Preconditioning of isolated rat heart is mediated by protein kinase C

Protein kinase C activation before cardioplegic arrest: beneficial effects on myocyte contractility

OBJECTIVE

A potential intracellular mechanism for the protective effects of myocardial preconditioning is the activation of protein kinase C. The present study tested the hypothesis that a brief period of protein kinase C activation before cardioplegic arrest would provide protective effects on myocyte contractility with subsequent reperfusion and rewarming.

METHODS

Left ventricular porcine myocytes were assigned to the following treatments: (1) Protein kinase C/cardioplegia: Protein kinase C activation in myocytes (n = 39) for 3 minutes with a phorbol ester (10(-9) mol/L of phorbol 12-myristate 13-acetate) in oxygenated, normothermic (37 degrees C) cell media. Protein kinase C activation was followed by 2 hours of cardioplegic arrest (K+, 24 mEq/L; HCO3-, 30 mEq/L; 4 degrees C) and a 5-minute reperfusion period (37 degrees C media). (2) Cardioplegia: Myocytes (n = 31), 2 hours of cardioplegic arrest, and a 5-minute reperfusion and rewarming period. Myocyte contractility was measured by means of high-speed videomicroscopy. For comparison purposes, contractile function was examined in myocytes (n = 70) under normothermic control conditions.

RESULTS

Myocyte shortening velocity was reduced after cardioplegic arrest when compared with normothermic values (22.3 +/- 1.6 vs 48.8 +/- 2.0 microm/sec, p < 0.0001). Protein kinase C activation before cardioplegic arrest normalized myocyte shortening velocity (48.8 +/- 2.5 microm/sec). Co-incubation with phorbol 12-myristate 13-acetate and chelerythrine (10(-6) mol/L), an inhibitor of protein kinase C, before cardioplegic arrest abolished the protective effects of phorbol 12-myristate 13-acetate pretreatment.

CONCLUSION

These results suggest that an endogenous means of providing improved myocardial protection during prolonged cardioplegic arrest can be achieved through a brief period of protein kinase C activation.

Beneficial actions of preconditioning and stretch on postischemic contractile function of isolated working rat heart: effects of staurosporine

Preconditioning is commonly induced by a brief ischemic insult; myocardial stretch can trigger this protection by an unknown mechanism. Myocardial stretch preconditions the in vivo canine heart; however, the existence of a stretch-induced protection in the rat heart remains unknown. The purpose of this study was to test this myocardial protection induced, in isolated working rat heart, by global ischemia and stretch initiated by a transient increase in the left ventricle (LV). Isolated rat hearts underwent 30 min of global ischemia followed by 30 min of reperfusion. Before this, hearts received a 15-min period of either no intervention (control; C), 5 min of global ischemia + 10 min of reperfusion (preconditioning; PC) or 5 min of stretch + 10 min with no intervention (stretch; S). Stretch was induced by a transient increase in LV preload from 5 to 20 cm H2O. LV work started under a afterload of 80 cm H2O. Control, PC, and S hearts received either no drug (untreated) or staurosporine (50 nM), a protein kinase C inhibitor, before the "preconditioning" period. Creatine kinase (CK) release, ventricular fibrillation during reperfusion, and postischemic recovery of contractile function (aortic flow) were the end points of the study. In the S group, the abrupt increase in preload resulted in a significant increase of aortic flow (42 +/- 2 to 47 +/- 2 ml/min; p < 0.05). During the 30-min reperfusion period, control hearts displayed a poor recovery of contractile functions (8 +/- 3 ml/min, 30 min after reflow, versus 40 +/- 2 ml/min at baseline; p < 0.05). Both untreated PC and S groups exhibited a significant reduction in CK release, incidence of ventricular fibrillation (55% of control hearts developed persistent VF vs. 6% in both the PC and S groups), and postischemic dysfunction during reperfusion (p < 0.05 vs. control). Staurosporine prevented these beneficial effects in PC and S groups. Our study suggests that myocardial protection can be induced by stretch in the isolated working rat heart, likely through activation of protein kinase C. In conclusion, our results show that ischemic preconditioning and stretch had comparable favorable effect on functional recovery after a sustained ischemic insult in the isolated rat heart.

Intravenous co-infusion of adenosine and norepinephrine preconditions the heart without adverse hemodynamic effects

OBJECTIVE

A simple intervention is needed that could protect the heart against infarction during limited-access coronary artery bypass grafting. Adenosine and norepinephrine can precondition the heart with resulting protection, but adverse hemodynamic effects prevent clinical application. Because heart rate, blood pressure, and contractility effects of these two drugs are diametrically opposite, a mixture might be beneficial.

METHODS

A superficial branch of the left coronary artery of rabbits was surrounded with a suture. Infarction was produced in all hearts by a 30-minute coronary artery occlusion. Infarct size after reperfusion was measured and is presented as a percentage of the risk zone. The effect of 5-minute intravenous co-infusion of adenosine (20 mg/kg) and norepinephrine (0.1 mg/kg) 15 minutes before ischemia was examined. In addition, the protective effect of three sequential intravenous bolus injections of adenosine at either 0.2 or 0.4 mg/kg was evaluated.

RESULTS

Thirty minutes of regional ischemia caused infarction of 40% +/- 4% of the risk zone. The combination of adenosine and norepinephrine caused no change in blood pressure but rather protected the heart, with infarction of only 9% +/- 2% of the risk zone (p = 0.0001 vs control). Adenosine-norepinephrine co-infusion still protected the heart when the interval between infusion and ischemia was extended to 60 minutes, but it did not protect with a 120-minute interval. Intravenous bolus injections of adenosine resulted in cardiac slowing and marked hypotension. Boluses of 0.2 mg/kg resulted in a minimal, but significant, reduction in infarct size, whereas the higher dose provided no protection.

CONCLUSION

Adenosine-norepinephrine co-infusion provides a feasible and safe parenteral method for preconditioning the heart.

Cardioadaptation induced by cyclic ischemic preconditioning is mediated by translational regulation of de novo protein synthesis

Repetitive episodes of brief ischemia induce myocardial adaptation to prolonged ischemia. To investigate whether this myocardial adaptive response involves gene transcription and de novo protein synthesis, this study examined the effects of actinomycin D (ActD) and cycloheximide (Chx) on the cardioprotection induced by repeated ischemic preconditioning. Isolated, perfused working rat hearts underwent cyclic ischemia (CI, four 5-min ischemic intervals, 37 degrees C) with and without pretreatment with Chx (1.0 mg/kg, ip; translation inhibition) or ActD (1.5 mg/kg, ip; transcription inhibition) 3 hr prior to heart isolation. All hearts were subjected to 20 min global ischemia (37 degrees C) and 40 min reperfusion (I/R). Coronary effluent was assayed for creatine kinase (CK) activity. Myocardial tissue was homogenized and crude protein content determined. CI preconditioning improved postischemic recovery of cardiac output (CO; 48 +/- 5.1% vs 73 +/- 2.8% for control and CI, respectively, P < 0.05) and reduced CK release (61 +/- 8.5 U/L vs 38 +/- 4.2 U/L for control and CI, respectively, P < 0.05). The beneficial effects of CI preconditioning on myocardial function and cellular integrity were abolished by Chx while ActD had no effect. Myocardial protein content was increased in CI preconditioned myocardium relative to control hearts (5082 +/- 89 microg/g vs. 4459 +/- 260 microg/g, respectively, P < 0.05). Similarly, pretreatment with Chx but not ActD prevented the increase in myocardial protein content (Chx + CI, 4020 +/- 254 microg/g; ActD + CI, 5049 +/- 68 microg/g, P < 0.05 Chx + CI vs CI or ActD + CI). Myocardial dry/wet weight ratios were not different between groups (P > 0.05). We conclude that CI preconditioning induces protein synthesis-dependent myocardial protection against I/R injuries. CI-induced de novo protein synthesis in the myocardium appears to be regulated at the translational level rather than by gene transcription.

Protein kinase C isoform diversity in preconditioning

Protein kinase C (PKC) appears to be a common intracellular effector and signal collector during cardiac preconditioning; however, it remains unknown whether agonists that activate different PKC isoforms are also linked to select aspects of myocardial protection. Using agonists that are known to activate unique combinations of PKC isoforms, we interrogated the relationship between isoform activation and the different aspects (pH, function, and viability) of endogenous myocardial protection. To study this, isolated rat hearts were subjected to ischemia-reperfusion (I/R) (20 min/40 min), without (control = Ctrl) or with receptor-dependent [phenylephrine (PE), 50 microM; adenosine (ADO), 125 microM] or -independent [phorbol myristate acetate (PMA), 100 nM] activation of PKC. Function, pH, and viability were assessed by rate pressure product (%RPP) and coronary flow (CF; ml/min), by 31P NMR, and by CF creatine kinase (CK; U/liter) leak, respectively. PMA, which activates PKC delta but not eta, resulted in intracellular pH (pHi) and viability protection, but did not protect against postischemic myocardial stunning. ADO, which activates PKC eta but not delta, protects against stunning, but not acidosis or necrosis. PE, which activates PKC delta and eta, provided global myocardial protection against necrosis, acidosis, and stunning. Different PKC isoforms may be linked to distinct aspects of myocardial protection. Targeted activation of PKC isoforms may allow precise mechanistic application of preconditioning-like myocardial protection.

Beta-adrenoceptor stimulation-mediated preconditioning-like cardioprotection in perfused rat hearts

To determine whether adrenergic stimulation induces preconditioning-like cardioprotection, rat hearts were perfused for 2 min with either norepinephrine, phenylephrine, or isoproterenol followed by 10-min drug-free perfusion. Then the hearts were subjected to 40-min ischemia and 30-min reperfusion. Little recovery of left ventricular developed pressure (LVDP) and loss of the myocardial creatine kinase (CK) during reperfusion were observed in the drug-untreated heart. Preperfusion with norepinephrine (0.25 microM) or isoproterenol (0.25 microM), but not phenylephrine (10 microM), resulted in a better recovery of LVDP in the postischemic reperfused heart and a reduction in CK release during reperfusion. A similar improvement of postischemic cardiac contractile dysfunction and CK loss was seen in the heart subjected to 5-min ischemia followed by 5-min reperfusion (ischemic preconditioning) before the prolonged period of ischemia/reperfusion. Pretreatment with timolol, a beta-adrenoceptor blocker, abolished the protective effect of norepinephrine, whereas pretreatment with bunazosin, an alpha 1-adrenoceptor blocker, did not affect the protective effect of isoproterenol. The results suggest that a brief period of stimulation of cardiac beta-adrenoceptor exerts the preconditioning-mimetic protective effect against postischemic contractile dysfunction in perfused rat hearts.

Activation of ecto-5'-nucleotidase by protein kinase C and its role in ischaemic tolerance in the canine heart

1. Ischaemic preconditioning (IP) protects the myocardium against irreversible ischaemic injury by activating protein kinase C (PKC). The mechanism by which PKC protects the myocardium is unknown. We have shown that PKC increases the activity of ecto-5'-nucleotidase (ecto-5'-N) and thereby the production of adenosine in cardiomyocytes which may protect the myocardium against ischaemia-reperfusion injury in vivo. 2. The objective of this study was to elucidate the possible role of PKC-induced activation of ecto-5'-N in the cardioprotection associated with IP in the canine heart. 3. IP increased the activities of both ecto-5'-N and PKC, and minimized ischaemic damage (infarct size: 7.5 +/- 1.8 vs. 42.3 +/- 2.8%, P < 0.01 vs. the control group). Treatment with the PKC activator (4 beta-phorbol 12-myristate-13-acetate) also reduced infarct size (13.5 +/- 2.9%, P < 0.01 vs. the control group). 8-Sulfophenyltheophylline (an antagonist of adenosine receptors) or alpha,beta-methyleneadenosine 5'-diphosphate (an inhibitor of ecto-5'-N) eliminated the cardioprotective effect of the PKC activator (infarct size: 36.6 +/- 3.9 and 34.7 +/- 4.2%, respectively), suggesting that PMA limits infarct size by increasing the activity of ecto-5'-N and the adenosine level. 4. The PMA-induced cardioprotection was blunted by GF109203X (an inhibitor of PKC, infarct size: 36.2 +/- 3.1%), but not by pretreatment with dexamethasone (infarct size, 14.2 +/- 2.6%). 5. We conclude that the PMA- and IP-induced cardioprotection is attributable to phosphorylation and activation of ecto-5'-N.

Myocardial alpha1-adrenoceptor: inotropic effect and physiologic and pathologic implications

Alpha1-adrenergic receptors have been found in myocardium of all mammalian species. Although the exact underlying mechanisms have not been conclusively determined, it would appear that the myocardial effects of alpha1-adrenoceptors may vary in importance according to the pathophysiologic process involved. In physiological conditions, this receptor system plays a role in cardiac growth, cardiac contraction, and has both an antiarrhythmic function as well as a role in cardiac adaptation to various situations. This system is also involved in some pathological processes such as ischemia/reperfusion, ischemic preconditioning, and cardiac hypertrophy. The role of alpha1-adrenoceptors in heart failure is somewhat controversial. Experimental evidence suggests that myocardial alpha1-adrenoceptors can have either beneficial or deleterious effects on the heart. It thus seems possible that the development of agents specific to certain subtypes of alpha1-adrenoceptor and a better understanding of their role in pathophysiologic states could be clinically relevant.

Does protein kinase C play a pivotal role in the mechanisms of ischemic preconditioning?

This communication reviews the evidence for the pivotal role of protein kinase C in ischemic myocardial preconditioning. It is believed that several intracellular signalling pathways via receptor-coupled phospholipase C and its "cross-talk" with phospholipase D converge to activation of protein kinase C isotypes which is followed by phosphorylation of until now (a number of) unknown target proteins which produce the protective state of ischemic preconditioning. After briefly introducing the general biochemical properties of protein kinase C, its isotypes and the limitations of the methodology used to investigate the role of protein kinase C, studies are discussed in which pharmacological inhibition and activation and (immunore) activity and/or isotypes measurements of protein kinase C isotypes were applied to assess the role of activation of protein kinase C in ischemic myocardial preconditioning. It is concluded that definitive proof for the involvement of protein kinase C in preconditioning requires future studies which must focus on the isotype(s) of protein kinase C that are activated, the duration of action, cellular translocation sites and the identity and stability (of covalently bound phosphate) of phosphorylated substrate proteins.

Hypoxia alters the subcellular distribution of protein kinase C isoforms in neonatal rat ventricular myocytes

Cardiac myocytes coexpress multiple protein kinase C (PKC) isoforms which likely play distinct roles in signaling pathways leading to changes in contractility, hypertrophy, and ischemic preconditioning. Although PKC has been reported to be activated during myocardial ischemia, the effect of ischemia/hypoxia on individual PKC isoforms has not been determined. This study examines the effect of hypoxia on the subcellular distribution of individual PKC isoforms in cultured neonatal rat ventricular myocytes. Hypoxia induces the redistribution of PKC alpha and PKC epsilon from the soluble to the particulate compartment. This effect (which is presumed to represent activation of PKC alpha and PKC epsilon) is detectable by 1 h, sustained for up to 24 h, and reversible within 1 h of reoxygenation. Inhibition of phospholipase C with tricyclodecan-9-yl-xanthogenate (D609) prevents the hypoxia-induced redistribution of PKC alpha and PKC epsilon, whereas chelation of intracellular calcium with 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA) blocks the redistribution of PKC alpha, but not PKC epsilon; D609 and BAPTA do not influence the partitioning of PKC alpha and PKC epsilon in normoxic myocytes. Hypoxia, in contrast, decreases the membrane association of PKC delta via a mechanism that is distinct from the hypoxia-induced translocation/activation of PKC alpha/PKC epsilon, since the response is slower in onset, slowly reversible upon reoxygenation, and not blocked by D609 or BAPTA. The hypoxia-induced shift of PKC delta to the soluble compartment does not prevent subsequent 4-beta phorbol 12-myristate-13-acetate-dependent translocation/activation of PKC delta. Hypoxia does not alter the abundance of any PKC isoform nor does it alter the subcellular distribution of PKC lambda. The selective hypoxia-induced activation of PKC isoforms through a pathway involving phospholipase C (PKC alpha/PKC epsilon) and intracellular calcium (PKC alpha) may critically influence cardiac myocyte contractility, gene expression, and/or tolerance to ischemia.

Does glycogen depletion play an important role in ischemic preconditioning?

The present study was undertaken to determine whether or not tissue glycogen depletion prior to ischemia, and subsequent attenuation of tissue lactate accumulation during ischemia, correlates with postischemic functional recovery of the preconditioned heart. Isolated rat hearts were subjected to 40-min ischemia and 30-min reperfusion. Preconditioning with 5-min ischemia and 5-min reperfusion reduced the preischemic glycogen and postischemic lactate levels of the heart to 60.5 +/- 5.6% and 66.9 +/- 7.7% respectively, of values in non-preconditioned hearts (n = 6), and improved the recovery of the rate-pressure product (RPP) of the ischemic/reperfused heart (87.0 +/- 5.8% versus 25.2 +/- 4.5% of the initial value for the non-preconditioned group, n = 8). Treatment with polymyxin B (50 microM) abolished the preconditioning-induced postischemic recovery of the RPP. Treatment of the non-preconditioned heart with phorbol 12-myristate 13-acetate (15 pmol/5 min) resulted in an improvement in the postischemic recovery of RPP. Neither of these treatments affected the preischemic glycogen and postischemic lactate levels. The results suggest that preischemic glycogen depletion and subsequent attenuation of ischemic lactate accumulation do not play a major role in the preconditioning-induced protection against postischemic contractile dysfunction in perfused rat hearts.

Adenosine prevents hyperkalemia-induced calcium loading in cardiac cells: relevance for cardioplegia

BACKGROUND

Hyperkalemic cardioplegic solutions effectively arrest the heart but also induce membrane depolarization, which could lead to intracellular Ca2+ loading and contribute to ventricular dysfunction associated with cardiac operations. Adenosine, which possesses cardioprotective properties, has been proposed as an adjunct to conventional cardioplegic solutions. However, it is not known whether adenosine supplementation enables cardiac cells to withstand hyperkalemia-induced Ca2+ loading.

METHODS

Single ventricular cardiomyocytes were isolated from guinea pig hearts, loaded with a Ca(2+)-sensitive fluorescent probe, and imaged by digital epifluorescent microscopy. The emitted fluorescence of the probe, a measure of the intracellular Ca2+ concentration, was recorded from single myocytes during hyperkalemic challenges in the absence and the presence of adenosine to assess the protective effectiveness of this agent.

RESULTS

Hyperkalemic solutions induced intracellular Ca2+ loading (estimated intracellular Ca2+ concentration, 88 +/- 5 nmol/L before and 1,825 +/- 112 nmol/L after addition of 16 mmol/L KCl). Adenosine (1 mmol/L) prevented K(+)-induced Ca2+ loading (intracellular Ca2+ concentration, 86 +/- 6 nmol/L before and 85 +/- 8 nmol/L after exposure to K+). Whereas glyburide (3 mumol/L), an antagonist of adenosine triphosphate-sensitive K+ channels, had no effect, staurosporine (200 nmol/L) and chelerythrine (5 mumol/L), two inhibitors of protein kinase C, did abolish the action of adenosine.

CONCLUSIONS

Adenosine prevents hyperkalemia-induced Ca2+ loading in cardiomyocytes. This effect is due to a direct action on ventricular cells, as the preparation employed was free from atrial, neuronal, and vascular elements, and appears to be mediated through a protein kinase C-dependent mechanism. The property of adenosine to prevent hyperkalemia-induced Ca2+ loading may contribute to the cytoprotective efficacy of this agent as an adjunct to conventional hyperkalemic cardioplegic solutions.

Specific induction of protein kinase C delta subspecies after transient middle cerebral artery occlusion in the rat brain: inhibition by MK-801

Protein kinase C (PKC) consists of a family of closely related Ca2+/phospholipid-dependent phosphotransferase isozymes, most of which are present in the brain and are differentially activated by second messengers. Calcium-dependent PKC activity may cause neuronal degeneration after ischemic insult. PKC is also involved in trophic-factor signaling, indicating that activity of some PKC subspecies may be beneficial to the injured brain. Therefore, we screened long-term changes in the expression of multiple PKC subspecies after focal brain ischemia. Middle cerebral artery occlusion was produced by using an intraluminal suture for 30 min of 90 min. In in situ hybridization experiments, mRNA levels of PKC alpha, -beta, -gamma, -delta, -epsilon, and -zeta were decreased in the infarct core 4 hr after ischemia and were lost completely 12 hr after ischemia. In areas surrounding the core, PKC delta mRNA was specifically induced 4, 12, and 24 hr after ischemia in the cortex. At 3 and 7 d, the core and a rim around it showed increased mRNA levels of PKC delta. No other subspecies were induced. At 2 d, immunoblotting demonstrated increased levels of PKC delta protein in the perifocal tissue, and immunocytochemistry revealed an increased number of PKC delta-positive neurons in the perifocal cortex. In the core, PKC delta-positive macrophages and endothelial cells were seen. Pretreatment with MK-801, an NMDA antagonist, inhibited cortical PKC delta mRNA induction. The data show that focal brain ischemia induces PKC delta mRNA and protein but not other PKC subspecies through the activation of NMDA receptors and that the upregulation lasts for several days in neurons of the perifocal zone.

Mast cell degranulation does not contribute to ischemic preconditioning in isolated rabbit hearts

Preconditioning the heart with a short period of ischemia makes it resistant to infarction from a subsequent ischemic insult. We have proposed that preconditioning is triggered by the release of endogenous substances including adenosine which activate protein kinase C through receptormediated cell signaling pathways. However, it has also been proposed that the initial brief ischemia may result in mast cell degranulation without significant myocardial damage, making it less likely that the toxic granule contents could be released to irreversibly damage vulnerable myocardial cells during the subsequent prolonged ischemia. To study the role of mast cells in ischemic preconditioning (PC) isolated rabbit hearts were subjected to 30 min of regional ischemia followed by 120 min of reperfusion. Infarct size was measured with triphenyltetrazolium chloride. In control hearts infarction was 31.9 +/- 2.6% of the risk zone. Preconditioning with 5 min of global ischemia and 10 min of reperfusion reduced infarct size to 5.6 +/- 6.1% (p < 0.01). When disodium cromoglycate (DSCG)(10 microM), a mast cell stabilizer, was infused shortly before the long ischemia it did protect the heart (12.8 +/- 2.9% infarction, p < 0.01 vs control) which supports the mast cell theory. However, a mast cell degranulating agent, compound 48/80 (24 mg/L), added to the perfusate prior to the 30 min ischemic period could not mimic PC (39.7 +/- 5.6% infarction). Mast cell granules are rich in histamine, and the latter was assayed in myocardium by immunoassay as a marker of intact granules. In homogenized left ventricle from normal rabbit hearts and those following a standard PC protocol of 5-min global ischemia/10-min reperfusion, histamine contents were 9.3 +/- 1.4 and 8.9 +/- 1.4 ng/g wet tissue, respectively. Compound 48/80 reduced histamine levels to 2.9 +/- 0.6 ng/g (p < 0.05 vs control). Although baseline histamine contents were 10-fold higher in rats, PC also had no effect, but compound 48/80 reduced content by 91%. Therefore, histamine tissue content and presumably mast cell granules were unaffected by a PC protocol which successfully protected ischemic myocardium, while pharmacological myocardial histamine depletion was not associated with protection. Hence, mast cells do not appear to be important in ischemic preconditioning. Although a mast cell stabilizer such as DSCG can protect ischemic myocardium, it may do so by one of its other properties, e.g., membrane stabilization.

The role of protein kinase in C ischemic/reperfused preconditioned isolated rat hearts

Protein kinase C (PKC) has been implicated in the preconditioning-induced cardiac protection in ischemic/reperfused myocardium. We studied the effect of PKC inhibition with calphostin C (25, 50, 100, 200, 400, and 800 nM), a potent and specific inhibitor of PKC, in isolated working nonpreconditioned and preconditioned ischemic/reperfused hearts. In the nonpreconditioned groups, all hearts underwent 30 min of normothermic global ischemia followed by 30 min of reperfusion. In the preconditioned groups, hearts were subjected to four cycles of ischemic preconditioning by using 5 min of ischemia followed by 10 min reperfusion, before the induction of 30 min ischemia and reperfusion. At low concentrations of calphostin C (25, 50, and 100 nM), the PKC inhibitor had no effect on the incidence or arrhythmias or postischemic cardiac function in the nonpreconditioned ischemic/reperfused groups. With 200 and 400 nM of calphostin C, a significant increase in postischemic function and a reduction in the incidence of arrhythmias were observed in the nonpreconditioned ischemic/reperfused groups. Increasing the concentration of calphostin C to 800 NM, the recovery of postischemic cardiac function was similar to that of the drug-free control group. In preconditioned hearts, lower concentrations (< 100 nM) of calphostin C did not change the response of the myocardium to ischemia and reperfusion in comparison to the preconditioned drug-free myocardium. Two hundred and 400 nM of the PKC inhibitor further reduced the incidence of ventricular fibrillation (VF) from the preconditioned drug-free value of 50% to 0 (p < 0.05) and 0 (p < 0.05), respectively, indicating that the combination of the two, preconditioning and calphostin C, affords significant additional protection. Increasing the concentration of calphostin C to 800 nM blocked the cardioprotective effect of preconditioning (100% incidence of VF). The recovery of cardiac function was similarly improved at calphostin C doses of 200 and 400 nM and was reduced at 800 nM (p < 0.05). With 200 and 400 nM of calphostin C, both cytosolic and particulate PKC activity were reduced by approximately 40 and 60%, respectively, in both preconditioned and preconditioned/ischemic/reperfused hearts. The highest concentration of calphostin C (800 nM) resulted in almost a complete inhibition of cytosolic (100%) and particulate (85%) PKC activity correlated with the abolition of preconditioning-induced cardiac protection. In conclusion, calphostin C protects the ischemic myocardium obtained from intact animals, provides significant additional protection to preconditioning at moderate doses, and blocks the protective effect of preconditioning at high concentrations. The dual effects of calphostin C appear to be strictly dose and "enzyme inhibition" related.

Translocation of protein kinase C-alpha, delta and epsilon isoforms in ischemic rat heart

To explore the spatial and temporal localization of PKC isoforms during ischemia, we quantified PKC isoforms in the subcellular fractions in perfused rat heart by immunoblotting using specific antibodies against PKC isoforms. PKCs-alpha and epsilon translocated from the 100000 x g supernatant (S, cytosolic) fraction to the 1000 x g pellet (PI, nucleus-myofibril) and the 1000-100000 x g pellet (P2, membrane) fractions during 5-40 min of ischemia. PKC-delta redistributed from the P2 to the S fraction. A 50-kDa fragment of PKC-alpha appeared during ischemia possibly through calpain action. Immunohistochemical observations showed the different localizations of PKC-alpha, delta, and epsilon in the myocytes. The PKC assay displayed high basal levels of Ca(2+)-independent PKC, the activation of Ca(2+)-dependent PKC in the P1 and P2 fractions, and the activation of Ca(2+)-independent PKC in the P1 fraction after 20 min of ischemia. These observations show that ischemia induces different patterns of translocation of the three PKC isoforms, suggesting differences in their roles.

The slowing of ischemic energy demand in preconditioned myocardium

One or several brief episodes of myocardial ischemia (ischemic preconditioning; IP) rapidly induces tolerance to a later ischemic challenge. This endogenous cardioprotective effect is characterized by a slower onset of cell death. A key feature and probable proximate mechanism of IP is reduced ischemic energy demand which is evident by slower use of ATP and slower accumulation of ischemic catabolites. Several mechanisms for IP and the associated metabolic slowing have been studied: The mitochondrial ATPase is a major cause of ATP hydrolysis in ischemic myocardium but slower ATP depletion in preconditioned myocardium is not due to persistent inhibition of this ATPase. Brief episodes of ischemia in dogs induce stunning as well as IP. Stunning, however, is neither necessary nor sufficient to establish the protective effects of IP. Release of norepinephrine from adrenergic cardiac nerves causes beta adrenergic receptor-mediated stimulation of adenylate cyclase, which stimulates energy-dependent processes. However, IP in dogs that were depleted of catecholamines by pretreatment with reserpine was less effective than IP in control hearts. Thus, an antiadrenergic mechanism does not fully account for the preconditioned state. Another proposed mechanism involves earlier or more complete opening of ATP-sensitive potassium (KATP+) channels. Which of these (or other) pathways mediate the energy sparing effects of ischemic preconditioning remains unknown.

Stress-induced cardioadaptation reveals a code linking hormone receptors and spatial redistribution of PKC isoforms

Extracellular agents, including growth factors, cytokines and hormones, transmit their information into cells utilizing a balanced mosaic of intracellular phosphatases and kinases. How do these agonists select the correct substrates and modify them in order to produce defined physiological responses? Our studies have centered on the mechanisms of stress-induced cardioprotection (preconditioning) against postischemic dysfunction. In several species, the ischemia-reperfusion resistant phenotype appears to be induced by metabotropic-receptor pathways linked to PKC. Our results on the isolated rat heart show that each protective stimulus involves a characteristic mosaic of PKC isoforms, translocating into distinct cellular compartments. The distinct receptor-stimulated PKC isoform profile engaged by each extracellular metabotropic agent could allow the heart several overlapping modes of phenotypic adaptation to ischemia.

Intramyocardial infusion of tool drugs for the study of molecular mechanisms in ischemic preconditioning

Many of the new tool drugs useful for the study of molecular mechanisms of ischemic preconditioning (IP) are very valuable in in vitro systems but produce undesired side-effects after systemic injection in intact animals that limit their applicability. Our aim was to develop an experimental in vivo model that allows the use of said drugs in sufficiently high local concentrations, but avoiding at the same time the systemic side-effects. Several techniques were combined to study regional damage or protection as a result of local drug infusion such as nuclear staining, NADH fluorescence, fluorescent microspheres and tetrazolium salts. In open-chest pigs, the intramyocardial infusion (20 microliters/min) of the adenosine A1-receptor agonist N6-cyclohexyladenosine (0.3 mmol) for 10 min prior to a 60-min LAD-occlusion and 120-min reperfusion mimicked IP by exerting a local protection (n = 9, p < 0.001). Krebs-Henseleit buffer (negative control) was without protective effect. IP's cardioprotection was locally prevented by the intramyocardial application of the adenosine A1-receptor antagonist cyclopentyltheophylline (1 mmol, infused during IP; n = 6, p < 0.001) but not by KHB. The protein kinase C (PKC)-inhibitors staurosporine (100 nmol, n = 6) or bisindolylmaleimide (BIS, 25 mumol, n = 9) did not prevent IP locally. The PKC activator phorbol myristate acetate (PMA, 1 mumol, n = 6) was ineffective in preventing ischemic injury and increased the amount of necrosis in IP, whereas BIS exerted a local myocardial protection (n = 9, p < 0.001). In conclusion, the new model of intramyocardial infusion appears to be useful for the investigation of IP's signal transduction. Our data support the role of the adenosine A1-receptor in IP, but suggest that inhibition instead of activation of PKC may protect ischemic myocardium from infarction.

Cardiac preconditioning with calcium: clinically accessible myocardial protection

Cardiac preconditioning is mediated by protein kinase C. Although endogenous calcium is a potent stimulus of protein kinase C, it remains unknown whether preischemic administration of exogenous calcium can induce protein kinase C-mediated myocardial protection against ischemia-reperfusion injury. To study this, calcium chloride was administered retrogradely through the aorta at a rate 5 nmol/min for 2 minutes to isolated perfused rat hearts 10 minutes before a 20-minute ischemia and 40-minute reperfusion insult. Calcium-mediated cardioadaptation was then linked to protein kinase C by means of the protein kinase C inhibitor chelerythrine (20 mumol.L-1.2 min-1). To determine whether exogenous calcium administration induces protein kinase C translocation and activation, immunohistochemical staining for the calcium-dependent protein kinase C isoform alpha was performed on adjacent 5 microns myocardial sections with and without calcium chloride treatment. Results indicated that preischemic calcium chloride administration improved myocardial functional recovery, as determined by enhanced developed pressure, improved coronary flow, reduced end-diastolic pressure, and decreased creatine kinase leakage during reperfusion. Beneficial effects of calcium chloride were eliminated by concurrent protein kinase C inhibition. Immunohistochemical staining for the alpha isoform of protein kinase C demonstrated that calcium chloride induces translocation of this isoform from the cytoplasm to the sarcolemma, indicating that exogenous calcium administration activates this isoform. These results suggest that calcium chloride, a safe and routinely administered agent, can induce protein kinase C-mediated cardiac preconditioning. Calcium-induced cardioadaptation to ischemia-reperfusion injury may be promising as a clinically feasible therapy before planned ischemic events such as cardiac allograft preservation and elective cardiac operations.

Protection induced by a brief ischemic episode in the Langendorff perfused rat heart

RATIONALE AND OBJECTIVES

Ischemic episodes lasting approximately 1 min may be associated with coronary angioplasty. We explored whether such episodes could induce myocardial protection against prolonged ischemic episodes in an ex vivo model.

METHODS

Protection afforded by pretreatment with a 1-min ischemic episode (ischemic preconditioning) against prolonged ischemia was investigated in the isolated rat heart. Left ventricular developed pressure (LVDP; LV systolic pressure-LV end-diastolic pressure), heart rate (HR), and enzyme leakage (lactate dehydrogenase) were indexes of protection.

RESULTS

An increased recovery of LVDP x HR after 16 and 19 min of ischemia of 37% and 28%, respectively, paralleled by reduced enzyme leakage, was observed in preconditioned hearts after 10 min of reperfusion. However, the difference between preconditioned and control hearts was lost after 30 min of reperfusion.

CONCLUSION

Ischemic episodes lasting approximately 1 min are not sufficient to initiate stable protection even if initial functional and metabolic indexes suggest a protective effect.

The obligate role of protein kinase C in mediating clinically accessible cardiac preconditioning

BACKGROUND

Cardiac preconditioning is an adaptation of cardiomyocytes that promotes tolerance to a subsequent ischemic insult. Adenosine receptor signaling is proposed as a mediator of preconditioning, but its mechanism of protection remains unknown. We hypothesized that protection against hypoxia-reoxygenation (H/R) injury could be conferred in a rat ventricle by adenosine-mediated protein kinase C (PKC) activation and that adenosine-mediated cardioprotection could be extended to human ventricular muscle.

METHODS

Isolated rat and human ventricular muscle (VM) strips were subjected to 30 minutes of hypoxia and 60 minutes of reoxygenation (H/R control). The VM was pretreated with 125 mumol/L adenosine, an adenosine antagonist ((p-Sulfophenyl) theophylline [SPT] 50 mumol/L) and adenosine (adenosine + SPT), or with a PKC inhibitor (chelerythrine, 10 mumol/L) and adenosine (adenosine + chelerythrine) before H/R Developed force (DF) and tissue creatine kinase (CK) activity were assessed at end reoxygenation. Human trabeculae were obtained from diseased explanted hearts at cardiac transplantation and were also subjected to H/R injury. Human VM was pretreated with adenosine (125 mumol/L) before H/R injury. Results are expressed as mean +/- standard error of mean.

RESULTS

In the rat, adenosine pretreatment conferred protection of DF against H/R injury (adenosine, 62% +/- 6%; H/R control, 27% +/- 2%, p < 0.05). Adenosine + SPT or adenosine + chelerythrine eliminated the functional recovery conferred by adenosine. This recovery of contractile function was associated with greater tissue CK activity (adenosine, 415 +/- 40 units/gm; H/R control, 78 +/- 13 units/gm, p < 0.05). The protective effects of adenosine against H/R were present in the human ventricle and with recovery of DF in adenosine (66% +/- 5%) and H/R control (24% +/- 4%), p < 0.05.

CONCLUSIONS

Adenosine, a clinically accessible agonist, induces protection against H/R injury through a PKC-mediated mechanism in the rat ventricle. Further, the protection conferred by adenosine against H/R extends to the human ventricle.

Stimulation of phosphatidylinositol hydrolysis, protein kinase C translocation, and mitogen-activated protein kinase activity by bradykinin in rat ventricular myocytes: dissociation from the hypertrophic response

In ventricular myocytes cultured from neonatal rat hearts, bradykinin (BK), kallidin or BK(1-8) [(Des-Arg9)BK] stimulated PtdinsP2 hydrolysis by 3-4-fold. EC50 values were 6 nM (BK), 2 nM (kallidin), and 14 microM [BK(1-8)]. BK or kallidin stimulated the rapid (less than 30 s) translocation of more than 80% of the novel protein kinase C (PKC) isoforms nPKC-delta and nPKC-epsilon from the soluble to the particulate fraction. EC50 values for nPKC-delta translocation by BK or kallidin were 10 and 2 nM respectively. EC50 values for nPKC-epsilon translocation by BK or kallidin were 2 and 0.6 nM respectively. EC50 values for the translocation of nPKC-delta and nPKC-epsilon by BK(1-8) were more than 5 microM. The classical PKC, cPKC-alpha, and the atypical PKC, nPKC-zeta, did not translocate. BK caused activation and phosphorylation of p42-mitogen-activated protein kinase (MAPK) (maximal at 3-5 min, 30-35% of p42-MAPK phosphorylated). p44-MAPK was similarly activated. EC50 values for p42/p44-MAPK activation by BK were less than 1 nM whereas values for BK(1-8) were more than 10 microM. The order of potency [BK approximately equal to kallidin >> BK (1-8)] for the stimulation of PtdInsP2 hydrolysis, nPKC-delta and nPKC-epsilon translocation, and p42/p44-MAPK activities suggests involvement of the B2 BK receptor subtype. In addition, stimulation of all three processes by BK was inhibited by the B2BK receptor-selective antagonist HOE140 but not by the B1-selective antagonist Leu8BK(1-8). Exposure of cells to phorbol 12-myristate 13-acetate for 24 h inhibited subsequent activation of p42/p44-MAPK by BK suggesting participation of nPKC (and possibly cPKC) isoforms in the activation process. Thus, like hypertrophic agents such as endothelin-1 (ET-1) and phenylephrine (PE), BK activates PtdInsP2 hydrolysis, translocates nPKC-delta, and nPKC-epsilon, and activates p42/p44-MAPK. However, in comparison with ET-1 and PE, BK was only weakly hypertrophic as assessed by cell morphology and patterns of gene expression. This difference could not be attributed to dissimilarities between the duration of activation of p42/p44-MAPK by BK or ET-1. Thus activation of these signalling pathways alone may be insufficient to induce a powerful hypertrophic response.

Preconditioning does not prevent postischemic dysfunction in aging heart

OBJECTIVES

This study was performed to investigate the effect of single or multiple brief periods of ischemia and the administration of exogenous norepinephrine before a more prolonged ischemic period and after reperfusion in adult and senescent isolated and perfused rat hearts.

BACKGROUND

The mortality rate for coronary artery disease is greater in the elderly. Ischemic preconditioning has been proposed as an endogenous form of protection against ischemia-reperfusion injury. However, the role of preconditioning in aging heart is unknown.

METHODS

We compared the protective effect of preconditioning transient ischemic and norepinephrine stimuli against 20 min of global normothermic ischemia and 40 min of reperfusion in isolated perfused hearts of adult (6 months old) and senescent (24 months old) rats. Norepinephrine release in coronary effluent was determined by high performance liquid chromatography.

RESULTS

Final recovery of percent developed pressure was improved after single preconditioning transient ischemic and norepinephrine stimuli in adult hearts (87.7 +/- 9% and 82.3 +/- 8.7%) versus unconditioned control hearts (50.6 +/- 4.8%, p < 0.01 [mean +/-SD]). The effect of preconditioning on developed pressure recovery was not present in senescent hearts after transient ischemic stimulus (39.8 +/- 4.9% vs. 41.6 +/- 5.8%, p = NS) but was present after norepinephrine stimulus (74.3 +/- 10.5, p < 0.01). Norepinephrine release significantly increased after preconditioning transient ischemic stimulus in adult but not in senescent hearts (p < 0.01 vs. adult). Transient ischemic- and norepinephrine-induced preconditioning was blocked by alpha-adrenergic receptor antagonists in both adult and senescent hearts. Multiple transient ischemic stimuli were able to reduce postischemic dysfunction in adult but not in senescent hearts.

CONCLUSIONS

Preconditioning transient ischemic stimulus significantly reduces postischemic dysfunction in adult but not in senescent hearts, whereas exogenous norepinephrine is able to mimic preconditioning in both adult and senescent hearts. Ischemic preconditioning induces an increase in norepinephrine release in adult but not in senescent hearts. Preconditioning induced by transient ischemic stimulus and norepinephrine was abolished by alpha-adrenergic receptor blockade in both adult and senescent hearts. Thus, our data demonstrate that preconditioning is absent in aging heart and is probably related to the reduction of norepinephrine release and alpha-adrenergic receptor stimulation in response to ischemic preconditioning.

Pretreatment with ischaemia attenuates acute epirubicin-induced cardiotoxicity in isolated rat hearts

We investigated whether a brief ischaemic episode (ischaemic pretreatment) preconditioning might attenuate the acute cardiotoxicity of the anthracycline, epirubicin. Isolated rat hearts perfused at a constant flow rate of 10 ml/min, were preconditioned with 5 min. of global ischaemia and 10 min. of reperfusion (preconditioned hearts), or were perfused for 15 min. (control hearts). The hearts were then subjected to 20 min. of infusion with epirubicin (2 mg/ml) or vehicle by a side arm of the perfusion system at a rate of 0.1 ml/min. (0.2 mg epirubicin/min.). Attenuation of cardiotoxicity of a total dose of 4 mg of epirubicin was assessed by functional and metabolic parameters during infusion and during the following 30 min. recovery period. Cardiotoxic effects were reduced in preconditioned hearts compared to control hearts. Thus left ventricular developed pressure and heart rate product after 20 min. of epirubicin infusion was depressed to 27 +/- 7% (mean +/- S.D.) and 40 +/- 4% (mean +/- S.D.) of baseline values in the control group and the preconditioned group, respectively (P < 0.05). Furthermore, we observed less contracture during epirubicin infusion and more effective reversal of contracture during the recovery period in the preconditioned hearts. Improvement in cardiac function was associated with a significantly lower (P < 0.05) myocardial content of epirubicin in the preconditioned group at the end of the infusion period. We conclude that ischaemic preconditioning attenuates the acute cardiotoxicity of epirubicin, probably by reducing the myocardial accumulation of the anthracycline.

Adenosine mediates the antiarrhythmic effect of ischemic preconditioning in isolated rat hearts

Adenosine appears to mediate the preconditioning-induced reduction in infarct size in rabbits and dogs, but little is known about the role of adenosine in preconditioning-induced protection against ischemia-induced arrhythmias. We compared the effects of preconditioning induced by 2 cycles of 5 min of global ischemia and 2 cycles of 5 min of perfusion with either adenosine (100 mumol/L) or the adenosine A1-selective agonist 2-chloro-N6-cyclopentyladenosine (CCPA, 100 nmol/L) in protecting against ischemia-induced arrhythmias in Langendorff-perfused rat hearts. Preconditioning reduced the incidence of ventricular tachycardia (VT) from 100 to 58% and the incidence of sustained VT or ventricular fibrillation (VF) from 92 to 33%. Perfusion with adenosine reduced the incidence of VT from 100 to 55%, the incidence of VF from 67 to 9% and the incidence of sustained VT or VF from 92 to 9%. CCPA reduced the incidence of sustained VT or VF from 92 to 25%. These interventions provided a true reduction in the severity of arrhythmias, rather than merely a delay in the onset. Our results suggest that the stimulation of A1 receptor by adenosine is involved in triggering ischemic preconditioning-induced protection against ischemia-induced arrhythmias in rats.

Is potassium channel opening an effective form of preconditioning before cardioplegia?

BACKGROUND

Opening of adenosine triphosphate-sensitive potassium channels might be one of the mechanisms by which preconditioning preserves the myocardium against ischemic damage. The present study was therefore designed to compare the protective efficacy of ischemic preconditioning with that of pharmacologic preconditioning involving the use of a potassium channel opener in a surgically relevant model of cold cardioplegic arrest.

METHODS

Thirty isolated isovolumic rat hearts were subjected to 2 hours of potassium arrest at an average myocardial temperature of 23 degrees C, followed by 1 hour of reperfusion. Three groups (n = 10 per group) were studied: (1) control (no prearrest intervention); (2) ischemic preconditioning, achieved with 5 minutes of noflow ischemia followed by 5 minutes of reperfusion before arrest; and (3) pharmacologic preconditioning, achieved with a 5-minute infusion of the potassium channel opener nicorandil (10 mumol/L) followed by 5 minutes of drug-free perfusion before arrest. Standard functional indices were measured at multiple times during reperfusion, at the end of which pressure-volume curves were constructed and compared with those obtained at baseline.

RESULTS

Both ischemically and pharmacologically preconditioned hearts recovered systolic and diastolic function to a significantly greater extent than the controls. There was no difference in the recovery patterns between the forms of preconditioning. However, analysis of the postischemic pressure-volume curves demonstrated that nicorandil-preconditioned hearts incurred the smallest losses of compliance throughout the ischemia-reperfusion sequence.

CONCLUSIONS

The protective effects of a standard ischemic preconditioning challenge on functional recovery after an episode of moderately hypothermic cardioplegic arrest can be duplicated by pharmacologic opening of adenosine triphosphate-sensitive potassium channels. This finding may be of clinical relevance because of the availability of potassium channel openers, such as nicorandil, for human use.

No evidence for mediation of ischemic preconditioning by alpha 1-adrenergic signal transduction pathway or protein kinase C in the isolated rat heart

The purpose of this study was to elucidate the role of activation of the alpha 1-adrenergic signal transduction pathway and of protein kinase C (PKC) in the mechanism of protection of functional recovery by ischemic preconditioning in the isolated perfused rat heart. After a stabilization period, nonpreconditioned and preconditioned isolated perfused rat hearts were subjected to sustained ischemia for 25 and 30 minutes of reperfusion. Preconditioning consisted of three episodes of 5 minutes of ischemia, interspersed with 5 minutes of reperfusion. The endpoint was postischemic functional recovery. The effectiveness of preconditioning in the presence of the alpha 1-adrenergic blocker prazosin, the selective PKC blockers chelerythrine and bisindolylmaleimide (BIM), and the ability of repetitive alpha 1-adrenergic activation to mimic preconditioning were compared with the appropriate nonpreconditioned and preconditioned control groups. Alpha 1-adrenergic blockade with prazosin (3 x 10(-7) M) during the preconditioning phase did not abolish the protective effect of preconditioning on functional recovery, and repeated intermittent alpha 1-adrenergic activation with phenylephrine in different concentrations (1 x 10(-8) to 3 x 10(-5) M) did not mimic the protective effect of preconditioning. PKC blockade with the selective PKC inhibitors, chelerythrine (10 microM) and BIM (4 microM), did not abolish the protective effect of preconditioning on functional recovery is isolated perfused rat hearts when given either during the preconditioning phase or shortly before the onset of sustained ischemia. The characteristic metabolic changes of preconditioning during sustained ischemia, namely, energy sparing as manifested in reduced accumulation of lactate, were also not abolished by preconditioning in the presence of selective PKC blockers. We conclude that no evidence could be found for alpha 1-adrenergic or PKC activation in the mechanism of ischemic preconditioning in the isolated rat heart.

A comparison between ischemic preconditioning and anti-adrenergic interventions: cAMP, energy metabolism and functional recovery

OBJECTIVES

The postulate that ischemic preconditioning caused an attenuation in ischemia induced increases in tissue cAMP, and that this may pertain to the mechanism of ischemic preconditioning, was investigated in the isolated rat heart. A significant reduction in tissue cAMP in preconditioned hearts was observed for all time periods of global ischemia studied. The significance of this observation was evaluated by comparing the effect of anti-adrenergic interventions on energy metabolism and post-ischemic functional recovery of both non-preconditioned and preconditioned hearts.

METHODS

The isolated perfused rat heart was used as experimental model. Six groups were studied: Non-preconditioned rat hearts: i) untreated controls (Non-PC), ii) reserpinised (Non-PC Res), iii) propranolol treated (10(-7) M) (Non-PC Prop); Preconditioned rat hearts: iv) preconditioned controls (PC), v) reserpinised (PC Res) and vi) propranolol (10(-7) M) treated (PC Prop).

RESULTS

After 25 min global ischemia the concentration of cAMP was increased by 79.6% in the Non-PC group. This increase was attenuated in all of the treated groups, although in varying degrees. Energy utilization in these hearts also differed markedly between the groups. Functional recovery was however similar in all Non-PC and PC treated groups and significantly superior to that of Non-PC control hearts. Prior reserpinisation mimicked the protective effect of preconditioning on energy metabolism and functional recovery. To determine the significance of attenuation of the increase in cAMP in the protection conferred by preconditioning, hearts were pretreated with forskolin (10(-6) M). This caused an accumulation of tissue cAMP in preconditioned hearts to similar absolute values as seen in untreated non-preconditioned hearts during 25 min global ischemia. However, the percentage increase in forskolin-pretreated preconditioned hearts during sustained ischemia was only 50% vs. 71% in non-preconditioned hearts treated with forskolin, confirming an attenuated beta-response induced by preconditioning. Forskolin treatment of preconditioned hearts did not abolish the protective effect.

CONCLUSIONS

The findings suggest that the protection against ischemic damage conferred by preconditioning is associated with an attenuated beta-adrenergic response. However, whether the changes in cAMP occurring during sustained global ischemia is the cause of consequence of the elicited protection, remains to be established.

Cardiac surgical implications of calcium dyshomeostasis in the heart

The prevalence of coronary artery disease renders myocardial ischemia a leading cause of morbidity and mortality. Both cardiac bypass operations and cardiac transplantation cause myocardial ischemia and reperfusion injury. Intracellular calcium transport and regulation are of paramount importance in both normal and pathologic myocardial states. Calcium regulation is integral to nearly every myocyte function, from early development to senescence. Normal intracellular calcium-mediated excitation-contraction coupling and abnormal patterns of calcium regulation leading to systolic/diastolic dysfunction are now therapeutically accessible to the cardiac surgeon. Additionally, altered Ca2+ transport protein gene expression is a mechanism of myocardial dysfunction. Therapeutic strategies involve receptor-mediated transduction of signals to intracellular metabolic sites. Evidence implicates protein kinase C as well as a potential therapeutic role for Ca2+. The potential for pharmacologic access to this protective state has abundant clinical appeal. The protective state (cardiac "preconditioning") is transient but is amenable as therapy against operation-related ischemic events.

Decreased affinity of K-receptor binding during reperfusion following ischaemic preconditioning in the rat heart

The effects of ischaemic preconditioning with three cycles of ischaemia of 3 min and reperfusion of 5 min each cycle on ventricular fibrillation threshold (VFT) and ventricular fibrillation (VF), and binding properties of tritiated U69,593, a selective kappa opioid-receptor (k-receptor) agonist, during subsequent ischaemia and/or reperfusion were studied in the rat heart. It was found that ischaemic preconditioning significantly enhanced the VFT values during ischaemic and reperfusion. VF during the subsequent reperfusion period was also significantly reduced. The Kd of the [3H]U69,593 binding sites in the sarcolemma of the heart at 5 min of reperfusion was significantly increased following ischaemic preconditioning. The Bmax was, however, not altered after the preconditioning. The study provides evidence for the first time suggesting that the cardioprotective effects of ischaemic preconditioning may be related to a reduction in affinity of the K-receptor binding.

Optimal myocardial preservation: cooling, cardioplegia, and conditioning

Myocardial preservation techniques have evolved in conjunction with cardiac surgery and currently offer substantial protection against myocardial injury. We propose that cardiac preconditioning, a robust, endogenous mechanism of cardioprotection, is emerging as an important adjunct to current cardioplegic techniques. By reviewing the physiologic basis for current cardioplegic strategies, and understanding the cardioprotective benefits of preconditioning, we postulate that cardiac preconditioning may represent an important, clinically accessible component of myocardial protection.

Preconditioning with potassium channel openers. A new concept for enhancing cardioplegic protection?

Ischemic preconditioning defines an adaptive endogenous mechanism in which a brief episode of reversible ischemia renders the heart more resistant to a subsequent period of sustained ischemia. Because the cardioprotective effects of ischemic preconditioning might be mediated by an activation of adenosine triphosphate-sensitive potassium channels, this study was designed to assess whether these effects could be duplicated by the preischemic administration of a potassium channel opener. Fifty isolated isovolumic buffer-perfused rat hearts underwent 45 minutes of normothermic potassium arrest followed by 1 hour of reperfusion. They were divided into five equal groups that differed with regard to the preconditioning regimen: Group 1 hearts were left untreated and served a controls; in group 2, preconditioning was achieved with 5 minutes of total global ischemia followed by 5 minutes of buffer reperfusion before cardioplegic arrest; in group 3, the preconditioning stimulus consisted of a 5-minute infusion of the potassium channel opener nicorandil (10 mumol/L) followed by 5 minutes of drug-free buffer perfusion before arrest; group 4 hearts underwent a similar protocol except that the infusion of nicorandil was preceded by that of the potassium channel blocker glibenclamide (10 mumol/L); group 5 hearts were ischemically preconditioned like those of group 2 except that the no-flow preconditioning period was also preceded by a 5-minute infusion of glibenclamide (50 mumol/L). The results demonstrate that ischemic preconditioning significantly improved contractility and reduced contracture during reperfusion, as compared with results in control hearts. These protective effects were duplicated by pretreatment with nicorandil but were abolished when the drug was antagonized by a prior infusion of glibenclamide. Likewise, the glibenclamide-induced blockade of potassium channels largely blunted the beneficial effects of ischemic preconditioning. These data suggest that opening of adenosine triphosphate-sensitive potassium channels substantially contributes to preconditioning-induced cardiac protection in a surgically relevant model of global ischemia and, consequently, that the use of potassium channel openers like nicorandil could be an effective means of enhancing cardioplegic protection.

Myocardial and coronary endothelial protective effects of acetylcholine after myocardial ischaemia and reperfusion in rats: role of nitric oxide

1. Recent experiments suggest that acetylcholine (ACh) may exert myocardial protective effects during ischaemia (I) and reperfusion (R). The present study was designed (i) to assess whether ACh limits infarct size and protects coronary endothelial cells in a rat model of I and R, (ii) to evaluate the role of ATP-sensitive potassium (KATP) channels and nitric oxide (NO) in the beneficial effect of ACh (iii) to evaluate whether the protective effect of ACh also extends to coronary endothelial cells and (iv) to assess whether ACh contributes to the beneficial effect of preconditioning. 2. Anaesthetized rats were subjected to 20 min I (left coronary artery occlusion) and 2 h of R. Infarct size was assessed by triphenyltetrazolium (TTC) staining and expressed as a % of the area at risk (India ink injection). Vascular studies were performed on 1.5-2 mm coronary segments (internal diameter 250-300 micros) removed distal to the site of occlusion and mounted in wire myographs. 3. ACh limited infarct size (from 59 +/- 3 to 26 +/- 5%, P < 0.01), and this was prevented by atropine (46 +/- 7%; P < 0.05 vs ACh), but not by the inhibitor of KATP channels, glibenclamide (29 +/- 8%). The inhibitor of NO synthesis NG-nitro L-arginine did not affect infarct size (54 +/- 5%) but abolished the beneficial effect of ACh (59 +/- 8%; P < 0.05 vs ACh), whereas the NO donor 3-morpholinosydnonimine-N-ethylcarbamide (SIN-1 limited infarct size to the same extent as ACh (28 +/- 6%). Preconditioning also limited infarct size (5 +/- 2%, P< 0.01 vs control), and this was not affected by atropine (6 +/- 2%). I and R induced a significant decrease in the endothelium-dependent relaxations of isolated coronary arteries toACh (maximal response: sham: 58+/-4; I/R: 25+/-5%; P<0.01) and this dysfunction was prevented by prior in vivo treatment with ACh (55+/-7%; P<0.01 vs I/R) or (SIN-1 50+/-5%; P<0.05 vs I/R).4 Thus, in the rat model, ACh is able to stimulate potent endogenous protective mechanisms during I and R, which are evident both at the level of myocardial and coronary endothelial cells, and appear entirely mediated through the production of NO. Pharmacological stimulation of this endogenous protective mechanism may constitute a new approach in the treatment of acute myocaridal ischaemia.