Role of protein kinase C-alpha in activation of ecto-5'-nucleotidase in the preconditioned canine myocardium

Mitochondrial Kinase Signaling for Cardioprotection

Myocardial ischemia/reperfusion injury is reduced by cardioprotective adaptations such as local or remote ischemic conditioning. The cardioprotective stimuli activate signaling cascades, which converge on mitochondria and maintain the function of the organelles, which is critical for cell survival. The signaling cascades include not only extracellular molecules that activate sarcolemmal receptor-dependent or -independent protein kinases that signal at the plasma membrane or in the cytosol, but also involve kinases, which are located to or within mitochondria, phosphorylate mitochondrial target proteins, and thereby modify, e.g., respiration, the generation of reactive oxygen species, calcium handling, mitochondrial dynamics, mitophagy, or apoptosis. In the present review, we give a personal and opinionated overview of selected protein kinases, localized to/within myocardial mitochondria, and summarize the available data on their role in myocardial ischemia/reperfusion injury and protection from it. We highlight the regulation of mitochondrial function by these mitochondrial protein kinases.

GLP-1 vasodilatation in humans with coronary artery disease is not adenosine mediated

BACKGROUND

Incretin therapies appear to provide cardioprotection and improve cardiovascular outcomes in patients with diabetes, but the mechanism of this effect remains elusive. We have previously shown that glucagon-like peptide (GLP)-1 is a coronary vasodilator and we sought to investigate if this is an adenosine-mediated effect.

METHODS

We recruited 41 patients having percutaneous coronary intervention (PCI) for stable angina and allocated them into four groups administering a specific study-related infusion following successful PCI: GLP-1 infusion (Group G) (n = 10); Placebo, normal saline infusion (Group P) (n = 11); GLP-1 + Theophylline infusion (Group GT) (n = 10); and Theophylline infusion (Group T) (n = 10). A pressure wire assessment of coronary distal pressure and flow velocity (thermodilution transit time-Tmn) at rest and hyperaemia was performed after PCI and repeated following the study infusion to derive basal and index of microvascular resistance (BMR and IMR).

RESULTS

There were no significant differences in the demographics of patients recruited to our study. Most of the patients were not diabetic. GLP-1 caused significant reduction of resting Tmn that was not attenuated by theophylline: mean delta Tmn (SD) group G - 0.23 s (0.27) versus group GT - 0.18 s (0.37), p = 0.65. Theophylline alone (group T) did not significantly alter resting flow velocity compared to group GT: delta Tmn in group T 0.04 s (0.15), p = 0.30. The resulting decrease in BMR observed in group G persisted in group GT: - 20.83 mmHg s (24.54 vs. - 21.20 mmHg s (30.41), p = 0.97. GLP-1 did not increase circulating adenosine levels in group GT more than group T: delta median adenosine - 2.0 ng/ml (- 117.1, 14.8) versus - 0.5 ng/ml (- 19.6, 9.4); p = 0.60.

CONCLUSION

The vasodilatory effect of GLP-1 is not abolished by theophylline and GLP-1 does not increase adenosine levels, indicating an adenosine-independent mechanism of GLP-1 coronary vasodilatation.

TRIAL REGISTRATION

The local research ethics committee approved the study (National Research Ethics Service-NRES Committee, East of England): REC reference 14/EE/0018. The study was performed according to institutional guidelines, was registered on http://www.clinicaltrials.gov (unique identifier: NCT03502083) and the study conformed to the principles outlined in the Declaration of Helsinki.

Protein kinase C and cardiac dysfunction: a review

Heart failure (HF) is a physiological state in which cardiac output is insufficient to meet the needs of the body. It is a clinical syndrome characterized by impaired ability of the left ventricle to either fill or eject blood efficiently. HF is a disease of multiple aetiologies leading to progressive cardiac dysfunction and it is the leading cause of deaths in both developed and developing countries. HF is responsible for about 73,000 deaths in the UK each year. In the USA, HF affects 5.8 million people and 550,000 new cases are diagnosed annually. Cardiac remodelling (CD), which plays an important role in pathogenesis of HF, is viewed as stress response to an index event such as myocardial ischaemia or imposition of mechanical load leading to a series of structural and functional changes in the viable myocardium. Protein kinase C (PKC) isozymes are a family of serine/threonine kinases. PKC is a central enzyme in the regulation of growth, hypertrophy, and mediators of signal transduction pathways. In response to circulating hormones, activation of PKC triggers a multitude of intracellular events influencing multiple physiological processes in the heart, including heart rate, contraction, and relaxation. Recent research implicates PKC activation in the pathophysiology of a number of cardiovascular disease states. Few reports are available that examine PKC in normal and diseased human hearts. This review describes the structure, functions, and distribution of PKCs in the healthy and diseased heart with emphasis on the human heart and, also importantly, their regulation in heart failure.

The involvement of protein kinase C-ε in isoflurane induced preconditioning of human embryonic stem cell--derived Nkx2.5(+) cardiac progenitor cells

Background

Anesthetic preconditioning can improve survival of cardiac progenitor cells exposed to oxidative stress. We investigated the role of protein kinase C and isoform protein kinase C-ε in isoflurane-induced preconditioning of cardiac progenitor cells exposed to oxidative stress.

Methods

Cardiac progenitor cells were obtained from undifferentiated human embryonic stem cells. Immunostaining with anti-Nkx2.5 was used to confirm the differentiated cardiac progenitor cells. Oxidative stress was induced by H₂O₂ and FeSO₄. For anesthetic preconditioning, cardiac progenitor cells were exposed to 0.25, 0.5, and 1.0 mM of isoflurane. PMA and chelerythrine were used for protein kinase C activation and inhibition, while εψRACK and εV1-2 were used for protein kinase C -ε activation and inhibition, respectively.

Results

Isoflurane-preconditioning decreased the death rate of Cardiac progenitor cells exposed to oxidative stress (death rates isoflurane 0.5 mM 12.7 ± 9.3 %, 1.0 mM 12.0 ± 7.7 % vs. control 31.4 ± 10.2 %). Inhibitors of both protein kinase C and protein kinase C -ε abolished the preconditioning effect of isoflurane 0.5 mM (death rates 27.6 ± 13.5 % and 25.9 ± 8.7 % respectively), and activators of both protein kinase C and protein kinase C - ε had protective effects from oxidative stress (death rates 16.0 ± 3.2 % and 10.6 ± 3.8 % respectively).

Conclusions

Both PKC and PKC-ε are involved in isoflurane-induced preconditioning of human embryonic stem cells -derived Nkx2.5⁺ Cardiac progenitor cells under oxidative stress.

KATP Channels in the Cardiovascular System

KATP channels are integral to the functions of many cells and tissues. The use of electrophysiological methods has allowed for a detailed characterization of KATP channels in terms of their biophysical properties, nucleotide sensitivities, and modification by pharmacological compounds. However, even though they were first described almost 25 years ago (Noma 1983, Trube and Hescheler 1984), the physiological and pathophysiological roles of these channels, and their regulation by complex biological systems, are only now emerging for many tissues. Even in tissues where their roles have been best defined, there are still many unanswered questions. This review aims to summarize the properties, molecular composition, and pharmacology of KATP channels in various cardiovascular components (atria, specialized conduction system, ventricles, smooth muscle, endothelium, and mitochondria). We will summarize the lessons learned from available genetic mouse models and address the known roles of KATP channels in cardiovascular pathologies and how genetic variation in KATP channel genes contribute to human disease.

Molecular basis of cardioprotection: signal transduction in ischemic pre-, post-, and remote conditioning

Reperfusion is mandatory to salvage ischemic myocardium from infarction, but reperfusion per se contributes to injury and ultimate infarct size. Therefore, cardioprotection beyond that by timely reperfusion is needed to reduce infarct size and improve the prognosis of patients with acute myocardial infarction. The conditioning phenomena provide such cardioprotection, insofar as brief episodes of coronary occlusion/reperfusion preceding (ischemic preconditioning) or following (ischemic postconditioning) sustained myocardial ischemia with reperfusion reduce infarct size. Even ischemia/reperfusion in organs remote from the heart provides cardioprotection (remote ischemic conditioning). The present review characterizes the signal transduction underlying the conditioning phenomena, including their physical and chemical triggers, intracellular signal transduction, and effector mechanisms, notably in the mitochondria. Cardioprotective signal transduction appears as a highly concerted spatiotemporal program. Although the translation of ischemic postconditioning and remote ischemic conditioning protocols to patients with acute myocardial infarction has been fairly successful, the pharmacological recruitment of cardioprotective signaling has been largely disappointing to date.

An interaction between glucagon-like peptide-1 and adenosine contributes to cardioprotection of a dipeptidyl peptidase 4 inhibitor from myocardial ischemia-reperfusion injury

Dipeptidyl peptidase 4 (DPP4) inhibitors suppress the metabolism of the potent antihyperglycemic hormone glucagon-like peptide-1 (GLP-1). DPP4 was recently shown to provide cardioprotection through a reduction of infarct size, but the mechanism for this remains elusive. Known interactions between DPP4 and adenosine deaminase (ADA) suggest an involvement of adenosine signaling in DPP4 inhibitor-mediated cardioprotection. We tested whether the protective mechanism of the DPP4 inhibitor alogliptin against myocardial ischemia-reperfusion injury involves GLP-1- and/or adenosine-dependent signaling in canine hearts. In anesthetized dogs, the coronary artery was occluded for 90 min followed by reperfusion for 6 h. A 4-day pretreatment with alogliptin reduced the infarct size from 43.1 ± 2.5% to 17.1 ± 5.0% without affecting collateral flow and hemodynamic parameters, indicating a potent antinecrotic effect. Alogliptin also suppressed apoptosis as demonstrated by the following analysis: 1) reduction in the Bax-to-Bcl2 ratio; 2) cytochrome c release, 3) an increase in Bad phosphorylation in the cytosolic fraction; and 4) terminal deoxynucleotidyl transferase dUTP nick end labeling assay. This DPP4 inhibitor did not affect blood ADA activity or adenosine concentrations. In contrast, the nonselective adenosine receptor blocker 8-(p-sulfophenyl)theophylline (8SPT) completely blunted the effect of alogliptin. Alogliptin did not affect Erk1/2 phosphorylation, but it did stimulate phosphorylation of Akt, glycogen synthase kinase-3β, and cAMP response element-binding protein (CREB). Only 8SPT prevented alogliptin-induced CREB phosphorylation. In conclusion, the DPP4 inhibitor alogliptin suppresses ischemia-reperfusion injury via adenosine receptor- and CREB-dependent signaling pathways.

Pursuing enigmas on ischemic heart disease and sudden cardiac death

This article reviews what our colleagues have found as to how ischemic injury or cell death develop in myocardium through Ca(2+)-dependent protease calpain and how compensatory responses evolve through activation of intracellular signaling molecules including PKC isoforms, MAP kinase family enzymes and PI3 kinase. We also addressed how restraint or other psychological stress evokes hypertension and cardiovascular responses in signaling molecules or genes. Unexpectedly, carbon monoxide protects heart and cardiogenic cells against ischemia-resperfusion injury. When I think back, the unresolved cases of autopsies provided ideas for experimental study, which then taught us how the other cases died.

Regulation of renal ectophosphodiesterase by protein kinase C and sodium diet

Kidneys metabolize arterial cAMP to adenosine by the sequential actions of ectophosphodiesterase (cAMP --> AMP) and ecto-5'-nucleotidase (AMP --> adenosine). In this study, we demonstrated that etheno-AMP (fluorescent AMP analog) is nearly completely converted to etheno-adenosine during a single pass through the isolated, perfused rat kidney indicating that ecto-5'-nucleotidase is not rate limiting. Therefore, we examined the regulation of ectophosphodiesterase. In 17 control kidneys pretreated with alpha,beta-methylene-adenosine-5'-diphosphate (inhibitor of ecto-5'-nucleotidase to prevent AMP metabolism; 100 microM), addition of cAMP (10 microM) to the perfusate increased renal venous AMP from 0.6 +/- 0.2 to 3.5 +/- 0.5 nmol/min/g. Pretreatment of kidneys with phorbol 12-myristate 13-acetate (protein kinase C activator; 7.5 nM) increased renal vascular resistance and significantly augmented the cAMP-induced increase in renal venous AMP (from 0.8 +/- 0.2 to 5.2 +/- 0.7 nmol/min/g with cAMP). Pretreatment of kidneys with bisindolymaleimide I (protein kinase C inhibitor; 3 microM) abrogated the effects of phorbol 12-myristate 13-acetate on both renovascular resistance and cAMP conversion to AMP. Compared with kidneys from rats fed a high-sodium diet (3.15%) for 1 week, in kidneys from rats fed a low-sodium diet (0.03%) the conversion of cAMP to AMP was attenuated (high sodium, from 1.0 +/- 0.1 to 4.6 +/- 0.4 nmol/min/g with cAMP; low sodium, from 0.5 +/- 0.04 to 2.6 +/- 0.04 nmol/min/g with cAMP). We conclude that the renal vasculature efficiently converts AMP to adenosine and that metabolism of cAMP to AMP is rate limiting and regulated acutely by protein kinase C and chronically by sodium intake.

Adenosine: trigger and mediator of cardioprotection

Adenosine, a purine nucleoside, is ubiquitous in the body, and is a critical component of ATP. Its concentration jumps 100-fold during periods of oxygen depletion and ischemia. There are four adenosine receptors: A(1) and A(3) coupled to G(i/o) and the high-affinity A(2A) and low-affinity A(2B) coupled to G(s). Adenosine is one of three autacoids released by ischemic tissue which are important triggers of ischemic preconditioning (IPC). It is the A(1) and to some extent A(3) receptors which participate in the intracellular signaling that triggers cardioprotection. Unlike bradykinin and opioids, the other two autacoids, adenosine is not dependent on opening of mitochondrial K(ATP) channels or release of reactive oxygen species (ROS), but rather activates phospholipase C and/or protein kinase C (PKC) directly. Another signaling cascade at reperfusion involves activated PKC which initiates binding to and activation of an A(2) adenosine receptor that we believe is the A(2B). Although the latter is the low-affinity receptor, its interaction with PKC increases its affinity and makes it responsive to the accumulated tissue adenosine. A(2B) agonists, but not adenosine or A(1) agonists, infused at reperfusion can initiate this second signaling cascade and mimic preconditioning's protection. The same A(2B) receptors are critical for postconditioning's protection. Thus adenosine is both an important trigger and a mediator of cardioprotection.

Sevoflurane-induced cardioprotection depends on PKC-alpha activation via production of reactive oxygen species

BACKGROUND

We previously demonstrated the involvement of the Ca2+-independent protein kinase C-delta (PKC-delta) isoform in sevoflurane-induced cardioprotection against ischaemia and reperfusion (I/R) injury. Since sevoflurane is known to modulate myocardial Ca2+-handling directly, in this study we investigated the role of the Ca2+-dependent PKC-alpha isoform in sevoflurane-induced cardioprotective signalling in relation to reactive oxygen species (ROS), adenosine triphosphate-sensitive mitochondrial K+ (mitoK+(ATP)) channels, and PKC-delta.

METHODS

Preconditioned (15 min 3.8 vol% sevoflurane) isolated rat right ventricular trabeculae were subjected to I/R, consisting of 40 min superfusion with hypoxic, glucose-free buffer, followed by normoxic glucose-containing buffer for 60 min. After reperfusion, contractile recovery was expressed as percentage of force development before I/R. The role of PKC-alpha, ROS, mitoK+(ATP) channels, and PKC-delta was established using the following pharmacological inhibitors: Go6976 (GO; 50 nM), n-(2-mercaptopropionyl)-glycine (MPG; 300 microM), 5-hydroxydecanoic acid sodium (5HD; 100 microM), and rottlerin (ROT; 1 microM).

RESULTS

Preconditioning of trabeculae with sevoflurane improved contractile recovery after I/R [65 (3)% (I/R + SEVO) vs 47 (3)% (I/R); n = 8; P < 0.05]. This cardioprotective effect was attenuated in trabeculae treated with GO [42 (4)% (I/R + SEVO + GO); P > 0.05 vs (I/R)]. In sevoflurane-treated trabeculae, PKC-alpha translocated towards mitochondria, as shown by immunofluorescent co-localization analysis. GO and MPG, but not 5HD or ROT, abolished this translocation.

CONCLUSIONS

Sevoflurane improves post-ischaemic contractile recovery via activation of PKC-alpha. ROS production, but not opening of mitoK+(ATP) channels, precedes PKC-alpha translocation towards mitochondria. This study shows the involvement of Ca2+-dependent PKC-alpha in addition to the well-established role of Ca2+-independent PKC isoforms in sevoflurane-induced cardioprotection.

Ischemic preconditioning targets the reperfusion phase

Emerging studies suggest that signaling during the myocardial reperfusion phase contributes to ischemic preconditioning (IPC). Whether the activation of PKC, the opening of the mKATP channel, redox signaling and transient acidosis specifically at the time of myocardial reperfusion are required to mediate IPC-induced protection is not known. Langendorff-perfused rat hearts were subjected to 35 min ischemia followed by 120 min reperfusion at the end of which infarct size was determined by tetrazolium staining. Control and IPC-treated hearts were randomized to receive for the first 15 min of reperfusion: (1) DMSO (0.02%) vehicle control; (2) chelerythrine (10 micromol/l), a PKC antagonist; (3) 5 hydroxydecanoate (5- HD,100 micromol/l), a mKATP channel blocker; (4) N-mercaptopropionylglycine (MPG,1 mmol/l), a reactive oxygen species scavenger; (5) NaHCO3 (pH 7.6), to counteract any acidosis. Interestingly, all four agents given at the time of myocardial reperfusion abolished the infarct reduction elicited by IPC (N>6/group): (1) DMSO at reperfusion: 49.3+/-3.6% in control versus 21.0+/-3.6% with IPC:P<0.05; (2) chelerythrine at reperfusion: 57.1+/-2.5% in control versus 60.1+/-3.3% with IPC:P=NS; (3) 5-HD at reperfusion: 53.4+/-6.5 % in control versus 42.6+/-4.4% with IPC:P=NS; (4) MPG at reperfusion: 55.3+/-4.6% in control versus 43.9+/-5.2% with IPC:P=NS; (5) NaHCO3 at reperfusion 53.4+/-2.5% in control versus 59.0+/-3.3% with IPC:P=NS. In conclusion, we report for the first time that PKC activation, mKATP channel opening, redox signaling and a low pH at the time of myocardial reperfusion are required to mediate the cardioprotection elicited by ischemic preconditioning.

Protein kinase C protects preconditioned rabbit hearts by increasing sensitivity of adenosine A2b-dependent signaling during early reperfusion

Although protein kinase C (PKC) plays a key role in ischemic preconditioning (IPC), the actual mechanism of that protection is unknown. We recently found that protection from IPC requires activation of adenosine receptors during early reperfusion. We, therefore, hypothesized that PKC might act to increase the heart's sensitivity to adenosine. IPC limited infarct size in isolated rabbit hearts subjected to 30-min regional ischemia/2-h reperfusion and IPC's protection was blocked by the PKC inhibitor chelerythrine given during early reperfusion revealing involvement of PKC at reperfusion. Similarly chelerythrine infused in the early reperfusion period blocked the increased phosphorylation of the protective kinases Akt and ERK1/2 observed after IPC. Infusing phorbol 12-myristate 13-acetate (PMA), a PKC activator, during early reperfusion mimicked IPC's protection. As expected, the protection triggered by PMA at reperfusion was blocked by chelerythrine, but surprisingly it was also blocked by MRS1754, an adenosine A(2b) receptor-selective antagonist, suggesting that PKC was somehow facilitating signaling from the A(2b) receptors. NECA [5'-(N-ethylcarboxamido) adenosine], a potent but not selective A(2b) receptor agonist, increased phosphorylation of Akt and ERK1/2 in a dose-dependent manner. Pretreating hearts with PMA or brief preconditioning ischemia had no effect on phosphorylation of Akt or ERK1/2 per se but markedly lowered the threshold for NECA to induce their phosphorylation. BAY 60-6583, a highly selective A(2b) agonist, also caused phosphorylation of ERK1/2 and Akt. MRS1754 prevented phosphorylation induced by BAY 60-6583. BAY 60-6583 limited infarct size when given to ischemic hearts at reperfusion. These results suggest that activation of cardiac A(2b) receptors at reperfusion is protective, but because of the very low affinity of the receptors endogenous cardiac adenosine is unable to trigger their signaling. We propose that the key protective event in IPC occurs when PKC increases the heart's sensitivity to adenosine so that endogenous adenosine can activate A(2b)-dependent signaling.

Adenosinergic cardioprotection: Multiple receptors, multiple pathways

Adenosine, formed primarily via hydrolysis of 5'-AMP, has been historically dubbed a "retaliatory" metabolite due to enhanced local release and beneficial actions during cellular/metabolic stress. From a cardiovascular perspective, evidence indicates the adenosinergic system is essential in mediation of intrinsic protection (e.g., pre- and postconditioning) and determining myocardial resistance to insult. Modulation of adenosine and its receptors thus remains a promising, though as yet not well-realized, approach to amelioration of injury in ischemic-reperfused myocardium. Adenosine exerts effects through A(1), A(2A), A(2B), and A(3) adenosine receptor subtypes (A(1)AR, A(2A)AR, A(2B)AR, and A(3)AR), which are all expressed in myocardial and vascular cells, and couple to G proteins to trigger a range of responses (generally, but not always, beneficial). Adenosine can also enhance tolerance to injurious stimuli via receptor-independent metabolic effects. Given adenosines contribution to preconditioning, it is no surprise that postreceptor signaling typically mimics that associated with preconditioning. This involves activation/translocation of PKC, PI3 kinase, and MAPKs, with ultimate effects at the level of mitochondrial targets-the mitochondrial K(ATP) channel and/or the mitochondrial permeability transition pore (mPTP). Nonetheless, differences in cytoprotective signaling and actions of the different adenosine receptor subtypes have been recently revealed. Our understanding of adenosinergic cytoprotection continues to evolve, with roles for the A(2) subtypes emerging, together with evidence of essential receptor "cross-talk" in mediation of protection. This review focuses on current research into adenosine-mediated cardioprotection, highlighting recent findings which, together with a wealth of prior knowledge, may ultimately facilitate adenosinergic approaches to clinical cardiac protection.

Exposure to Hg2+ and Pb2+ changes NTPDase and ecto-5'-nucleotidase activities in central nervous system of zebrafish (Danio rerio)

Neurotransmission can be affected by exposure to heavy metals, such as mercury and lead. ATP is a signaling molecule that can be metabolized by a group of enzymes called ecto-nucleotidases. Here we investigated the effects of mercury chloride (HgCl(2)) and lead acetate (Pb(CH(3)COO)(2)) on NTPDase (nucleoside triphosphate diphosphohydrolase) and ecto-5'-nucleotidase activities in zebrafish brain membranes. In vitro exposure to HgCl(2) decreased ATP and ADP hydrolysis in an uncompetitive mechanism and AMP hydrolysis in a non-competitive manner. Pb(CH(3)COO)(2) inhibited ATP hydrolysis in an uncompetitive manner, but not ADP and AMP hydrolysis. In vivo exposure of zebrafish to HgCl(2) or Pb(CH(3)COO)(2) (20mug/L, during 24, 96h and 30 days) caused differential effects on nucleotide hydrolysis. HgCl(2), during 96h, inhibited the hydrolysis of ATP, ADP and AMP. After 30 days of exposure to HgCl(2), ATP hydrolysis returned to the control levels, ADP hydrolysis was strongly increased and AMP hydrolysis remained inhibited. Exposure to Pb(CH(3)COO)(2) during 96h caused a significant decrease only on ATP hydrolysis. After 30 days, Pb(CH(3)COO)(2) promoted the inhibition of ATP, ADP and AMP hydrolysis. Semi-quantitative RT-PCR analysis showed no changes in the expression of NTPDase1 and 5'-nucleotidase, following 30 days of exposure to both metals. This study demonstrated that Hg(2+) and Pb(2+) affect the ecto-nucleotidase activities, an important enzymatic pathway for the control of purinergic signaling.

Cardioprotective-Mimetics Reduce Myocardial Infarct Size in Animals Resistant to Ischemic Preconditioning

BACKGROUND

Ischemic preconditioning (IPC) elicits two distinct windows of cardioprotection, an early phase that lasts for 1-2 h and a delayed phase that lasts for 24-72 h. However, there is conflicting data as to how long the heart is resistant to IPC-induced cardioprotection after the initial protection wanes, leading to the demonstration of IPC-resistance. This resistance to IPC appears to be dependent on the timing of the next IPC stimulus, the species of animals used and the model studied. Furthermore, the mechanisms responsible IPC-resistance are unknown. It is also important to demonstrate therapeutic interventions that will produce cardioprotection during this period of IPC-resistance.

METHODS AND RESULTS

To examine potential mechanisms responsible for acute IPC-induced resistance, the NHE-1 inhibitor EMD 85131 (2-methyl-5-methylsulfonyl-1-(1-pyrrollyl)-benzoylguanidine), which exerts its effects via mechanisms distinct from IPC, and the K(ATP) channel opener bimakalim, which bypasses the signaling mechanisms of IPC to directly open K(ATP) channels, were examined in a canine model of IPC-resistance. One 10 min. IPC stimulus followed by 10 min. of reperfusion produced a significant reduction in IS/AAR compared to Control (7.1 +/- 2.6% versus 26.0 +/- 6.2%; P < 0.05). However, IPC did not significantly protect the myocardium if a 2 h reperfusion period occurred between the initial IPC stimulus and the subsequent prolonged (60 min) ischemic challenge (IS/AAR: 22.5 +/- 4.8%: P > 0.05). Furthermore, hearts treated with IPC followed by 2 h of reperfusion were resistant to an additional IPC stimulus administered just prior to the subsequent 60 min. occlusion period (IS/AAR: 22.9 +/- 3.2%: P > 0.05). In contrast, administration of the NHE-1 inhibitor EMD 85131 (IS/AAR: 7.4 +/- 2.5%: P < 0.05) or the K(ATP) channel opener bimakalim (IS/AAR: 11.8 +/- 2.4%: P < 0.05) both afforded significant cardioprotection when administered at 2 h of reperfusion in previously preconditioned canine hearts resistant to IPC.

CONCLUSIONS

IPC resistance occurs in this canine model of ischemia-reperfusion injury. However, in spite of IPC resistance, hearts can still be pharmacologically protected by direct application of the K(ATP) channel opener bimakalim or the NHE inhibitor EMD 85131.

Endogenous adenosine protects preconditioned heart during early minutes of reperfusion by activating Akt

Ischemic preconditioning (IPC) is thought to protect by activating survival kinases during reperfusion. We tested whether binding of adenosine receptors is also required during reperfusion and, if so, how long these receptors must be populated. Isolated rabbit hearts were subjected to 30 min of regional ischemia and 2 h of reperfusion. IPC reduced infarct size from 32.1 +/- 4.6% of the risk zone in control hearts to 7.3 +/- 3.6%. IPC protection was blocked by a 20-min pulse of the nonselective adenosine receptor blocker 8-(p-sulfophenyl)-theophylline when started either 5 min before or 10 min after the onset of reperfusion but not when started after 30 min of reperfusion. Protection was also blocked by either 8-cyclopentyl-1,3-dipropylxanthine, an adenosine A1-selective receptor antagonist, or MRS1754, an A2B-selective antagonist, but not by 8-(3-chlorostyryl)caffeine, an A2A-selective antagonist. Blockade of phosphatidylinositol 3-OH kinase (PI3K) with a 20-min pulse of wortmannin also aborted protection when started either 5 min before or 10 or 30 min after the onset of reperfusion but failed when started after 60 min of reflow. U-0126, an antagonist of MEK1/2 and therefore of ERK1/2, blocked protection when started 5 min before reperfusion but not when started after only 10 min of reperfusion. These studies reveal that A1 and/or A2B receptors initiate the protective signal transduction cascade during reperfusion. Although PI3K activity must continue long into the reperfusion phase, adenosine receptor occupancy is no longer needed by 30 min of reperfusion, and ERK activity is only required in the first few minutes of reperfusion.

Aldosterone nongenomically worsens ischemia via protein kinase C-dependent pathways in hypoperfused canine hearts

Rapid nongenomic actions of aldosterone independent of mineralocorticoid receptors (MRs) on vascular tone are divergent. Until now, the rapid nongenomic actions of aldosterone on vascular tone of coronary artery and cardiac function in the in vivo ischemic hearts were not still fully estimated. Furthermore, although aldosterone can modulate protein kinase C (PKC) activity, there is no clear consensus whether PKC is involved in the nongenomic actions of aldosterone on the ischemic hearts. In open chest dogs, the selective infusion of aldosterone into the left anterior descending coronary artery (LAD) reduced coronary blood flow (CBF) in the nonischemic hearts in a dose-dependent manner. Also, in the ischemic state that CBF was decreased to 33% of the baseline, the intracoronary administration of aldosterone (0.1 nmol/L) rapidly decreased CBF (37.4+/-3.8 to 19.3+/-5.2 mL/100 g/min; P<0.05), along with decreases in fractional shortening (FS) (8.4+/-0.7 to 5.4+/-0.4%; P<0.05) and lactate extraction rate (LER) (-31.7+/-2.9 to -41.4+/-3.7%; P<0.05). The decrease in CBF was reproduced by the infusion of bovine serum albumin-conjugated aldosterone. Notably, these aldosterone-induced deteriorations of myocardial contractile and metabolic functions were blunted by the co-administration of GF109203X, an inhibitor of PKC, but not spironolactone. In addition, aldosterone activated vascular PKC. These results indicate that aldosterone nongenomically induces vasoconstriction via PKC-dependent pathways possibly through membrane receptors, which leads to the worsening of the cardiac contractile and metabolic functions in the ischemic hearts. Elevation of plasma or cardiac aldosterone levels may be deleterious to ischemic heart disease through its nongenomic effects.

Functional proteomic analysis of a three-tier PKCepsilon-Akt-eNOS signaling module in cardiac protection

Cardiac protective signaling networks have been shown to involve PKCepsilon. However, the molecular mechanisms by which PKCepsilon interacts with other members of these networks to form task-specific modules remain unknown. Among 93 different PKCepsilon-associated proteins that have been identified, Akt and endothelial nitric oxide (NO) synthase (eNOS) are of importance because of their independent abilities to promote cell survival and prevent cell death. The simultaneous association of PKCepsilon, Akt, and eNOS has not been examined, and, in particular, the formation of a module containing these three proteins and the role of such a module in the regulation of NO production and cardiac protection are unknown. The present study was undertaken to determine whether these molecules form a signaling module and, thereby, play a collective role in cardiac signaling. Using recombinant proteins in vitro and PKCepsilon transgenic mouse hearts, we demonstrate the following: 1) PKCepsilon, Akt, and eNOS interact and form signaling modules in vitro and in the mouse heart. Activation of either PKCepsilon or Akt enhances the formation of PKCepsilon-Akt-eNOS signaling modules. 2) PKCepsilon directly phosphorylates and enhances activation of Akt in vitro, and PKCepsilon activation increases phosphorylation and activation of Akt in PKCepsilon transgenic mouse hearts. 3) PKCepsilon directly phosphorylates eNOS in vitro, and this phosphorylation enhances eNOS activity. Activation of PKCepsilon in vivo increased phosphorylation of eNOS at Ser(1177), indicating eNOS activation. This study characterizes, for the first time, the physical, as well as functional, coupling of PKCepsilon, Akt, and eNOS in the heart and implicates these PKCepsilon-Akt-eNOS signaling modules as critical signaling elements during PKCepsilon-induced cardiac protection.

Bmx, a member of the Tec family of nonreceptor tyrosine kinases, is a novel participant in pharmacological cardioprotection

Previous studies have indicated that PKC-ε is a central regulator of protective signal transduction in the heart. However, the signaling modules through which PKC-ε exerts its protective effects have only begun to be understood. We have identified a novel participant in the PKC-ε signaling system in cardioprotection, the nonreceptor tyrosine kinase Bmx. Functional proteomic analyses of PKC-ε signaling complexes identified Bmx as a member of these complexes. Subsequent studies in rabbits have indicated that Bmx is activated by nitric oxide (NO) in the heart, concomitant with the late phase of NO donor-induced protection, and provide the first analysis of Bmx expression/distribution in the setting of cardioprotection. In addition, increased expression of Bmx induced by NO donors was blocked by the same mechanism that blocked cardioprotection: inhibition of PKC with chelerythrine. These findings indicate that a novel type of PKC-tyrosine kinase module (involving Bmx) is formed in the heart and may be involved in pharmacological cardioprotection by NO donors.

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.

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.

Opening of mitochondrial K(ATP) channel occurs downstream of PKC-epsilon activation in the mechanism of preconditioning

We examined whether the mitochondrial ATP-sensitive K channel (K(ATP)) is an effector downstream of protein kinase C-epsilon (PKC-epsilon) in the mechanism of preconditioning (PC) in isolated rabbit hearts. PC with two cycles of 5-min ischemia/5-min reperfusion before 30-min global ischemia reduced infarction from 50.3 +/- 6.8% of the left ventricle to 20.3 +/- 3.7%. PC significantly increased PKC-epsilon protein in the particulate fraction from 51 +/- 4% of the total to 60 +/- 4%, whereas no translocation was observed for PKC-delta and PKC-alpha. In mitochondria separated from the other particulate fractions, PC increased the PKC-epsilon level by 50%. Infusion of 5-hydroxydecanoate (5-HD), a mitochondrial K(ATP) blocker, after PC abolished the cardioprotection of PC, whereas PKC-epsilon translocation by PC was not interfered with 5-HD. Diazoxide, a mitochondrial K(ATP) opener, infused 10 min before ischemia limited infarct size to 5.2 +/- 1.4%, but this agent neither translocated PKC-epsilon by itself nor accelerated PKC-epsilon translocation after ischemia. Together with the results of earlier studies showing mitochondrial K(ATP) opening by PKC, the present results suggest that mitochondrial K(ATP)-mediated cardioprotection occurs subsequent to PKC-epsilon activation by PC.

Cardioprotective effect afforded by transient exposure to phosphodiesterase III inhibitors: the role of protein kinase A and p38 mitogen-activated protein kinase

BACKGROUND

Phosphodiesterase III inhibitors (PDEIII-Is) improve the hemodynamic status of heart failure via inotropic/vasodilatory effects attributable to the increase in intracellular cAMP level. Direct cardioprotection by PDEIII-Is and its underlying mechanisms, however, have not been identified. We tested the infarct size-limiting effect of PDEIII-Is and the roles of cAMP, protein kinase (PK) A, PKC, and mitogen-activated protein kinase (MAPK) families in open-chest dogs. Methods and Results-- Milrinone, olprinone (PDEIII-Is), or dibutyryl-cAMP (db-cAMP) was injected intravenously 30 minutes before 90-minute ischemia, followed by 6 hours of reperfusion. Olprinone was also examined with an intracoronary cotreatment with a PKA inhibitor (H89), a PKC inhibitor (GF109203X), an extracellular signal-regulated kinase kinase (MEK) inhibitor (PD98059), or a p38 MAPK inhibitor (SB203580) throughout the preischemic period. Either PDEIII-Is or db-cAMP caused substantial hemodynamic changes, which returned to control levels in 30 minutes. Collateral flow and percent risk area were identical for all groups. Both PDEIII-Is and db-cAMP increased myocardial p38 MAPK activity during the preischemic period, which was blocked by H89, but not by GF109203X. Both PDEIII-Is and db-cAMP reduced infarct size (19.1+/-4.1%, 17.5+/-3.3%, and 20.3+/-4.8%, respectively, versus 36.1+/-6.2% control, P<0.05 each). Furthermore, the effect of olprinone was blunted by either H89 (35.5+/-6.4%) or SB203580 (32.6+/-5.9%), but not by GF109203X or PD98059. H89, GF109203X, PD98059, or SB203580 alone did not influence infarct size.

CONCLUSIONS

Pretreatment with PDEIII-Is has cardioprotective effects via cAMP-, PKA-, and p38 MAPK-dependent but PKC-independent mechanisms in canine hearts.

Role of protein kinase C in the reduction of infarct size by N-methyl-1-deoxynojirimycin, an alpha-1,6-glucosidase inhibitor

Preischaemic treatment with N-methyl-1-deoxynojirimycin (MOR-14), an alpha-1,6-glucosidase inhibitor, attenuates glycogenolysis and lactate accumulation during ischaemia and markedly reduces infarct size in rabbit hearts. In the present study, we have investigated whether protein kinase C (PKC), a principal mediator of ischaemic preconditioning, is also involved in the cardioprotective effect of MOR-14. To assess the effect of PKC inhibition on infarct size in MOR-14-treated hearts, 38 rabbits were subjected to 30 min of ischaemia followed by 48 h of reperfusion. Infarct size, as a per cent of area at risk, was significantly smaller in rabbits administered 100 mg kg(-1) of MOR-14 10 min before ischaemia (17+/-2%, n=10), than in a control group (46+/-5%, n=10). This beneficial effect of MOR-14 was abolished when 5 mg kg(-1) of chelerythrine, a PKC inhibitor, was given 10 min prior to MOR-14 injection (39+/-4%, n=10), although chelerythrine alone did not alter infarct size (43+/-4%, n=8). Further, chelerythrine had no effect on MOR-14-induced attenuation of glycogen breakdown and lactate accumulation in hearts excised at 30 min of ischaemia. Immunoblot analysis of PKC in homogenates of Langendorff-perfused rabbit hearts revealed that MOR-14 significantly increased levels of PKC-epsilon in the particulate fraction at 20 and 30 min of ischaemia and in the cytosolic fraction at 30 min of ischaemia. Taken as a whole, our data suggest that PKC acts downstream of the inhibition of glycogenolysis by MOR-14 to reduce infarct size. Thus, activation of PKC is a more direct mediator of the cardioprotection afforded by MOR-14 than is inhibition of glycogenolysis.

Ischemic preconditioning upregulates vascular endothelial growth factor mRNA expression and neovascularization via nuclear translocation of protein kinase C epsilon in the rat ischemic myocardium

Ischemic preconditioning (IP) exerts cardioprotection through protein kinase C (PKC) activation, whereas myocardial ischemia enhances vascular endothelial growth factor (VEGF) mRNA expression. However, the IP effect or the involvement of PKC on the VEGF expression is unknown in myocardial infarction. We investigated whether IP enhances VEGF gene expression and angiogenesis through PKC activation in the in vivo myocardial infarction model. Sprague-Dawley rats were assigned into the following 3 groups: the sham group; the IP group, which underwent 3 cycles of 3 minutes of ischemia and 5 minutes of reperfusion (IP procedure); and the non-IP group. The latter 2 groups were subsequently subjected to left anterior descending coronary artery occlusion. To examine the involvement of PKC, the PKC inhibitor chelerythrine (5 mg/kg) or bisindolylmaleimide (1 mg/kg) was injected intravenously before the IP procedures. PKCepsilon was translocated to the nucleus after 10 minutes of ischemia after the IP procedure but was not translocated in the non-IP and the sham groups. VEGF mRNA expression 3 hours after infarction was significantly higher in the IP group than in the non-IP and the sham groups. Capillary density in the infarction was significantly higher, whereas the infarct size was smaller in the IP group than in the non-IP group at 3 days of infarction. Chelerythrine but not bisindolylmaleimide blocked all of the IP effects on the nuclear translocation of PKCepsilon, enhancement of VEGF mRNA expression and angiogenesis, and infarct size limitation. These results show that IP may enhance VEGF gene expression and angiogenesis through nuclear translocation of PKCepsilon in the infarcted myocardium.

Adenosine 5'-triphosphate: a P2-purinergic agonist in the myocardium

ATP, besides an intracellular energy source, is an agonist when applied to a variety of different cells including cardiomyocytes. Sources of ATP in the extracellular milieu are multiple. Extracellular ATP is rapidly degraded by ectonucleotidases. Today ionotropic P2X(1--7) receptors and metabotropic P2Y(1,2,4,6,11) receptors have been cloned and their mRNA found in cardiomyocytes. On a single cardiomyocyte, micromolar ATP induces nonspecific cationic and Cl(-) currents that depolarize the cells. ATP both increases directly via a G(s) protein and decreases Ca(2+) current. ATP activates the inward-rectifying currents (ACh- and ATP-activated K(+) currents) and outward K(+) currents. P2-purinergic stimulation increases cAMP by activating adenylyl cyclase isoform V. It also involves tyrosine kinases to activate phospholipase C-gamma to produce inositol 1,4,5-trisphosphate and Cl(-)/HCO(3)(-) exchange to induce a large transient acidosis. No clear correlation is presently possible between an effect and the activation of a given P2-receptor subtype in cardiomyocytes. ATP itself is generally a positive inotropic agent. Upon rapid application to cells, ATP induces various forms of arrhythmia. At the tissue level, arrhythmia could be due to slowing of electrical spread after both Na(+) current decrease and cell-to-cell uncoupling as well as cell depolarization and Ca(2+) current increase. In as much as the information is available, this review also reports analog effects of UTP and diadenosine polyphosphates.

Overexpression of FGF-2 increases cardiac myocyte viability after injury in isolated mouse hearts

We generated transgenic (TG) mice overexpressing fibroblast growth factor (FGF)-2 protein (22- to 34-fold) in the heart. Chronic FGF-2 overexpression revealed no significant effect on heart weight-to-body weight ratio or expression of cardiac differentiation markers. There was, however, a significant 20% increase in capillary density. Although there was no change in FGF receptor-1 expression, relative levels of phosphorylated c-Jun NH(2)-terminal kinase and p38 kinase as well as of membrane-associated protein kinase C (PKC)-alpha and total PKC-epsilon were increased in FGF-2-TG mouse hearts. An isolated mouse heart model of ischemia-reperfusion injury was used to assess the potential of increased endogenous FGF-2 for cardioprotection. A significant 34-45% increase in myocyte viability, reflected in a decrease in lactate dehydrogenase released into the perfusate, was observed in FGF-2 overexpressing mice and non-TG mice treated exogenously with FGF-2. In conclusion, FGF-2 overexpression causes augmentation of signal transduction pathways and increased resistance to ischemic injury. Thus, stimulation of endogenous FGF-2 expression offers a potential mechanism to enhance cardioprotection.

Modification by arachidonic acid of extracellular adenosine metabolism and neuromodulatory action in the rat hippocampus

Adenosine and arachidonate (AA) fulfil opposite modulatory roles, arachidonate facilitating and adenosine inhibiting cellular responses. To understand if there is an inter-play between these two neuromodulatory systems, we investigated the effect of AA on extracellular adenosine metabolism in hippocampal nerve terminals. AA (30 microm) facilitated by 67% adenosine evoked release and by 45% ATP evoked release. These effects were not significantly modified upon blockade of lipooxygenase or cyclooxygenase and were attenuated (52-61%) by the protein kinase C inhibitor, chelerythrine (6 microm). The ecto-5'-nucleotidase inhibitor, alpha,beta-methylene ADP (100 microm), caused a larger inhibition (54%) of adenosine release in the presence of AA (30 microm) compared with control (37% inhibition) indicating that the AA-induced extracellular adenosine accumulation is mostly originated from an increased release and extracellular catabolism of ATP. This AA-induced extracellular adenosine accumulation is further potentiated by an AA-induced decrease (48%) of adenosine transporters capacity. AA (30 microm) increased by 36-42% the tonic inhibition by endogenous extracellular adenosine of adenosine A(1) receptors in the modulation of acetylcholine release and of CA1 hippocampal synaptic transmission in hippocampal slices. These results indicate that AA increases tonic adenosine modulation as a possible feedback loop to limit AA facilitation of neuronal excitability.

Adenosine therapy: a new approach to chronic heart failure

Both the prevention and attenuation of chronic heart failure (CHF) are important issues for cardiologists. There are three different strategies to prevent patients from deleterious sequels. The first strategy is to remove the causes of CHF if possible; the second is to attenuate the events that may lead to CHF, such as myocardial ischaemia and reperfusion injury, cardiomyopathy and myocarditis, cardiac hypertrophy and ventricular remodelling; the third is to prevent or attenuate the progression of CHF. Adenosine has a number of actions which merit it as a possible cardioprotective and therapeutic agent for CHF. Firstly, adenosine induces collateral circulation via inducing growth factors and triggering ischaemic preconditioning, both of which induce ischaemic tolerance in advance. Adenosine is also known to reduce the release of noradrenaline, production of endothelin and attenuate the activation of renin-angiotensin system all of which are believed to cause cardiac hypertrophy and remodelling. Secondly, exogenous adenosine is known to reduce the severity of ischaemia and reperfusion injury. Thirdly, adenosine is reported to counteract neurohumoral factors, i.e., cytokine systems, known to be related to the pathophysiology of CHF. Recently, we revealed that adenosine metabolism is changed in patients with CHF and increases in adenosine levels may aid to reduce the severity of CHF. Thus, there are many potential mechanisms for cardioprotection attributable to adenosine and we postulate the use of adenosine therapy will be beneficial in patients with CHF.

Protein tyrosine kinase is not involved in the infarct size-limiting effect of ischemic preconditioning in canine hearts

Protein kinase C (PKC) plays an important role in ischemic preconditioning (IP). Because (1) tyrosine kinase is located at the downstream of PKC for IP in the rabbit hearts and (2) we have reported that ecto-5'-nucleotidase is the substrate for PKC and plays a crucial role for the infarct size-limiting effect, we tested whether tyrosine kinase activation contributes to either activation of ecto-5'-nucleotidase or the infarct size-limiting effect of the early phase of IP in the canine heart. In dogs, the IP procedure (4 cycles of 5-minute occlusion of coronary artery) and exposure to 12, 13-phorbol myristate acetate (PMA) each activated myocardial ecto-5'-nucleotidase and Lck tyrosine kinase. Genistein (10, 30, and 100 microg. kg(-)(1). min(-)(1) IC), an inhibitor of tyrosine kinase, attenuated the activation of Lck tyrosine kinase but did not attenuate the activation of ecto-5'-nucleotidase due to either IP or PMA. In the other canine hearts, IP attenuated infarct size (49+/-5 versus 11+/-3 or 16+/-3%, P<0.01) due to 90 minutes of coronary occlusion followed by 6 hours of reperfusion, which was not blunted by 3 or 2 (30 and 100 microg. kg(-)(1). min(-)(1)) doses of genistein (infarct sizes, 15+/-4, 13+/-4, and 13+/-3%, respectively, and 17+/-3 and 15+/-4%, respectively) or lavendustin A. Tyrosine kinase does not activate ecto-5'-nucleotidase or trigger the infarct size-limiting effect of the early phase of IP in canine hearts.

Is adenosine preconditioning truly cardioprotective in coronary artery bypass surgery?

BACKGROUND

The large number of experimental studies showing that adenosine "turns on" the protein kinase C (PKC)-mediated pathway that accounts for the cardioprotection conferred by ischemic preconditioning contrasts with the scarcity of clinical data documenting the preconditioning-like protective effect of adenosine during cardiac operations on humans.

METHODS

Forty-five patients undergoing coronary artery bypass were randomized to receive, after the onset of cardiopulmonary bypass, a 5-minute infusion of adenosine (140 microg x kg(-1) x min(-1)) followed by 10 minutes of washout before cardioplegic arrest (n = 23) or an equivalent period (15 minutes) of prearrest drug-free bypass (controls, n = 22). Outcome measurements included troponin I release over the first 48 postoperative hours and activity of ecto-5'-nucleotidase, an admitted reporter of PKC activation, as assessed on right atrial biopsies taken before bypass and at the end of the preconditioning protocol (or after 15 minutes of bypass in control patients).

RESULTS

Aortic cross-clamping times were not different between the two groups. Likewise, prebypass values of ecto-5'-nucleotidase (nanomoles/mg protein per minute) were similar in control (3.14+/-1.02) and adenosine-treated (2.66+/-1.08) patients. They subsequently remained unchanged in control patients (3.87+/-1.65) whereas they significantly increased after adenosine preconditioning (4.47+/-1.96, p<0.001 versus base line values). However, peak postoperative values of troponin I (microg/L) were not significantly different between control (4.8+/-2.8) and adenosine-preconditioned patients (5.9+/-6.6) nor were the areas under the curve. There were no adverse effects related to adenosine.

CONCLUSIONS

Adenosine, given at a clinically safe dose, can turn on the PKC-mediated signaling pathway involved in preconditioning but this biochemical event does not translate into reduced cell necrosis after coronary artery surgery, suggesting that a preconditioning-like protocol may not be the best suited for exploiting the otherwise well-documented cardioprotective effetcs of adenosine.

Relationship between free radicals and adenosine in the mechanism of preconditioning: are they interrelated or independent triggers?

Both free radicals (FRs) and adenosine receptor activation contribute to triggering a mechanism of preconditioning (PC) against infarction. This study examined the possibility that there is some interaction between FRs and adenosine generation during PC. In the first series of experiments, the effects of an FR scavenger, N-2-mercaptopropionyl glycine (MPG), on the interstitial adenosine level during PC and on the infarct size-limiting effect of PC were assessed in the rabbit heart in situ. PC with 5-min ischemia/5-min reperfusion limited infarct size after 30-min coronary occlusion (expressed as a percentage of area at risk, %IS/AR) from 33.2 +/- 4.7% (S.E.) to 10.8 +/- 1.1% (p < 0.05). This cardioprotection was blocked by MPG (1.5 mg/kg/min i.v.) infused before and during PC (%IS/AR = 27.4 +/- 3.6). However, the same dose of MPG did not suppress elevation of the adenosine and inosine levels in the microdialysate from the myocardium during 5-min ischemia/reperfusion. In the second series of experiments, the effect of an FR-generating system (1 mM hypoxanthine and 20 mU/ml xanthine oxidase) on the purine production was compared to that of PC in isolated rabbit hearts. Whereas PC increased the adenosine level in the coronary effluent from 0.17 +/- 0.16 microM under baseline to 1.68 +/- 0.53 microM, infusion of the FR generators over a period of 5 min did not increase the adenosine release. However, infarct size was similarly reduced by PC and by 5-min transient infusion of FR generators, and the cardioprotection by the FR generators was abolished by 300 microM MPG. These results suggest that there is no interaction between free radicals and adenosine during the trigger phase of PC in the rabbit heart.

It is time to ask what adenosine can do for cardioprotection

Prevention and attenuation of ischemia and reperfusion injury in patients with acute coronary syndrome are critically important for cardiologists. To save these patients from deleterious ischemic insults, there are three different strategies. The first strategy is to increase ischemic tolerance before the onset of myocardial ischemia; the second is to attenuate the ischemia and reperfusion injury when an irreversible process of myocardial cellular injury occurs; the third is to treat the ischemic chronic heart failure that is caused by acute myocardial infarction. Adenosine, which is known to be cardioprotective against ischemia and reperfusion injury, may merit being used for these three cardioprotection strategies. First of all, adenosine induces collateral circulation via induction of growth factors, and triggers ischemic preconditioning, both of which induce ischemic tolerance in advance. Secondly, endogenous adenosine may mediate the infarct size-limiting effect of ischemic preconditioning, and exogenous adenosine is known to attenuate ischemia and reperfusion injury. Thirdly, we also revealed that adenosine metabolism is changed in patients with chronic heart failure, and increases in adenosine levels may attenuate the severity of ischemic heart failure. Therefore, adenosine therapy may improve the pathophysiology of ischemic chronic heart failure. Taking these factors together, we hereby propose potential tools for cardioprotection attributable to adenosine in ischemic hearts, and we postulate the use of adenosine therapy before, during, and after the onset of acute myocardial infarction.

Cellular mechanisms of infarct size reduction with ischemic preconditioning. Role of calcium?

Brief episodes of ischemia protect or "precondition" the heart and reduce infarct size caused by a subsequent sustained ischemic insult. Despite a decade of intensive investigation, the cellular mechanism(s) responsible for this paradoxical protection remain poorly understood. In this review, we focus on the emerging concept that alterations in intracellular calcium homeostasis may participate in either triggering and/or mediating infarct size reduction with preconditioning.

Role of ecto-kinase in phorbol ester-enhanced growth hormone-binding protein release from human IM-9 cells

Previously we reported that a phorbol ester, phorbol 12, 13-dibutyrate (PDBu), increased the release of human growth hormone-binding protein (hGH-BP) in IM-9 cells, and that this phorbol ester-enhanced release was mediated by protein kinase Ca (PKCalpha). In the present study, the mechanisms of the phorbol ester-enhanced hGH-BP release were further investigated. Treatment of IM-9 cells with PDBu did not increase hGH-BPs (55-60 kDa) in the intracellular soluble fraction. When the cells were treated with trypsin to remove human growth hormone receptors (hGHRs) on the cell surface after stimulation, no hGH-BPs were detected in the culture supernatants, nor did treatment with bafilomycin A1 or chloroquine affect the PDBu-enhanced hGH-BP release. These results suggest that hGH-BPs released by PDBu stimulation are derived from cell surface hGHRs and not generated within the cells. Protein kinase inhibitors with broad specificities, K-252a and K-252b, inhibited the PDBu-enhanced release with almost the same dose-dependency, although only a trace amount of K-252b was incorporated into IM-9 cells than K-252a, suggesting that K-252b probably inhibits an ecto-kinase extracellularly. PDBu actually enhanced the phosphorylation of several extracellular proteins, and this enhanced phosphorylation was completely inhibited by K-252b treatment. Moreover, the PKCalpha-specific inhibitor bisindolylmaleimide III which inhibits PDBu enhanced hGH-BP release inhibited the PDBu-enhanced phosphorylation of extracellular proteins. On the other hand, the impermeable PKC inhibitor PKC inhibitor peptide 19-31 did not inhibit PDBu-enhanced release, suggesting that the target PKCalpha for PDBu is not present on the extracellular surface. Taken together, these results suggest that, in addition to intracellular PKCalpha, activation of an undefined ecto-kinase may also be involved in the PDBu-enhanced hGH-BP release.

Adenosine and cardioprotection in the diseased heart

Biological and mechanical stressors such as ischemia, hypoxia, cellular ATP depletion, Ca2+ overload, free radicals, pressure and volume overload, catecholamines, cytokines, and renin-angiotensin may independently cause reversible and/or irreversible cardiac dysfunction. As a defense against these forms of stress, several endogenous self-protective mechanisms are exerted to avoid cellular injury. Adenosine, a degradative substance of ATP, may act as an endogenous cardioprotective substance in pathophysiological conditions of the heart, such as myocardial ischemia and chronic heart failure. For example, when brief periods of myocardial ischemia precede sustained ischemia, infarct size is markedly limited, a phenomenon known as ischemic preconditioning. We found that ischemic preconditioning activates the enzyme responsible for adenosine release, ie, ecto-5'-nucleotidase. Furthermore, the inhibitor of ecto-5'-nucleotidase reduced the infarct size-limiting effect of ischemic preconditioning, which establishes the cause-effect relationship between activation of ecto-5'-nucleotidase and the infarct size-limiting effect. We also found that protein kinase C is responsible for the activation of ecto-5'-nucleotidase. Protein kinase C phosphorylated the serine and threonine residues of ecto-5'-nucleotidase. Therefore, we suggest that adenosine produced via ecto-5'-nucleotidase gives cardioprotection against ischemia and reperfusion injury. Also, we found that plasma adenosine levels are increased in patients with chronic heart failure. Ecto-5'-nucleotidase activity increased in the blood and the myocardium in patients with chronic heart failure, which may explain the increases in adenosine levels in the plasma and the myocardium. In addition, we found that further elevation of plasma adenosine levels due to either dipyridamole or dilazep reduces the severity of chronic heart failure. Thus, we suggest that endogenous adenosine is also beneficial in chronic heart failure. We propose potential mechanisms for cardioprotection attributable to adenosine in pathophysiological states in heart diseases. The establishment of adenosine therapy may be useful for the treatment of either ischemic heart diseases or chronic heart failure.