleate (20 microM) induced a significant improvement of functional recovery of ischemic hearts during reperfusion (as monitored by coronary flow and left intraventricular pressure measurements) and an attenuation of cellular injury as expressed by lactate dehydrogenase and creatine kinase release in the coronary effluent during reperfusion. These results suggest a PLD-mediated signaling in the ischemic heart which may benefit functional recovery during reperfusion.