Blockade of ATP-sensitive potassium channels prevents myocardial preconditioning in dogs

Ischemic preconditioning: emerging evidence, controversy, and translational trials

Protection against ischemia by ischemic preconditioning (IP) is seen in many tissues and organs. However, the preconditioning ischemia must precede lethal ischemia for this effect to occur, and the creation of ischemia to treat heart disease does not seem to be a realistic strategy. Accordingly, the underlying mechanisms that confer cardioprotection should be identified. Early studies revealed that IP causes two windows of cardioprotection, and subsequent efforts to detect cardioprotective factors have identified various triggers, mediators, and potent effectors of IP, such as endogenous receptor agonists (adenosine, catecholamines, bradykinin, and opioids), intracellular messengers [protein kinase C (PKC), p38MAPK, PI-3K, and PKA], ion channels such as KATP channels, enzymes including heat shock proteins (HSPs), superoxide dismutase (SOD), and 5'-nucleotidase, and other factors [nitric oxide (NO), growth factors, free radicals, and products of the arachidonic acid cascade]. Some of these factors are involved in several different pathways and may have multiple roles in IP-induced cardioprotection. Recently, however, certain problems have arisen such as controversies related to increasing knowledge and the relative lack of clinical studies in contrast to the intensive performance of basic studies. To overcome these problems, the latest studies have followed three major trends: (1) investigation of mechanisms to explain the current controversies, (2) detection of other unknown potent mechanisms, and (3) promotion of clinical trials based on the evidence from experimental studies in larger animals. Here, we summarize recent investigations on IP, emphasizing on the controversial issues and emerging factors, and discuss current research on the prevention or treatment of ischemic heart disease including some relevant clinical studies.

Preconditioning: evolution of basic mechanisms to potential therapeutic strategies

Preconditioning describes the phenomenon by which a traumatic or stressful stimulus confers protection against subsequent injury. Originally recognized in dog heart subjected to ischemic challenges, preconditioning has been demonstrated in multiple species, can be induced by various stimuli, and is applicable in different organ systems. Tremendous progress has been made elucidating the signal transduction cascade of preconditioning. Preconditioning represents a potent tissue-protective condition, and mechanistic understanding may allow safe clinical application. This review recalls the history of preconditioning and how it relates to the history of the investigation of endogenous adaptation; summarizes the current mechanistic understanding of acute preconditioning; outlines the signal transduction cascade leading to the development of delayed preconditioning; discusses preconditioning in noncardiac tissue; and explores the potential of using preconditioning clinically.

Difference in the cardioprotective mechanisms between ischemic preconditioning and pharmacological preconditioning by diazoxide in rat hearts

BACKGROUND

Recent studies have implicated the opening of mitochondrial K(ATP) (mitoK(ATP)) channels and the production of reactive oxygen species (ROS) in the cardioprotective mechanism of ischemic preconditioning (IPC).

METHODS AND RESULTS

The involvement of mitoK(ATP) channels and ROS in the cardioprotective effects of both IPC and the mitoK(ATP) channel opener diazoxide (DZ) was investigated in ischemic/reperfused rat hearts. The effects of IPC and DZ on myocardial high-energy phosphate concentrations and intracellular pH (pH(i)) were also examined using (31)P nuclear magnetic resonance spectroscopy. Although both the mitoK(ATP) channel inhibitor 5-hydroxydecanoate and the antioxidant N-acetylcysteine abolished the postischemic recovery of contractile function by DZ, neither of them inhibited that by IPC. IPC attenuated the decline in pHi during ischemia, but DZ did not (6.28+/-0.04 in IPC, p<0.05, and 6.02+/-0.05 in DZ vs 6.02 +/-0.06 in control hearts). DZ, but not IPC, reduced the decrease in ATP levels during ischemia (ATP levels at 20-min ischemia: 26.3+/-3.4% of initial value in DZ, p<0.05, and 8.1+/-3.0% in IPC vs 15.1+/-1.3% in control hearts).

CONCLUSIONS

These results suggest that DZ-induced cardioprotection is related to ROS production and reduced ATP degradation during ischemia, whereas attenuated acidification during ischemia is involved in IPC-induced cardioprotection, which is not mediated through mitoK(ATP) channel opening or ROS production.

Effects of nicorandil on cardiac sympathetic nerve activity after reperfusion therapy in patients with first anterior acute myocardial infarction

PURPOSE

Ischaemic preconditioning (PC) is a cardioprotective phenomenon in which short periods of myocardial ischaemia result in resistance to decreased contractile dysfunction during a subsequent period of sustained ischaemia. Nicorandil, an ATP-sensitive potassium channel opener, can induce PC effects on sympathetic nerves during myocardial ischaemia. However, its effects on cardiac sympathetic nerve activity (CSNA) and left ventricular remodelling have not been determined. In this study, we sought to determine whether nicorandil administration improves CSNA in patients with acute myocardial infarction (AMI).

METHODS

We studied 58 patients with first anterior AMI, who were randomly assigned to receive nicorandil (group A) or isosorbide dinitrate (group B) after primary coronary angioplasty. The nicorandil or isosorbide dinitrate was continuously infused for >48 h. The extent score (ES) was determined from 99mTc-pyrophosphate scintigraphy, and the total defect score (TDS) was determined from 201Tl scintigraphy 3-5 days after primary angioplasty. The left ventricular end-diastolic volume (LVEDV) and left ventricular ejection fraction (LVEF) were determined by left ventriculography 2 weeks later. The delayed heart/mediastinum count (H/M) ratio, delayed TDS and washout rate (WR) were determined from 123I-meta-iodobenzylguanidine (MIBG) images 3 weeks later. The left ventriculography results were re-examined 6 months after treatment.

RESULTS

Fifty patients originally enrolled in the trial completed the entire protocol. After treatment, no significant differences were observed in ES or left ventricular parameters between the two groups. However, in group A (n=25), the TDSs determined from 201Tl and 123I-MIBG were significantly lower (26+/-6 vs 30+/-5, P<0.01, and 32+/-8 vs 40+/-6, P<0.0001, respectively), the H/M ratio significantly higher (1.99+/-0.16 vs 1.77+/-0.30, P<0.005) and the WR significantly lower (36%+/-8% vs 44%+/-12%, P<0.005) than in group B (n=25). Moreover, 6 months after treatment, LVEDV and LVEF were better in group A than in group B.

CONCLUSION

These findings indicate that nicorandil can have beneficial effects on CSNA and left ventricular remodelling in patients with first anterior AMI.

PKC-epsilon is upstream and PKC-alpha is downstream of mitoKATP channels in the signal transduction pathway of ischemic preconditioning of human myocardium

Protein kinase C (PKC) is involved in the process of ischemic preconditioning (IPC), although the precise mechanism is still a subject of debate. Using specific PKC inhibitors, we investigated which PKC isoforms were involved in IPC of the human atrial myocardium sections and to determine their temporal relationship to the opening of mitochondrial potassium-sensitive ATP (mitoKATP) channels. Right atrial muscles obtained from patients undergoing elective cardiac surgery were equilibrated and then randomized to receive any of the following protocols: aerobic control, 90-min simulated ischemia/120-min reoxygenation, IPC using 5-min simulated ischemia/5-min reoxygenation followed by 90-min simulated ischemia/120-min reoxygenation and finally, PKC inhibitors were added 10 min before and 10 min during IPC followed by 90-min simulated ischemia/120-min reoxygenation. The PKC isoforms inhibitors investigated were V1-2 peptide, GO-6976, rottlerin, and LY-333531 for PKC-epsilon, -alpha, -delta and -beta, respectively. To investigate the relation of PKC isoforms to mitoKATP channels, PKC inhibitors found to be involved in IPC were added 10 min before and 10 min during preconditioning by diazoxide followed by 90-min simulated ischemia/120-min reoxygenation in a second experiment. Creatine kinase leakage and methylthiazoletetrazolium cell viability were measured. Phosphorylation of PKC isoforms after activation of the sample by either diazoxide or IPC was detected by using Western blot analysis and then analyzed by using Scion image software. PKC-alpha and -epsilon inhibitors blocked IPC, whereas PKC-delta and -beta inhibitors did not. The protection elicited by diazoxide, believed to be via mitoKATP channels opening, was blocked by the inhibition of PKC-alpha but not -epsilon isoforms. In addition, diazoxide caused increased phosphorylation of PKC-alpha to the same extent as IPC but did not affect the phosphorylation of PKC-epsilon, a process believed to be critical in PKC activation. The results demonstrate that PKC-alpha and -epsilon are involved in IPC of the human myocardium with PKC-epsilon being upstream and PKC-alpha being downstream of mitoKATP channels.

Plasmolemmal potassium gradient does not affect lung protection by an ATP-regulated potassium channel opener

BACKGROUND

We have previously shown that metabolic arrest induced with ATP-regulated potassium channel openers (PCOs) can improve lung preservation by adding Aprikalim (a PCO, Rhone-Poulene Roher) to modified Euro-Collins solution for pulmonary artery flush. Because the membrane hyperpolarizing effects of a PCO potentially competes with the depolarizing effects of a hyperkalemic solution, this study evaluated the effects of the potassium gradient on PCO-mediated lung protection.

STUDY DESIGN

Twenty rabbits underwent lung protection in four groups. Group 1 underwent harvest and reperfusion as a "no ischemia" control. Groups 2, 3, and 4 underwent harvest followed by 18 hours of cold ischemic storage before reperfusion. Groups 1 and 4 received Euro Collins as the pulmonary flush at induction of ischemia. Group 2 received Euro Collins plus Aprikalim (100 microM); and group 3 received lactated Ringer's plus Aprikalim. After ischemic storage, the lungs were reperfused with autologous blood for 2 hours. Every 30 minutes, the lungs were given a 10-minute 100% fractional inspired oxygen (F(i)O(2)) challenge to measure maximal gas exchange as an indication of graft function.

RESULTS

Repeated measures ANOVA showed Aprikalim improved graft function after 18 hours of cold ischemia (p < 0.0001). No significant differences were found when Aprikalim was used in either Euro-Collins (group 2) or lactated Ringer's (group 3) solution.

CONCLUSIONS

The ability of the PCO Aprikalim to preserve gas exchange in a model of hypothermic pulmonary ischemia-reperfusion injury was not affected by the plasmolemmal potassium gradient. This is consistent with recent findings in myocardial protection studies that the protective effects of PCOs may be intracellular.

Cardiac protection during acute myocardial infarction: Where do we stand in 2004?

Despite better outcomes with early coronary artery reperfusion for the treatment of acute ST-elevation myocardial infarction (MI), morbidity and mortality from acute myocardial infarction (AMI) remain significant, the incidence of congestive heart failure continues to increase, and there is a need to provide better cardioprotection (therapy that reduces the amount of necrosis that may be coupled with better clinical outcome) in the setting of AMI. Since the introduction of the concept of cardiac protection over a quarter of a century ago, various interventions have been investigated to reduce myocardial infarct size. Intravenous beta-blockers administered in the early hours of infarction were clearly shown to be of benefit. Intravenous adenosine appeared promising for anterior wall AMIs, as did cariporide in some studies. Glucose-insulin-potassium infusion was beneficial in certain subgroups of patients, particularly diabetics. A variety of other medications were studied with negative or marginal results. The best strategy to limit infarct size is early reperfusion with percutaneous coronary stenting or thrombolytic therapy. Stenting is superior and should be adopted whenever there is a qualified laboratory available. Available resources should focus on decreasing time from onset of symptoms to start of reperfusion and maintaining vessel patency. Future studies powered to better assess clinical outcome are needed for adjunctive therapy with adenosine, K(ATP) channel openers, Na(+)/H(+) exchange inhibitors, and hypothermia.

Differential activation of protein kinase C between ischemic and pharmacological preconditioning in the rabbit heart

The objective of the present study was to investigate the differential activation of protein kinase C between ischemic (IPC) and pharmacological preconditioning (PPC) in the rabbit heart. Control, IPC, diazoxide (Diaz), and chelerythrine (Chel)+IPC groups underwent prolonged coronary artery occlusion (CAO) for 30 minutes followed by 180 minutes' reperfusion (protocol I). In protocol II, sham, IPC-only, Diaz-only, and Chel+IPC-only groups did not undergo prolonged CAO. IPC was induced with 4 cycles of 5-min regional ischemia and 10-min reperfusion before prolonged CAO. Diaz (5 mg/kg) was administered 30 min before prolonged CAO. Chel (5 mg/kg) was administered 5 min before the IPC procedure. Infarct size was determined by tetrazolium staining. Assessment of protein kinase C (PKC) isoforms from a left ventricular (LV) sample was conducted by western blotting. Apoptosis in situ was determined by TUNEL assay. The infarction area in the IPC (11.6 +/- 1.0%) and Diaz (19.5 +/- 3.8%) groups was reduced significantly (p< 0.01, p< 0.05) relative to the control group (40.0 +/- 3.8%). The reduction by IPC was abolished by pretreatment with Chel. Apoptosis was significantly decreased (p< 0.01) in the IPC and diazoxide groups compared with the control and Chel+IPC groups (control: 4.78 +/- 0.56% vs. IPC: 2.00 +/- 0.38% vs. Diaz: 2.20 +/- 0.32% vs. Chel+IPC: 4.32 +/- 0.41%) and DNA laddering was attenuated in the IPC and Diaz groups. Membrane PKC-epsilon levels in the IPC and Diaz groups increased significantly relative to the control and Chel+IPC groups. Membrane PKC-epsilon levels in the IPC-only group showed greater increases than the Diaz-only and Chel+IPC-only groups. These findings suggest that whereas PPC suppresses apoptosis when diazoxide opens mitochondrial K(ATP) channels and then activates PKC-epsilon through ischemia-reperfusion, IPC activates PKC-epsilon in the particulate fraction prior to continuous ischemia-reperfusion. We concluded that the difference between IPC and PPC appears to consist in the difference in the timing of PKC-epsilon activation, though both IPC and PPC provide the cardioprotection in ischemia-reperfusion injury.

[How to use the paradigm of ischemic preconditioning to protect the heart?]

Ischemic preconditioning affords the most powerful protection to a heart submitted to a prolonged ischemia-reperfusion. During the past decade, a huge amount of work allowed to better understand the features of this protective effect as well as the molecular mechanisms. Ischemic preconditioning reduces infarct size and improves functional recovery; its effects on arrhythmias remain debated. Triggering of the protection involves cell surface receptors that activate pro-survival pathways including protein kinase C, PI3-kinase, possibly Akt and ERK1/2, whose downstream targets remain to be determined. Much attention has been recently focused on the role of mitochondrial K(+)ATP channels and the permeability transition pore that seem to play a major role in the progression toward irreversible cellular injury. Based on these experimental studies attempts have been made to transfer preconditioning from bench to bedside. Human experimental models of ischemic preconditioning have been set up, including cardiac surgery, coronary angioplasty or treadmill exercise, to perform pathophysiological studies. Yet, protecting the heart of CAD (coronary artery disease) patients requires a pharmacological approach. The IONA trial has been an example of the clinical utility of preconditioning. It helped to demonstrate that chronic administration of nicorandil, a K(+)ATP opener that mimics ischemic preconditioning in experimental preparations, improves the cardiovascular prognosis in CAD patients. Recent experimental studies appear further encouraging. It appears that "postconditioning" the heart (i.e. performing brief episodes of ischemia-reperfusion at the time of reperfusion) is as protective as preconditioning. In other words, a therapeutic intervention performed as late as at the time of reflow can still significantly limit infarct size. Further work is needed to determine whether this may be transferred to the clinical practice.

KATP channel openers: structure-activity relationships and therapeutic potential

ATP-sensitive potassium channels (K(ATP) channels) are heteromeric complexes of pore-forming inwardly rectifying potassium channel subunits and regulatory sulfonylurea receptor subunits. K(ATP) channels were identified in a variety of tissues including muscle cells, pancreatic beta-cells, and various neurons. They are regulated by the intracellular ATP/ADP ratio; ATP induces channel inhibition and MgADP induces channel opening. Functionally, K(ATP) channels provide a means of linking the electrical activity of a cell to its metabolic state. Shortening of the cardiac action potential, smooth muscle relaxation, inhibition of both insulin secretion, and neurotransmitter release are mediated via K(ATP) channels. Given their many physiological functions, K(ATP) channels represent promising drug targets. Sulfonylureas like glibenclamide block K(ATP) channels; they are used in the therapy of type 2 diabetes. Openers of K(ATP) channels (KCOs), for example, relax smooth muscle and induce hypotension. KCOs are chemically heterogeneous and include as different classes as the benzopyrans, cyanoguanidines, thioformamides, thiadiazines, and pyridyl nitrates. Examples for new chemical entities more recently developed as KCOs include cyclobutenediones, dihydropyridine related structures, and tertiary carbinols.

Reduction of ST elevation in repeated coronary occlusion model depends on both altered metabolic response and conduction property

The aim of this study was to elucidate the mechanisms of altered electrical response to ischemia in repeated coronary occlusion model. To test its dependence on metabolic response, extracellular K+ concentration (eKC), myocardial pH and PCO2 were simultaneously measured with epicardial ECG during three consecutive 4 min of left anterior descending coronary artery (LAD) occlusion separated by 15 min of reperfusion in canine hearts. ECG changes induced by infusion of high K+-buffer (10 mM) into the coronary arterial bed via carotid artery-LAD bypass (referred to as high K+-challenges: HKC) were also tested prior to (the first HKC), and during each reperfusion period (the second to the fourth HKC). ST elevation was significantly reduced in subsequent occlusions (3.14 +/- 0.48 and 2.98 +/- 0.47 mV in the second and third occlusion, both P<0.05, compared to 4.91 +/- 0.78 mV in the first). This was accompanied by significant attenuation of the changes in eKC, tissue pH and PCO2. ST elevation induced by HKC also significantly reduced after repeated occlusion (4.09 +/- 0.79 mV in the fourth HKC vs. 5.64 +/- 0.68 mV in the first, P<0.05) in spite of the identical changes in eKC during HKC. This progressive decrease in ST changes by HKC was rather consistent with augmented conduction delay (86.4 +/- 7.1% increase in activation time in the fourth vs. 54.3 +/- 3.4% in the first, P<0.01). These findings indicate that repeated ischemia induces altered electrical response to subsequent ischemia based on both attenuated metabolic response and altered conduction property.

Hypoxia-induced preconditioning in adult stimulated cardiomyocytes is mediated by the opening and trafficking of sarcolemmal KATP channels

The opening of sarcolemmal and mitochondrial ATP-sensitive K(+) (KATP) channels in the heart is believed to mediate ischemic preconditioning, a phenomenon whereby brief periods of ischemia/reperfusion protect the heart against myocardial infarction. Here, we have applied digital epifluorescent microscopy, immunoprecipitation and Western blotting, perforated patch clamp electrophysiology, and immunofluorescence/laser confocal microscopy to examine the involvement of KATP channels in cardioprotection afforded by preconditioning. We have shown that adult, stimulated-to-beat, guinea-pig cardiomyocytes survived in sustained hypoxia for approximately 17 min. An episode of 5-min-long hypoxia/5-min-long reoxygenation before sustained hypoxia dramatically increased the duration of cellular survival. Experiments with different antagonists of KATP channels, applied at different times during the experimental protocol, suggested that the opening of sarcolemmal KATP channels at the beginning of sustained hypoxia mediate preconditioning. This conclusion was supported by perforated patch clamp experiments that revealed activation of sarcolemmal KATP channels by preconditioning. Immunoprecipitation and Western blotting as well as immunofluorescence and laser confocal microscopy showed that the preconditioning is associated with the increase in KATP channel proteins in sarcolemma. Inhibition of trafficking of KATP channel subunits prevented preconditioning without affecting sensitivity of cardiomyocytes to hypoxia in the absence of preconditioning. We conclude that the preconditioning is mediated by the activation and trafficking of sarcolemmal KATP channels.

Role of reactive oxygen species in ischemic preconditioning of subcellular organelles in the heart

Ischemic preconditioning (IPC) is an endogenous adaptive mechanism and is manifested by early and delayed phases of cardioprotection. Brief episodes of ischemia-reperfusion during IPC cause some subtle functional and structural alterations in sarcolemma, mitochondria, sarcoplasmic reticulum, myofibrils, glycocalyx, as well as nucleus, which render these subcellular organelles resistant to subsequent sustained ischemia-reperfusion insult. These changes occur in functional groups of various receptors, cation transporters, cation channels, and contractile and other proteins, and may explain the initial effects of IPC. On the other hand, induction of various transcriptional factors occurs to alter gene expression and structural changes in subcellular organelles and may be responsible for the delayed effects of IPC. Reactive oxygen species (ROS), which are formed during the IPC period, may cause these changes directly and indirectly and act as a trigger of IPC-induced cardioprotection. As ROS may be one of the several triggers proposed for IPC, this discussion is focused on the current knowledge of both ROS-dependent and ROS-independent mechanisms of IPC. Furthermore, some events, which are related to functional preservation of subcellular organelles, are described for a better understanding of the IPC phenomenon.

Sublethal simulated ischemia promotes delayed resistance against ischemia via ATP-sensitive (K+) channels in murine myocytes: role of PKC and iNOS

In this study, we examined whether sublethal simulated ischemia (SSI) induces delayed cellular protection in mouse cardiac myocytes, and whether the delayed cellular protection depends on the activation of protein kinase C-epsilon (PKC-epsilon), inducible nitric oxide synthase (iNOS), and ATP-sensitive K(+) (K(ATP)) channels against subsequent sustained simulated ischemia (SI). The following groups of mouse cardiac myocytes were studied: (a) SI: incubation with SI buffer for 1 h; (b) SSI: incubation with SSI buffer for 30 min; (c) SSI + PKC inhibitor, chelerythrine chloride (CCl): SSI and 1 micro M CCl; (d) SSI + iNOS inhibitor, S-methylthiourea (SMT): SSI and 100 nM SMT; (e) SSI + K(ATP) channel blocker, glibenclamide (Glb): SSI and 50 micro M Glb; (f) SSI + mitochondrial K(ATP) channel blocker, 5-hydroxydecanoate (5-HD): SSI and 50 micro M 5-HD. The release of lactate dehydrogenase into the medium and the amount remaining in the cells was measured, and A(1) adenosine receptor, PKC-epsilon, and iNOS were detected through western blot analysis. The delayed cellular protection acquired due to SSI showed a decreased release of lactate dehydrogenase (%) from 46.51 +/- 1.60 to 37.00 +/- 1.34 (p < 0.001) and was blocked by CCl (47.08 +/- 0.95), SMT (48.08 +/- 1.18), Glb (45.88 +/- 1.31), and 5-HD (47.20 +/- 1.56). Simultaneously, SSI-induced up-regulation of A(1) adenosine receptor, PKC-epsilon, iNOS, and opening of both membrane and mitochondrial K(ATP) channels also was observed compared with controls.

Thioredoxin regulation of ischemic preconditioning

Thioredoxins are a class of small redox-regulating proteins that appear to play a crucial role in many oxidative stress-inducible degenerative diseases. A recent study demonstrated a reduction of thioredoxin-1 (Trx1) protein in the ischemic reperfused myocardium. When the same heart was adapted to ischemic stress by preconditioning with repeated cyclic episodes of small duration of ischemia and reperfusion, there was an increased induction of Trx1 expression. Inhibition of Trx1 expression resulted in reduced postischemic ventricular recovery and increased myocardial infarct size in the preconditioned heart. Corroborating these findings, transgenic mouse hearts overexpressing Trx1 were resistant to ischemic reperfusion injury as compared with the hearts from wild-type mice. Thus, it appears that thioredoxin plays a crucial role in cardioprotection induced by preconditioning.

Cardioprotection by glucose-insulin-potassium: dependence on KATP channel opening and blood glucose concentration before ischemia

We tested the hypothesis that glucose-insulin-potassium (GIK)-induced protection against myocardial infarction depends on ATP-dependent K(+) (K(ATP)) channel activation and is abolished by hyperglycemia before the ischemia. Dogs were subjected to a 60-min coronary artery occlusion and 3-h reperfusion in the absence or presence of GIK (25% dextrose; 50 IU insulin/l; 80 mM/l KCl infused at 1.5 ml x kg(-1) x h(-1)) beginning 75 min before coronary artery occlusion or 5 min before reperfusion. The role of K(ATP) channels was evaluated by pretreatment with glyburide (0.1 mg/kg). The efficacy of GIK was investigated with increases in blood glucose (BG) concentrations to 300 or 600 mg/dl or experimental diabetes (alloxan/streptozotocin). Infarct size (IS) was 29 +/- 2% of the area at risk in control experiments. GIK decreased (P < 0.05) IS when administered beginning 5 min before reperfusion. This protective action was independent of BG (13 +/- 2 and 12 +/- 2% of area at risk; BG = 80 or 600 mg/dl, respectively) but was abolished in dogs receiving glyburide (30 +/- 4%), hyperglycemia before ischemia (27 +/- 4%), or diabetes (25 +/- 3%). IS was unchanged by GIK when administered before ischemia independent of BG (31 +/- 3, 27 +/- 2, and 35 +/- 3%; BG = 80, 300, and 600 mg/dl, respectively). The insulin component of GIK promotes cardioprotection by K(ATP) channel activation. However, glucose decreases K(ATP) channel activity, and this effect predominates when hyperglycemia is present before ischemia.

SUR2A C-terminal fragments reduce KATP currents and ischaemic tolerance of rat cardiac myocytes

C-terminal fragments of the sulphonylurea receptor SUR2A can alter the functional expression of cloned ATP-sensitive K(+) channels (K(ATP)). To investigate the protective role of K(ATP) channels during metabolic stress we transfected SUR2A fragments into adult rat cardiac myocytes. A fragment comprising residues 1294-1358, the A-fragment, reduced sarcolemmal K(ATP) currents by over 85% after 2 days (pinacidil-activated current densities were: vector alone 7.04 +/- 1.22; and A-fragment 0.94 +/- 0.07 pA pF(-1), n= 6,6, P < 0.001). An inactive fragment (1358-1545, current density 6.30 +/- 0.85 pA pF(-1), n= 6) was used as a control. During metabolic inhibition (CN and iodoacetate) of isolated myocytes stimulated at 1 Hz, the A-fragment delayed action potential shortening and contractile failure, but accelerated rigor contraction and increased Ca(2+) loading. On reperfusion, A-fragment-transfected cells also showed increased intracellular Ca(2+) and the proportion of cells recovering contractile function was reduced from 40.0 to 9.5% (P < 0.01). The protective effect of pretreatment with 2,4-dinitrophenol, measured from increased functional recovery and reduced Ca(2+) loading, was abolished by the A-fragment. Our data are consistent with a role for K(ATP) channels in causing action potential failure and reduced Ca(2+) loading during metabolic stress, and with a major role in protection by preconditioning. The effects of the A-fragment may arise entirely from reduced expression of the sarcolemmal K(ATP) channel, but we also discuss the possibility of mitochondrial effects.

Simvastatin-induced myocardial protection against ischemia–reperfusion injury is mediated by activation of ATP-sensitive K+ channels

OBJECTIVES

Previous studies have suggested that the 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors attenuate ischemia-reperfusion injury. We investigated whether pretreatment with simvastatin reduces myocardial infarct size and whether glyburide, a non-selective inhibitor of the ATP-sensitive K channels, abrogates this infarct size-limiting effect.

METHODS

Sprague-Dawley rats were treated with either simvastatin (20 mg/kg per day) or saline alone for 3 days. Additional groups of rats were treated as above and on the fourth day they received intravenous glyburide (0.3 mg/kg). All rats underwent 30 min of coronary artery occlusion followed by 180 min of reperfusion. Ischemic myocardium at risk was assessed with blue dye and infarct size with triphenyltetrazolium chloride.

RESULTS

Infarct size, expressed as a percentage of the myocardium at risk, was significantly smaller in the simvastatin group (n = 8, 20.8 +/- 3.4%) than in the placebo group (n = 6, 40.1 +/- 2.7%) (P = 0.001). Glyburide abolished the protective effect of simvastatin with infarct size being 34.2 +/- 6.9% and 29.7 +/- 3.9% of the area at risk in the simvastatin group (n = 7) and placebo (n = 7) group, respectively (P = 0.58).

CONCLUSIONS

Simvastatin significantly reduced myocardial infarct size. The protective effect was completely abrogated by glyburide, strongly suggesting that this protective effect is mediated via activation of the ATP-sensitive K channels.

Cardioprotection of Interleukin-2 Is Mediated via κ-Opioid Receptors

We examined whether interleukin-2 (IL-2) protects the myocardium against injury induced by ischemia and reperfusion via the kappa-opioid receptor (OR). The cardioprotective effect of IL-2 was evaluated by measuring infarct size and lactate dehydrogenase (LDH) release in response to ischemia and reperfusion in the isolated rat heart. IL-2 at an optimal dose of 50 U/ml mimicked the effect of ischemic preconditioning by reducing infarct size and LDH release. The infarct and LDH-reducing effects of IL-2 were blocked by nor-binaltorphimine (5 microM), a kappa-OR antagonist, but not naltrindole (5 microM), a delta-OR antagonist known to block the action of its stimulation. Moreover, blockade of the mitochondrial ATP-sensitive potassium (mito-K(ATP)) channel with a selective antagonist, 5-hydroxydecanoate (100 microM), or a nonselective antagonist of K(ATP) channels, glybenclamide (100 microM), or blockade of protein kinase C (PKC) with its inhibitors chelerythrine (5 microM) or GF 109203X (10 microM) [3-[1-[3-(dimethylaminopropyl]-1H-indol-3-yl]-4-(1H-indol-3-yl)-1H-pyrrole-2,5-dione monohydrochloride] abolished the protective effect of IL-2. Administration of free radical scavengers N-acetylcysteine (4 mM) or N-(2-mercaptopropionyl)-glycine (1 mM) also abolished the protective effects of IL-2 and U50,488H [(trans)-3,4-dichloro-N-methyl-N-[2-(1-pyrrolidinyl)-cyclohexyl]benzeneacetamide], a selective kappa-OR agonist. This study provides the first evidence that IL-2 confers cardioprotection against injury induced by ischemia/reperfusion. The effect of IL-2 is mediated via kappa-OR as evidenced by kappa-OR antagonism and similar signaling mechanisms, mito-K(ATP), PKC, and reactive oxygen species involved in the cardioprotective effects of both IL-2 and kappa-OR stimulation.

Bradykinin induces mitochondrial ROS generation via NO, cGMP, PKG, and mitoKATP channel opening and leads to cardioprotection

Bradykinin (BK) mimics ischemic preconditioning by generating reactive oxygen species (ROS). To identify intermediate steps that lead to ROS generation, rabbit cardiomyocytes were incubated in reduced MitoTracker Red stain, which becomes fluorescent after exposure to ROS. Fluorescence intensity in treated cells was expressed as a percentage of that in paired, untreated cells. BK (500 nM) caused a 51 +/- 16% increase in ROS generation (P < 0.001). Coincubation with either the BK B2-receptor blocker HOE-140 (5 microM) or the free radical scavenger N-(2-mercaptopropionyl)glycine (1 mM) prevented this increase, which confirms that the response was receptor mediated and ROS were actually being measured. Closing mitochondrial ATP-sensitive K+ (mitoKATP) channels with 5-hydroxydecanoate (5-HD, 1 mM) prevented increased ROS generation. BK-induced ROS generation was blocked by Nomega-nitro-m-arginine methyl ester (m-NAME, 200 microM), which implicates nitric oxide as an intermediate. Blockade of guanylyl cyclase with 1-H-[1,2,4]oxadiazole[4,3-a]quinoxalin-1-one (ODQ, 10 microM) aborted BK-induced ROS generation but not that from diazoxide, a direct opener of mitoKATP channels. The protein kinase G (PKG) blocker 8-bromoguanosine-3',5'-cyclic monophosphorothioate (25 microM) eliminated the effects of BK. Conversely, direct activation of PKG with 8-(4-chlorophenylthio)-guanosine-3',5'-cyclic monophosphate (100 microM) increased ROS generation (39 +/- 15%; P < 0.004) similar to BK. This increase was blocked by 5-HD. Finally, the nitric oxide donor S-nitroso-N-acetylpenicillamine (1 microM) increased ROS by 34 +/- 6%. This increase was also blocked by 5-HD. In intact rabbit hearts, BK (400 nM) decreased infarction from 30.5 +/- 3.0 of the risk zone in control hearts to 11.9 +/- 1.4% (P < 0.01). This protection was aborted by either 200 microM m-NAME or 2 microM ODQ (35.4 +/- 5.7 and 30.4 +/- 3.0% infarction, respectively; P = not significant vs. control). Hence, BK preconditions through receptor-mediated production of nitric oxide, which activates guanylyl cyclase. The resulting cGMP activates PKG, which opens mitoKATP. Subsequent release of ROS triggers cardioprotection.

Is impairment of ischaemic preconditioning by sulfonylurea drugs clinically important?

In the UGDP study, published in the 1970s, a high incidence of cardiovascular mortality was found in patients treated with the sulfonylurea agent tolbutamide. Impaired ischaemic preconditioning is presumed to be the most important mechanism for the excess cardiovascular mortality observed. However, as tolbutamide has only a low affinity for cardiac sulfonylurea receptors, interference with ischaemic preconditioning seems unlikely to account for this excess mortality. Several smaller studies also failed to establish a definite link between sulfonylurea treatment before acute myocardial infarction and in-hospital mortality. However, when the myocardium becomes exposed to repeated or prolonged periods of ischaemia, ischaemic preconditioning may become clinically important. Myocardial ischaemia can also develop during emergency or elective angioplasty and during coronary bypass surgery. Therefore discontinuation of sulfonylurea treatment should be considered in these circumstances.

Diazoxide provides protection to human myocardium in vitro that is concentration dependent

BACKGROUND

Diazoxide has been shown to confer significant myocardial protection in many experiments. This study was designed to assess its influence on the structural injury and functional recovery of human myocardium subjected to hypoxia/reoxygenation in vitro.

METHODS

The isolated electrically driven human right atrial trabeculae, obtained during cardiac surgery, were studied. The tissue bath was oxygenated with 95% oxygen and 5% carbon dioxide, hypoxia being obtained by replacing oxygen with argon. The influence of diazoxide on atrial contractility was studied first. Next, the two trabeculae from one atrial appendage were studied simultaneously, adding diazoxide to the tissue bath 10 minutes before hypoxia in one, with another serving as a control. We tested 10(-4.5) mol/L and 10(-4) mol/L diazoxide in three sets of experiments testing 30, 60, and 90 minutes of hypoxia. We continued reoxygenation for 120 minutes (in 60-minute and 90-minute hypoxia experiments) and subsequently tested reaction to 10(-4) mol/L norepinephrine. Apart from continuous recording of the contraction force, we measured the troponin I release into the tissue bath after ischemia and reoxygenation.

RESULTS

Diazoxide exerted a negative inotropic effect in human atrial muscle (pD(2)=3.96 +/- 0.18). Both concentrations of diazoxide studied resulted in better functional recovery of atrial trabeculae subjected to 30 minutes of hypoxia. With longer hypoxia, only the higher diazoxide concentration provided significant protection as assessed by contractility. After 120 minutes of reoxygenation, only diazoxide-treated muscle was viable enough to respond to norepinephrine. Only 10(-4) mol/L diazoxide resulted in lower troponin I release during hypoxia and reoxygenation.

CONCLUSIONS

This study shows that diazoxide provides significant concentration-dependent protection against hypoxia/reoxygenation injury to human myocardium in vitro.

CGX-1051, A Peptide from Conus Snail Venom, Attenuates Infarction in Rabbit Hearts When Administered at Reperfusion

CGX-1051, isolated from the venom of the marine snail Conus purpurasens, was previously noted to interact with potassium channels. Since potassium channels play an important role in cardiac physiology, we assessed the effect of CGX-1051 on infarct size in a rabbit heart model of ischemia/reperfusion. A coronary branch was occluded for 30 minutes followed by 3 hours of reperfusion in in situ and 2 hours in in vitro preparations. Infarct size was measured with triphenyltetrazolium chloride staining and expressed as a percent of the risk zone. In in situ studies, a bolus intravenous injection of CGX-1051, either 10 or 100 microg/kg, administered 5 minutes before reperfusion, reduced infarct size from 40.4 +/- 2.8% of the risk zone in untreated animals to 19.8 +/- 3.8% and 15.0 +/- 1.9%, respectively. One microg/kg CGX-1051 was not protective. To see if the salvage was sustained, two groups of rabbits underwent 72 hours of reperfusion. The dose of 10 microg/kg infused 5 minutes before reperfusion reduced infarct size from 37.0 +/- 1.6% in untreated rabbits to 15.5 +/- 2.0%. When administered 10 minutes after reperfusion had begun, 100 microg/kg CGX-1051 had no effect. CGX-1051 also reduced infarct size in crystalloid-perfused, isolated rabbit hearts suggesting that protection did not depend on circulating leukocytes. The mitochondrial KATP inhibitors glibenclamide and 5-hydroxydecanoate and the MEK(1/2), ERK and hence, inhibitor PD 98059 aborted protection from CGX-1051. These data indicate that functionally active ERK and mitochondrial KATP channels are necessary for protection. CGX-1051 caused no hemodynamic alterations at any dose tested. We conclude that CGX-1051 has a powerful anti-infarct effect when given just before reperfusion.

ATP-sensitive K+ channels in renal mitochondria

Isolated kidney mitochondria swell when incubated in hyposmotic solutions containing K+ salts in a manner inhibited by ATP, ADP, 5-hydroxydecanoate, and glibenclamide and stimulated by GTP and diazoxide. These results suggest the existence of ATP-sensitive K+ channels in these mitochondria, similar to those previously described in heart, liver, and brain. Renal mitochondrial ATP-sensitive K+ uptake rates are approximately 140 nmol.min-1.mg protein-1. This K+ transport results in a slight increase in respiration and decrease in the inner membrane potential. In addition, the activation of ATP-inhibited K+ uptake using diazoxide leads to a decrease of ATP hydrolysis through the reverse activity of the F0F1 ATP synthase when respiration is inhibited. In conclusion, we characterize an ATP-sensitive K+ transport pathway in kidney mitochondria that affects volume, respiration, and membrane potential and may have a role in the prevention of mitochondrial ATP hydrolysis.

Molecular assembly and subcellular distribution of ATP-sensitive potassium channel proteins in rat hearts

Cardiac ATP-sensitive K(+) (K(ATP)) channels are proposed to contribute to cardio-protection and ischemic preconditioning. Although mRNAs for all subunits of K(ATP) channels (Kir6.0 and sulfonylurea receptors SURs) were detected in hearts, subcellular localization of their proteins and the subunit combination are not well elucidated. We address these questions in rat hearts, using anti-peptide antibodies raised against each subunit. By immunoblot analysis, all of the subunits were detected in microsomal fractions including sarcolemmal membranes, while they were not detected in mitochondrial fractions at all. Immunoprecipitation and sucrose gradient sedimentation of the digitonin-solubilized microsomes indicated that Kir6.2 exclusively assembled with SUR2A. The molecular mass of the Kir6.2-SUR2A complex estimated by sucrose sedimentation was 1150 kDa, significantly larger than the calculated value for (Kir6.2)(4)-(SUR2A)(4), suggesting a potential formation of micellar complex with digitonin but no indication of hybrid channel formation under the conditions. These findings provide additional information on the structural and functional relationships of cardiac K(ATP) channel proteins involving subcellular localization and roles for cardioprotection and ischemic preconditioning.

Mitochondrial potassium transport: the role of the mitochondrial ATP-sensitive K(+) channel in cardiac function and cardioprotection

Coronary artery disease and its sequelae-ischemia, myocardial infarction, and heart failure-are leading causes of morbidity and mortality in man. Considerable effort has been devoted toward improving functional recovery and reducing the extent of infarction after ischemic episodes. As a step in this direction, it was found that the heart was significantly protected against ischemia-reperfusion injury if it was first preconditioned by brief ischemia or by administering a potassium channel opener. Both of these preconditioning strategies were found to require opening of a K(ATP) channel, and in 1997 we showed that this pivotal role was mediated by the mitochondrial ATP-sensitive K(+) channel (mitoK(ATP)). This paper will review the evidence showing that opening mitoK(ATP) is cardioprotective against ischemia-reperfusion injury and, moreover, that mitoK(ATP) plays this role during all three phases of the natural history of ischemia-reperfusion injury preconditioning, ischemia, and reperfusion. We discuss two distinct mechanisms by which mitoK(ATP) opening protects the heart-increased mitochondrial production of reactive oxygen species (ROS) during the preconditioning phase and regulation of intermembrane space (IMS) volume during the ischemic and reperfusion phases. It is likely that cardioprotection by ischemic preconditioning (IPC) and K(ATP) channel openers (KCOs) arises from utilization of normal physiological processes. Accordingly, we summarize the results of new studies that focus on the role of mitoK(ATP) in normal cardiomyocyte physiology. Here, we observe the same two mechanisms at work. In low-energy states, mitoK(ATP) opening triggers increased mitochondrial ROS production, thereby amplifying a cell signaling pathway leading to gene transcription and cell growth. In high-energy states, mitoK(ATP) opening prevents the matrix contraction that would otherwise occur during high rates of electron transport. MitoK(ATP)-mediated volume regulation, in turn, prevents disruption of the structure-function of the IMS and facilitates efficient energy transfers between mitochondria and myofibrillar ATPases.

Preconditioning protects the guinea-pig urinary bladder against ischaemic conditions in vitro

AIMS

To investigate the ability of ischaemic preconditioning (IPC) to protect guinea-pig detrusor from damage caused by a subsequent more prolonged exposure to ischaemic conditions.

MATERIALS AND METHODS

Smooth muscle strips were mounted for tension recording in small organ baths continuously superfused with Krebs' solution at 37 degrees C. Ischaemia was mimicked by removing oxygen and glucose from the superfusing solution. Contractile responses to electrical field stimulation (EFS) and carbachol were monitored. Three regimes of preconditioning were examined: 15, 10, and 5 min of ischaemic conditions followed by 15, 10, and 5 min of normal conditions, respectively.

RESULTS

Without preconditioning, nerve-mediated responses were significantly and proportionally reduced by periods of ischaemic conditions lasting for 45, 60, and 90 min, but recovered fully after exposure to ischaemic conditions for 30 min. The recovery of the responses to EFS was significantly improved in preconditioned strips when the period of ischaemic conditions was 45 or 60 min. However, no significant differences were seen with preconditioning when the period of ischaemic conditions was 90 min. The recovery of responses to carbachol was much greater than for the responses to EFS, and no significant differences were found between control and preconditioned strips.

CONCLUSIONS

It is suggested that in vivo short periods of transient ischaemia may be able to protect the guinea-pig bladder from the impairment associated with longer periods of ischaemia and reperfusion, which might happen in obstructed micturition. Our results also indicate that the phenomenon affects mainly the intrinsic nerves, which are more susceptible to ischaemic damage than the smooth muscle.

Sodium-hydrogen exchanger inhibition, pharmacologic ischemic preconditioning, or both for extended cardiac allograft preservation

BACKGROUND

The aim of this study was to determine the efficacy of cariporide (a sodium-hydrogen exchanger inhibitor), BMS180448 (a pharmacologic ischemic preconditioning agent), and the combination thereof, as adjuvant therapies for extended cardiac allograft preservation.

METHODS

A porcine model of donor brain death and orthotopic heart transplantation was used. All hearts were arrested and stored for 14 hr in an extracellular preservation solution. Control hearts (CON; n=3) did not receive any additional treatment. Treated hearts received BMS180448 alone (BMS; n=3), cariporide alone (CAR; n=6), or both BMS180448 and cariporide (B+C; n=6). Donors of BMS180448-treated hearts received 2 mg/kg, 15 min before explantation. Donors and recipients of cariporide-treated hearts received 2 mg/kg, 15 min before explantation and reperfusion, respectively.

RESULTS

The CON and BMS arms of the study were terminated after three transplantations because initial results in these groups were poor. Significantly, none of the control hearts could be weaned successfully from bypass, whereas all of the treated hearts were weaned successfully (CAR vs. CON and B+C vs. CON: P=0.012). The rate of troponin I release during the first 3 hr after reperfusion was significantly lower in CAR (P=0.0180) and B+C (P=0.0154) recipients than in CON recipients. Mean plasma troponin I levels (microg/mL) 3 hr after reperfusion were as follows: CON 633+/-177, BMS 576+/-110, CAR 346+/-93, and B+C 296+/-97.

CONCLUSION

In this porcine model of extended cardiac allograft preservation, cariporide was more effective than BMS180448 as an adjuvant to our usual preservation solution. There was no additional benefit from the combination of the two therapies.

Preconditioning the Myocardium: From Cellular Physiology to Clinical Cardiology

Yellon, Derek M., and James M. Downey. Preconditioning the Myocardium: From Cellular Physiology to Clinical Cardiology. Physiol Rev 83: 1113-1151, 2003; 10.1152/physrev.00009.2003.—The phenomenon of ischemic preconditioning, in which a period of sublethal ischemia can profoundly protect the cell from infarction during a subsequent ischemic insult, has been responsible for an enormous amount of research over the last 15 years. Ischemic preconditioning is associated with two forms of protection: a classical form lasting ∼2 h after the preconditioning ischemia followed a day later by a second window of protection lasting ∼3 days. Both types of preconditioning share similarities in that the preconditioning ischemia provokes the release of several autacoids that trigger protection by occupying cell surface receptors. Receptor occupancy activates complex signaling cascades which during the lethal ischemia converge on one or more end-effectors to mediate the protection. The end-effectors so far have eluded identification, although a number have been proposed. A range of different pharmacological agents that activate the signaling cascades at the various levels can mimic ischemic preconditioning leading to the hope that specific therapeutic agents can be designed to exploit the profound protection seen with ischemic preconditioning. This review examines, in detail, the complex mechanisms associated with both forms of preconditioning as well as discusses the possibility to exploit this phenomenon in the clinical setting. As our understanding of the mechanisms associated with preconditioning are unravelled, we believe we can look forward to the development of new therapeutic agents with novel mechanisms of action that can supplement current treatment options for patients threatened with acute myocardial infarction.

KATP channels and myocardial preconditioning: an update

Ischemic or myocardial preconditioning (IPC) is a phenomenon whereby brief periods of ischemia have been shown to protect the myocardium against a more sustained ischemic insult. The result of IPC may be manifest as a marked reduction in infarct size, myocardial stunning, or incidence of cardiac arrhythmias. Whereas many endogenous neurotransmitters, peptides, and hormones have been proposed to play a role in the signal transduction pathways mediating the cardioprotective effect of IPC, nearly universal evidence indicates the involvement of the ATP-sensitive potassium (KATP) channel. Initial evidence suggested that the surface or sarcolemmal KATP (sarcKATP) channel triggered or mediated the cardioprotective effects of IPC; however, more recent findings have suggested a major role for a mitochondrial site or possibly a mitochondrial KATP channel (mitoKATP). This review presents evidence that supports a role for these two channels as a trigger and/or downstream mediator in the phenomenon of IPC or pharmacologically induced PC as well as recent evidence that suggests the involvement of a mitochondrial calcium-activated potassium (mitoKca) channel or the electron transport chain in mediating the beneficial effects of IPC or pharmacologically induced PC.

Chemical preconditioning prevents paradoxical increase in glutamate release during ischemia by activating ATP-dependent potassium channels in gerbil hippocampus

Ischemic tolerance induced by pretreatment with a low dose of 3-nitropropionic acid (3-NPA), called chemical preconditioning, prolongs the delay to hypoxic depolarization and improves the recovery of synaptic transmission (Exp. Neurol. 166 (2000), 385-391). We studied the effect of chemical preconditioning on the presynaptic site by analyzing spontaneous excitatory postsynaptic currents (sEPSCs) and miniature EPSCs (mEPSCs) with a whole cell patch-clamp technique in gerbil hippocampal slices. The frequency of sEPSCs decreased first and then dramatically increased during ischemia (10 min in duration, low pO(2), and deprivation of glucose) up to 200-300%. This increase was apparently a paradox, since synaptic transmission evoked by electrical stimulation diminished when the sEPSC frequency started to increase. The frequency of mEPSCs also increased in the same time course. Increases in sEPSC and mEPSC frequencies were prevented by chemical preconditioning with 3-NPA (4 mg/kg) administered intraperitoneally 3 h before the preparation of brain slices. These effects of chemical preconditioning were abolished by glibenclamide (5 microM), a blocker of ATP-dependent potassium (K(ATP)) channels, applied in vitro before the ischemic insult. The application of diazoxide (500 microM), an opener of K(ATP) channels, produced the same preventive effects on sEPSC and mEPSC frequencies. These results suggested that chemical preconditioning acted on presynaptic terminals to prevent the paradoxical increase in glutamate release during ischemia through the activation of K(ATP) channels.

[Molecular and functional diversity of ATP-sensitive K+ channels: the pathophysiological roles and potential drug targets]

ATP-sensitive K(+) (K(ATP)) channels comprise the pore-forming subunit (Kir6.1 or Kir6.2) and the regulatory subunit sulfonylurea receptors (SUR1 or SUR2). K(ATP) channels with different combinations of these subunits are present in various tissues and regulate cellular functions. From the analysis of mouse models with targeted deletion of the gene encoding the pore-forming subunit Kir6.1 or Kir6.2, functional roles of K(ATP) channels in various organs have been clarified. Kir6.1(-/-) mice showed sudden death associated with ST elevation and atrioventricular block in ECG, a phenotype resembling Prinzmetal angina in humans. Kir6.2(-/-) mice were more susceptible to generalized seizure during hypoxia than wild-type (WT) mice, suggesting that neuronal K(ATP) channels, probably composed of Kir6.2 and SUR1, play a crucial role for the protection of the brain against lethal damage due to seizure. In Kir6.2(-/-) mice lacking the sarcolemmal K(ATP) channel activity in cardiac cells, ischemic preconditioning failed to reduce the infarct size, suggesting that sarcolemmal K(ATP) channels play an important role in cardioprotection against ischemia/reperfusion injuries in the heart. Mitochondrial K(ATP) channels have been also proposed to play a crucial role in cardioprotection, although the molecular identity of the channel has not been established. Nicorandil and minoxidil, K(+) channel openers activating mitochondrial K(ATP) channels, decreased the mitochondrial membrane potential, thereby preventing the Ca(2+) overload in the mitochondria of guinea-pig ventricular cells. SURs are the receptors for K(+) channel openers and the activating effects on sarcolemmal K(ATP) channels in cardiovascular tissues could be modulated by the interaction of nucleotides. Due to the molecular diversity of the accessory and pore subunits of K(ATP) channels, there would be considerable differences in the tissue selectivity of K(ATP) channel-acting drugs. Studies of Kir6.1 and Kir6.2 knockout mice indicate that K(ATP) channels are involved in the mechanisms of the protection against metabolic stress. Further clarification of physiological as well as pathophysiological roles of K(ATP) channels may lead to a new therapeutic strategy to improve the quality of life.

A3 adenosine receptor agonist IB-MECA reduces myocardial ischemia-reperfusion injury in dogs

We examined the effect of the A3 adenosine receptor (AR) agonist IB-MECA on infarct size in an open-chest anesthetized dog model of myocardial ischemia-reperfusion injury. Dogs were subjected to 60 min of left anterior descending (LAD) coronary artery occlusion and 3 h of reperfusion. Infarct size and regional myocardial blood flow were assessed by macrohistochemical staining with triphenyltetrazolium chloride and radioactive microspheres, respectively. Four experimental groups were studied: vehicle control (50% DMSO in normal saline), IB-MECA (100 microg/kg iv bolus) given 10 min before the coronary occlusion, IB-MECA (100 microg/kg iv bolus) given 5 min before initiation of reperfusion, and IB-MECA (100 microg/kg iv bolus) given 10 min before coronary occlusion in dogs pretreated 15 min earlier with the ATP-dependent potassium channel antagonist glibenclamide (0.3 mg/kg iv bolus). Administration of IB-MECA had no effect on any hemodynamic parameter measured including heart rate, first derivative of left ventricular pressure, aortic pressure, LAD coronary blood flow, or coronary collateral blood flow. Nevertheless, pretreatment with IB-MECA before coronary occlusion produced a marked reduction in infarct size ( approximately 40% reduction) compared with the control group (13.0 +/- 3.2% vs. 25.2 +/- 3.7% of the area at risk, respectively). This effect of IB-MECA was blocked completely in dogs pretreated with glibenclamide. An equivalent reduction in infarct size was observed when IB-MECA was administered immediately before reperfusion (13.1 +/- 3.9%). These results are the first to demonstrate efficacy of an A3AR agonist in a large animal model of myocardial infarction by mechanisms that are unrelated to changes in hemodynamic parameters and coronary blood flow. These data also demonstrate in an in vivo model that IB-MECA is effective as a cardioprotective agent when administered at the time of reperfusion.

Ischemic heart disease in type 2 diabetes

Type 2 diabetes has reached epidemic proportions and an increasing proportion of patients with coronary artery disease (CAD) are diabetics. CAD in diabetics has specificities and, in particular, more extensive atherosclerosis; diabetic patients are also more frequently asymptomatic, with silent myocardial ischemia, which makes the diagnosis of CAD more difficult. In addition, diabetic patients with CAD have poorer outcomes than nondiabetics. The management of diabetic patients with CAD is based on intensive intervention on lifestyle and risk factors, together with the mandatory use of medications of proven benefit as regards secondary prevention in coronary patients: antiplatelet agents, statins, beta-blockers, and angiotensin-converting enzyme (ACE) inhibitors. Glycemic control is also essential; although the use of sulfonylureas has been controversial, there is now a vast amount of data suggesting a beneficial effect, in particular when agents more specific for the pancreatic adenosine triphosphate-dependent potassium (K(ATP)) channels are used. At the acute stage of myocardial infarction, the Diabetes mellitus, Insulin Glucose infusion in Acute Myocardial Infarction (DIGAMI) trial suggested a beneficial effect of insulin therapy prolonged for 3 months after hospital discharge; these data will have to be confirmed by larger intervention trials. Finally, the respective roles of coronary angioplasty and coronary surgery in diabetics are debated; a post hoc analysis of the Bypass Angioplasty Revascularization Investigation (BARI) trial data showed increased mortality in diabetics with multivessel CAD treated with angioplasty compared with surgery, but the results of the more recent trials using intracoronary stents appear more balanced; in this regard, the effects of drug-eluting stents, which dramatically decrease the incidence of re-stenosis, seem promising.

Late ischemic preconditioning of the myocardium alters the expression of genes involved in inflammatory response

Myocardial ischemic preconditioning (IPC) is a potent endogenous mechanism of cardioprotection against ischemia-reperfusion injury. In this study we focused on the second phase of IPC as the most interesting in terms of therapeutic implementations. We aimed at the detection of genes, which are differentially expressed at 16 h after reperfusion. Preconditioning of canine myocardium was initiated by 5 min occlusion of the left anterior descending coronary artery with subsequent reperfusion. cDNA representational difference analysis in combination with microarray hybridization and reverse transcription polymerase chain reaction were used to reveal the changes in gene expression in canine hearts. We found that functionally related genes for tristetraproline (TTP), selectin E, matrix metalloproteinase 9, and tumor necrosis factor-alpha were highly upregulated at the late phase of IPC. The upregulation of TTP gene at the late phase of IPC, reported here for the first time, may represent a cardioprotective mechanism, which could be a promising perspective in clinical interventions against ischemia-reperfusion injuries of the heart.

Cardioprotection with pioglitazone is abolished by nitric oxide synthase inhibitor in ischemic rabbit hearts--comparison of the effects of pioglitazone and metformin

BACKGROUND

The effects of two drugs representing different classes of antidiabetic pharmacology (pioglitazone, a thiazolidinedione; and metformin, a biguanide) on the myocardial metabolism in the ischemia are poorly understood.

METHODS

To test the hypothesis that cardioprotection of pioglitazone and metformin is associated with nitric oxide (NO), we studied the high energy phosphate metabolism by 31P-nuclear magnetic resonance (NMR) in isolated rabbit hearts. Forty-five minutes of continuous normothermic global ischemia was carried out. Pioglitazone or metformin was administered at the beginning, 60 min prior to the global ischemia, with or without the nitric oxide synthase inhibitor, L-NAME, administered 5 min or 60 min prior to the ischemia. In the first experiment, whether NO was produced or not by administration of pioglitazone, for the prevention of myocardial ischemic injury, was investigated. Hearts of male Japanese white rabbits were divided into 4 experimental groups: the control (C) group, the P group consisting of pioglitazone treatment, the P + L5 group consisting of pioglitazone treatment with L-NAME (5 min before ischemia), and the P + L60 group consisting of pioglitazone treatment with L-NAME (60 min before ischemia). In the next experiment, a comparison between the effects of pioglitazone and metformin in preventing ischemic injury were studied. The hearts were divided into 4 experimental groups: the control (C) group, the P group consisting of pioglitazone treatment, the P + L5 group consisting of pioglitazone treatment with L-NAME (5 min before ischemia), the M group consisting of metformin treatment, and the M + L5 group consisting of metformin treatment with L-NAME (5 min before ischemia).

RESULTS

In the first experiment, the decrease in adenosine triphosphate (ATP) during ischemia was significantly inhibited in the P group in comparison with the C group (P < 0.01). However, the decrease in ATP was not inhibited in the P + L5 group during ischemia. In contrast, in the P + L60 group, the decrease in ATP was not inhibited during a part of ischemia. In the next experiment, a comparison between the effects of pioglitazone and metformin in preventing ischemic injury was studied. As a result of administration of either pioglitazone or metformin, there was no difference between groups with and without L-NAME.

CONCLUSION

These results suggest that pioglitazone has a significant beneficial effect on improving the myocardial energy metabolism during ischemia. This cardioprotection may be dependent on nitric oxide (NO) synthase during ischemia more than preischemia. Furthermore, the present findings suggest that both pioglitazone and metformin have equal cardioprotective effects mediated by NO on myocardial ischemic injury in rabbits.

Hibernation, Stunning, and Preconditioning: Historical Perspective, Current Concepts, Clinical Applications, and Future Implications

Despite considerable advances, coronary artery disease is the leading cause of morbidity and mortality in the Western world. The development of effective therapeutic strategies for protecting the myocardium from ischemia would have major impact on patients with coronary artery disease. It is now accepted that patients with coronary artery disease can experience prolonged regional ischemic dysfunction that does not necessarily arise from irreversible tissue damage, and to some extent, can be reversed by restoration of blood flow. The initial stages of dysfunction are probably caused by chronic stunning that can be reversed after revascularization, resulting in rapid and complete functional recovery. On the other hand, the more advanced stages of dysfunction likely correspond to chronic hibernation. After revascularization, functional recovery will probably be quite delayed and mostly incomplete. Over the past decade, the possibility that an innate mechanism of myocardial protection might be inducible in the human heart has generated considerable excitement. In the last two decades, there was phenomenal growth in the understanding of the mechanism known as ischemic preconditioning that is responsible for the innate myocardial protection. Continued research and progress in this area may soon lead to the availability of preconditioning-mimetic treatments. The current concepts, mechanisms, and potential clinical applications of myocardial hibernation, stunning, and ischemic preconditioning are reviewed.

Hypothermic preconditioning induces rapid tolerance to focal ischemic injury in the rat

Stressful, preconditioning stimuli can elicit rapid and delayed forms of tolerance to ischemic injury. The identification and characterization of preconditioning stimuli that are effective, but relatively benign, could enhance the clinical applicability of induced tolerance. This study examines the efficacy of brief hypothermia as a preconditioning stimulus for inducing rapid tolerance. Rats were administered hypothermic preconditioning or sham preconditioning and after an interval of 20-120 min were subjected to transient focal ischemia using a three-vessel occlusion model. The volume of cerebral infarction was measured 24 h or 7 days after ischemia. In other experiments, the depth or duration of the hypothermic stimulus was manipulated, or a protein synthesis inhibitor (anisomycin) was administered. Twenty minutes of hypothermia delivered 20 or 60 (but not 120) min prior to ischemia significantly reduces cerebral infarction. The magnitude of protection is enhanced with deeper levels of hypothermia, but is not affected by increasing the duration of the hypothermic stimulus. Treatment with a protein synthesis inhibitor does not block the induction of rapid tolerance. Hypothermic preconditioning elicits a rapid form of tolerance to focal ischemic injury. Unlike delayed tolerance induced by hypothermia, rapid tolerance is not dependent on either de novo protein synthesis or the duration of the preconditioning stimulus. These findings suggest that the mechanisms underlying rapid and delayed tolerance induced by hypothermia differ fundamentally. Brief hypothermia could provide a rapid means of inducing transient tissue protection in the context of predictable ischemic events.

Sulfonylureas and cardiovascular effects: from experimental data to clinical use. Available data in humans and clinical applications

OBJECTIVES

33 years after the UGDP study, the question of deleterious effects of the sulfoylurea (SU) is still raised. We have made a systematic review of the literature from experimental studies to clinical and epidemiological studies.

RESULTS

The main molecule studied is glibenclamide (GB). In vitro and in animal studies, GB is both deleterious for ischemic preconditionning (IPC) and protective for arrhythmia during acute ischemia. Glimepiride (GM) and gliclazide (GCZ) do not seem to have effect on IPC. These effects have been few studied in diabetic animals. In human, according to the investigations used, the GB seems nil or suppressing for IPC, it seems elsewhere decreases ventricular arrhythmias during periods of acute ischemia. It is possible that these two actions account for the non-appearance of concordant deleterious effects between short and long-term studies. With regards to other drugs, only the GM has been specifically studied in human and appears to be nil on IPC. The only prospective clinical study available, although not having for objective to answer to this question, is the UKPDS study. This trial demonstrates the absence of deleterious cardiac effects of GB compared to chlorpropamide and particularly compared to insulin.

CONCLUSION

In conclusion, in experimental studies the cardiac effects of SU differ: both deleterious and protective for GB, nil for GM and GCZ on IPC. In all cases the clinical consequences seems to be nil.

Remote preconditioning lessens the deterioration of pulmonary function after repeated coronary artery occlusion and reperfusion in sheep

PURPOSE

We investigated whether remote organ preconditioning (RPC) can preserve pulmonary function following repeated myocardial ischemia/reperfusion in a model mimicking multi-vessel off-pump coronary artery bypass (OPCAB) revascularization.

METHODS

Nine sheep (Group-RPC) underwent RPC by three episodes of five-minute occlusion and five-minute reperfusion of the iliac artery. Five sheep (Group-C) were time-matched controls. Afterwards, ten-minute occlusion and reperfusion of the left anterior descending, the first diagonal and the left circumflex coronary arteries were performed consecutively. Hemodynamic and respiratory parameters and arterial blood gases were measured until 120 min after the final coronary reperfusion. Anesthesia was maintained with halothane in oxygen and nitrous oxide. Animals were ventilated with a tidal volume of 15-20 mL.kg(-1) in a non-rebreathing system, and a respiratory rate 14-16 min, with 5-cm H(2)O positive end expiratory pressure after thoracotomy.

RESULTS

Repeated coronary occlusion and reperfusion was associated in this experimental model with an increase in pulmonary vascular resistance (PVR) and pulmonary arterial pressure (PAP) and a decrease in PaO(2) and PaO(2)/FIO(2) in Group-C. After 120 min reperfusion, PaO(2) and PaO(2)/FIO(2) in Group-RPC were higher (192 +/- 69 mmHg and 241 +/- 78 vs 115 +/- 54 mmHg and 129 +/- 64, P < 0.05), while PVR and PAP were lower than in Group-C. At 120 min of reperfusion, PaO(2) and PaO(2)/FIO(2) were inversely correlated with PVR (P < 0.01).

CONCLUSIONS

RPC by transient occlusion of the iliac artery improves lung gas exchange after repeated coronary artery occlusion and reperfusion mimicking OPCAB surgery, and preserves low PVR in sheep.

Isoflurane activates rat mitochondrial ATP-sensitive K+ channels reconstituted in lipid bilayers

Activation of mitochondrial ATP-sensitive K(+) (mitoK(ATP)) channels is critical in myocardial protection induced by preconditioning with volatile anesthetics or brief periods of ischemia. In this study, we characterized rat mitoK(ATP) channels reconstituted in lipid bilayers and examined their direct regulation by isoflurane. Mitochondria and the inner membrane fraction were isolated from rat ventricles and fused into lipid bilayers. On the basis of their inhibition by 5-hydroxydecanoate (5-HD)/ATP or activation by diazoxide, mitoK(ATP) channels of several conductance states were observed in symmetrical (150 mM) potassium glutamate (26, 47, 66, 83, and 105 pS). Isoflurane (0.8 mM) increased the cumulative open probability from 0.09 +/- 0.02 at baseline to 0.50 +/- 0.09 (P < 0.05, n = 5), which was inhibited by 5-HD. Isoflurane caused a dose-dependent rightward shift in ATP inhibition of mitoK(ATP) channels, which increased the IC(50) for ATP from 335 +/- 4 to 940 +/- 34 microM at 0.8 mM (P < 0.05, n = 5 approximately 8). We conclude that direct activation of the mitoK(ATP) channel by isoflurane is likely to contribute to volatile anesthetic-induced myocardial preconditioning.

Activation of ATP-dependent potassium channels is a trigger but not a mediator of ischaemic preconditioning in pigs

1. Activation of ATP-dependent potassium channels (K(ATP)) is involved in ischaemic preconditioning (IP). In isolated buffer-perfused rabbit hearts, activation of mitochondrial K(ATP)--through a generation of free radicals--acted as a trigger rather than a mediator of IP; the isolated buffer-perfused heart preparation, however, favours free radical generation. In contrast, in vivo studies in rats and dogs suggested that activation of K(ATP) acts as a mediator of IP's protection. A detailed analysis on the role of K(ATP) in IP's protection in vivo by varying the time and dose of K(ATP) blocker administration is, however, lacking. 2. In 54 enflurane-anaesthetized pigs, the left anterior descending coronary artery was perfused by an extracorporeal circuit. Infarct size (IS, %, TTC) following 90 min sustained low-flow ischaemia and 120 min reperfusion was 26.6+/-3.5 (s.e.m.) (n=8). IP with one cycle of 10 min ischaemia and 15 min reperfusion reduced IS to 6.5+/-2.1 (n=7, P<0.05). Blockade of K(ATP) with glibenclamide (0.5 mg kg(-1) i.v., 50 microg min(-1) continuous infusion) starting 10 min before or immediately following the preconditioning ischaemia abolished IS reduction by IP (20.7+/-2.7, n=7 and 21.9+/-6.6, n=6, respectively) while having no effect on IS per se (22.2+/-5.2, n=7), supporting a trigger role of K(ATP) in IP. In contrast, starting glibenclamide following the preconditioning ischaemia 10 min prior to the sustained ischaemia did not prevent IS reduction by IP (3.7+/-2.3, n=6), even when its bolus dose was increased to 1.5 mg kg(-1) (26.6+/-3.8 with IP vs 37.5+/-2.9 without IP; n=7 and 6 respectively, P<0.05), thereby refuting a mediator role of K(ATP) in IP. 3. In conclusion, activation of K(ATP) in the immediate reperfusion following the preconditioning ischaemia is pivotal for triggering IP.

Adenosine type 1 (A1) receptors mediate protection against myocardial infarction produced by chronic, intermittent ingestion of ethanol in dogs

BACKGROUND

Chronic consumption of small amounts of ethanol protects myocardium from ischemic injury. We tested the hypothesis that adenosine type 1 (A(1)) receptors mediate these beneficial effects.

METHODS

Dogs (n=37) were fed with ethanol (1.5 g/kg) or water mixed with dry food twice per day for 12 weeks, fasted overnight before experimentation, and instrumented for measurement of hemodynamics. Dogs received intravenous drug vehicle (50% polyethylene glycol in 0.1 N sodium hydroxide and 0.9% saline over 15 min) or the selective A(1) receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX, 0.8 mg/kg over 15 min) and were subjected to a 60 min coronary artery occlusion followed by 3 h of reperfusion. Myocardial infarct size and transmural coronary collateral blood flow were measured with triphenyltetrazolium chloride staining and radioactive microspheres, respectively.

RESULTS

The area at risk (AAR) for infarction was similar between groups. Pretreatment with ethanol significantly reduced infarct size to 13+/-2% (n=7) of the AAR as compared to control experiments (26+/-2%; n=7). DPCPX abolished the protective effects of ethanol pretreatment (30+/-3%; n=7) but had no effect in dogs that did not receive ethanol (25+/-2%; n=7). No differences in transmural coronary collateral blood flow were observed between groups.

CONCLUSIONS

The present findings indicate that chronic ingestion of small amounts of ethanol produces myocardial protection that persists after the discontinuation of ethanol. The results indicate that A(1) receptors mediate ethanol-induced preconditioning in dogs independent of alterations in systemic hemodynamics or coronary collateral blood flow.

The role of endogenous angiotensin II in ischaemia, reperfusion and preconditioning of the isolated rat heart

We examined the possibility that endogenous angiotensin II (AII) is involved in the regulation of the cardiac Na(+)/H(+) exchanger (NHE1) during ischaemia, reperfusion and preconditioning. Mechanical function and intracellular sodium ([Na(+)](i)) were studied in isolated, perfused rat hearts. To test whether AII production might underlie the increased activity of NHE1 on reperfusion, we applied the AII receptor antagonist losartan during ischaemia and reperfusion. Losartan significantly improved mechanical performance on reperfusion and reduced the peak [Na(+)](i) on reperfusion. It has been proposed that preconditioning inhibits the activity of NHE1 in early reperfusion. To test whether this might be because of impaired action of AII on NHE1 we applied AII throughout ischaemia and reperfusion in preconditioned hearts. AII abolished the improved mechanical recovery caused by preconditioning and the peak [Na(+)](i) on reperfusion was similar to that after ischaemia alone. Addition of the NHE1 antagonist cariporide or losartan simultaneously with AII, reversed the deleterious effects of AII on the preconditioned heart. These studies suggest that AII contributes to the activation of NHE1 in early reperfusion and that part of the beneficial effect of preconditioning may be attributed to the abolition of AII-induced activation of NHE1.

K(ATP) channel opener protects neonatal rabbit heart better than St. Thomas' solution

OBJECTIVES

Myocardial protection with ATP-sensitive potassium channel (K(ATP) channel) openers is as effective as St. Thomas' cardioplegia (StTCP) in adult rabbit hearts. This study compares the effectiveness of the K(ATP) channel opener pinacidil to StTCP in protecting neonatal rabbit hearts exposed to global ischemia.

METHODS

Seventeen neonatal rabbit hearts (7-9 days old) perfused with Krebs-Henseleit buffer (KHB) on a Langendorff apparatus underwent 90 min of normothermic ischemia. Six (ischemia control) received no pretreatment before or during ischemia. Six others (pinacidil) received a 3-min infusion of 50 microM pinacidil in KHB without StTCP at the onset of ischemia. Five others (StTCP) received a 3-min infusion of StTCP at the onset of ischemia. After 60 min of KHB reperfusion, recovery of left ventricular (LV) performance and coronary flow (CF) were measured and compared to preischemia. A paired t test was used for comparison between drug-treated and untreated groups.

RESULTS

Pinacidil-treated hearts had significantly better recovery of left ventricular developed pressure (47 +/- 3.8 mmHg vs 32 +/- 2.5 mmHg, P < 0.05), contractility (+dP/dt(max); 885.4 +/- 74 mmHg vs 643.7 +/- 65 mmHg, P < 0.05), left ventricular end diastolic pressure (10.5 +/- 0.9 mmHg vs 17.4 +/- 1.2 mmHg P < 0.05), compliance (-dP/dt(max); 994.2 +/- 86 mmHg vs 673.6 +/- 69 mmHg, P < 0.05), and CF (5.9 +/- 0.4 ml/min vs 4.2 +/- 0.2 ml/min, P < 0.05) compared to ischemic control. StTCP only improved the recovery of -dP/dt(max) (877.4 +/- 73 mmHg/s vs 673.6 +/- 69 mmHg/s, P < 0.05) and CF (5.7 +/- 0.3 ml/min vs 4.2 +/- 0.2 ml/min, P < 0.05) compared to control.

CONCLUSIONS

Pinacidil pretreatment provided superior recovery of systolic performance compared to St. Thomas' cardioplegia solution in neonatal hearts. Myocardial protection by pretreatment with the K(ATP) channel opener pinacidil may be a new strategy for myocardial protection during pediatric cardiac surgery.

Physiological and pathophysiological roles of ATP-sensitive K+ channels

ATP-sensitive potassium (K(ATP)) channels are present in many tissues, including pancreatic islet cells, heart, skeletal muscle, vascular smooth muscle, and brain, in which they couple the cell metabolic state to its membrane potential, playing a crucial role in various cellular functions. The K(ATP) channel is a hetero-octamer comprising two subunits: the pore-forming subunit Kir6.x (Kir6.1 or Kir6.2) and the regulatory subunit sulfonylurea receptor SUR (SUR1 or SUR2). Kir6.x belongs to the inward rectifier K(+) channel family; SUR belongs to the ATP-binding cassette protein superfamily. Heterologous expression of differing combinations of Kir6.1 or Kir6.2 and SUR1 or SUR2 variant (SUR2A or SUR2B) reconstitute different types of K(ATP) channels with distinct electrophysiological properties and nucleotide and pharmacological sensitivities corresponding to the various K(ATP) channels in native tissues. The physiological and pathophysiological roles of K(ATP) channels have been studied primarily using K(ATP) channel blockers and K(+) channel openers, but there is no direct evidence on the role of the K(ATP) channels in many important cellular responses. In addition to the analyses of naturally occurring mutations of the genes in humans, determination of the phenotypes of mice generated by genetic manipulation has been successful in clarifying the function of various gene products. Recently, various genetically engineered mice, including mice lacking K(ATP) channels (knockout mice) and mice expressing various mutant K(ATP) channels (transgenic mice), have been generated. In this review, we focus on the physiological and pathophysiological roles of K(ATP) channels learned from genetic manipulation of mice and naturally occurring mutations in humans.

Cardioprotection by metformin is abolished by a nitric oxide synthase inhibitor in ischemic rabbit hearts

We investigated the effects of metformin on myocardial metabolism during ischemia by 31P-nuclear magnetic resonance (NMR) in isolated rabbit hearts. Metformin was administered 60 min prior to induction of global ischemia, or in combination with a nitric oxide synthase inhibitor, N(G)-nitro-L-arginine methyl ester (L-NAME), at 5 min or 60 min prior to the ischemia. Normothermic global ischemia was then carried out for 45 min. Twenty-eight hearts were divided into 4 experimental groups consisting of 7 hearts each: a control (C) group; an M group receiving metformin treatment alone; an M+L (5) group receiving metformin treatment with L-NAME at 5 min before ischemia; and an M+L (60) group receiving metformin treatment with L-NAME at 60 min before ischemia. During ischemia, the decrease in adenosine triphosphate (ATP) was significantly inhibited in the M group in comparison with the C group (p < 0.01). However, this preservation of ATP in the M group was inhibited in the M+L (5) group during ischemia. In contrast, in the M+L (60) group, this preservation of ATP in the M group was not inhibited during, but not at the end of, ischemia. These results suggest that metformin has a significant beneficial effect for improving the myocardial energy metabolism during myocardial ischemia. This cardioprotection may be more dependent on nitric oxide synthase during ischemia than during pre-ischemia.

The role of mitochondrial K(ATP) channels in antiarrhythmic effects of ischaemic preconditioning in dogs

1. In the canine a single brief (5 min) coronary artery occlusion protects the myocardium against the severe ventricular arrhythmias and reduces the ischaemic changes that result from a subsequent, more prolonged (25 min) occlusion. The main purpose of the present study was to examine whether mitochondrial K(ATP) channels are involved in this protection. 2. In chloralose-urethane anaesthetized dogs, preconditioning (PC) was induced by a single 5 min period occlusion of the left anterior descending (LAD) coronary artery, 20 min prior to a 25 min occlusion of the same artery. In some of these PC dogs 5-hydroxydecanoate (5-HD; 150 micro g kg(-1) min(-1) by intracoronary infusion) was given over a period of 30 min either before, or after PC. In other dogs the mitochondrial K(ATP) channel opener diazoxide (1 mg kg(-1); i.c.) was given, either alone or in the presence of 5-HD. Control dogs (infused with saline) were simply subjected to a 25 min occlusion and reperfusion. 3. Compared to controls, both PC and diazoxide significantly reduced the number of ventricular premature beats (VPBs; 295+/-67 to 89+/-28 and 19+/-11, respectively; P<0.05), the number of episodes of ventricular tachycardia (VT; 8.3+/-4.2 to 1.6+/-0.9 and 0.2+/-0.1; P<0.05) and the incidences of VT (100 to 43 and 33%; P<0.05) and ventricular fibrilation (VF; 60 to 0 and 17%; P<0.05) during the 25 min occlusion of the LAD. Further, 43% of the PC dogs and 58% of the diazoxide treated dogs survived the combined ischaemia-reperfusion insult (cp. 0% in the controls; P<0.05). The protection afforded by PC and diazoxide was abolished by 5-HD, especially when it was given prior to the PC occlusion. In the presence of 5-HD, three out of 10 dogs fibrillated during the PC occlusion and another three dogs died following reperfusion. Furthermore, there were no survivors in this group from the prolonged ischaemia/reperfusion insult. 5-HD given after PC only attenuated the antiarrhythmic protection. 4. Opening of mitoK(ATP) channels prior to ischaemia by preconditioning and diazoxide protects the myocardium against ischaemia and reperfusion-induced arrhythmias. This protection is abolished if the opening of these channels is prevented by the prior administration of 5-HD but only attenuated if 5-HD is given after preconditioning. The results indicate that opening of mitoK(ATP) channels prior to ischaemia is mandatory for protection against ischaemia and reperfusion-induced arrhythmias.

Isoflurane does not produce a second window of preconditioning against myocardial infarction in vivo

The administration of a volatile anesthetic shortly before a prolonged ischemic episode exerts protective effects against myocardial infarction similar to those of ischemic preconditioning. A second window of preconditioning (SWOP) against myocardial infarction can also be elicited by brief episodes of ischemia when this occurs 24 h before prolonged coronary artery occlusion. Whether remote exposure to a volatile anesthetic also causes delayed myocardial protection is unknown. We tested the hypothesis that the administration of isoflurane 24 h before ischemia produces a SWOP against infarction. Barbiturate-anesthetized dogs (n = 25) were instrumented for measurement of hemodynamics, including aortic and left ventricular (LV) pressures and LV +dP/dt(max), and subjected to a 60-min left anterior descending coronary artery occlusion followed by 3 h of reperfusion. Myocardial infarct size and coronary collateral blood flow were assessed with triphenyltetrazolium chloride staining and radioactive microspheres, respectively. Two groups of dogs received 1.0 minimum alveolar anesthetic concentration isoflurane for 30 min or 6 h that was discontinued 30 min (acute) or 24 h (delayed) before ischemia and reperfusion, respectively. A control group of dogs did not receive isoflurane. Infarct size was 27% +/- 3% of the LV area at risk in the absence of pretreatment with isoflurane. Acute, but not remote, administration of isoflurane reduced infarct size (12% +/- 1% and 31% +/- 3%, respectively). No differences in hemodynamics or transmural myocardial perfusion during or after occlusion were observed between groups. The results indicate that isoflurane does not produce a SWOP when administered 24 h before prolonged myocardial ischemia in vivo.

IMPLICATIONS

Isoflurane mimics the beneficial effects of ischemic preconditioning by protecting myocardium against infarction when it is administered shortly before a prolonged ischemic episode. However, unlike ischemic preconditioning, isoflurane does not produce a second window of protection 24 h after administration in dogs.

Sarcolemmal and mitochondrial K(ATP) channels and myocardial ischemic preconditioning

Ischemic preconditioning (IPC) is the phenomenon whereby brief periods of ischemia have been shown to protect the myocardium against a sustained ischemic insult. The result of IPC may be manifest as a marked reduction in infarct size, myocardial stunning, or incidence of arrhythmias. While many substances and pathways have been proposed to play a role in the signal transduction mediating the cardioprotective effect of IPC, overwhelming evidence indicates an intimate involvement of the ATP-sensitive potassium channel (K(ATP) channel) in this process. Initial hypotheses suggested that the surface or sarcolemmal K(ATP) (sarcK(ATP)) channel mediated the cardioprotective effects of IPC. However, much research has subsequently supported a major role for the mitochondrial K(ATP) channel (mitoK(ATP)) as the one involved in IPC-mediated cardioprotection. This review presents evidence to support a role for the sarcK(ATP) or the mitoK(ATP) channel as either triggers and/or downstream mediators in the phenomenon of IPC.