Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:2.7.11.13 (protein kinase C)
49,245 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Rabbit hearts were preconditioned with four 5 min coronary artery occlusions 24 h before 30 min coronary occlusion with 120 min reperfusion. Preconditioning significantly reduced the percentage of myocardium infarcting within the risk zone from 49.1 +/- 4.3% to 31.8 +/- 3.5% (P < 0.05). When the protein kinase C (PKC) inhibitor, chelerythrine, was administered just before preconditioning, the delayed protection against infarction 24 h later was abolished. We conclude that the delayed cytoprotective response associated with ischaemic preconditioning of myocardium is likely to involve the early activation of one or more PKC subtypes.
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PMID:Involvement of protein kinase C in the delayed cytoprotection following sublethal ischaemia in rabbit myocardium. 754 15

The present study investigated whether protein kinase C (PKC) plays a role in ischemic preconditioning in the rat heart. Chelerythrine, a specific antagonist of PKC, and 1,2-dioctanoyl-sn-glycerol (DOG), a diacylglycerol analogue and specific antagonist of PKC, were used to determine whether preconditioning could be blocked or triggered, respectively. Sprague-Dawley rats were anesthetized and instrumented for coronary occlusion and reperfusion. All animals were subjected to 45 minutes of regional ischemia (ISC) followed by 2.5 hours of reperfusion. The preconditioning protocol consisted of 5 minutes of ischemia and then 10 minutes of reperfusion. There were six groups: (1) control (group C, n = 5), (2) preconditioned and ISC (group PC, n = 6), (3) chelerythrine given 2 minutes before ISC (group CC, n = 5), (4) preconditioned and chelerythrine given 2 minutes before ISC (group PCC, n = 6), (5) DOG (dissolved in dimethylsulfoxide [DMSO]) given 10 minutes before ISC (group CD, n = 5), and (6) DMSO given 10 minutes before ISC (group DMSO, n = 3). The end point was infarct size measured using triphenyl tetrazolium chloride and expressed as a percentage of the volume at risk (I/R), measured with fluorescent particles. I/R was significantly reduced by preconditioning (group C, 58.6 +/- 5.0%; group PC, 32.7 +/- 6.3%; P < .01) and by the PKC agonist DOG, which reduced I/R to a similar extent as preconditioning (group C, 58.6 +/- 5.0%; group CD, 28.0 +/- 7.0%; P < .01).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Protein kinase C. Its role in ischemic preconditioning in the rat. 806 29

Short periods of ischemia render the myocardium more resistant to a subsequent prolonged coronary occlusion resulting in a reduction of infarct size. This cardioprotective mechanism has been called ischemic preconditioning. Acute myocardial ischemia results in a rapid decline of high energy phosphates. After short periods of ischemia the high energy phosphate levels are better preserved and the increase of lactate is slower during the prolonged subsequent ischemia in the preconditioned group compared to control. The duration of ischemia needed for induction of the protective effect is 2.5 min in dogs and 20 min in our swine model. In porcine myocardium the protection is lost about 1 h after induction and a renewal is not possible at that time, but is 24 h later. For rabbits or dogs, but not in pigs, a late protection 24 h after induction or preconditioning has been shown ("second window of protection"). Adenosine or adenosine A1 receptor agonists, muscarinic M2 receptor agonists, alpha 1-receptor agonists and bradykinin B2 receptor agonists as well as opening of the K+ATP-channel substitute for ischemia in the induction of protection. Activation of protein kinase C results in protection in rats and rabbits, but not in dogs or pigs. Inhibition of protein kinase C translocation or kinase activity results in a loss of the protection induced by preceding ischemia. After blockade of the K+ATP-channel the protection induced by adenosine A1 receptor activation is lost. Therefore opening of the K+ATP-channel is a prerequisite for induction of the protective effect. Inhibition of the inhibitory G-protein by pertussis toxin has been shown to result in a loss of protection, therefore the Gi-protein seems to be involved in the evolution of protection. In humans during coronary angioplasty anginal pain and lactate production during a second balloon occlusion is diminished without any change in the regional myocardial perfusion. This adaptation is inhibited by blockade of the K+ATP-channel or of the adenosine A1 receptor. Intermittent cross-clamping before a longer occlusion during open-heart surgery results in a better preservation of high energy phosphates compared to controls without preceding short ischemia. These observations support the hypothesis that ischemic preconditioning also occurs in humans. Angina pectoris preceding the myocardial infarction may have preconditioned the human heart against the subsequent myocardial infarction, but studies concerning the influence of angina pectoris on short-term outcome after thrombolysis are conflicting. In the future, ischemic preconditioning or preconditioning with drugs may prolong the duration of ischemia tolerated without necrosis and improve the prognosis of patients by reducing the infarct size.
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PMID:-Myocardial protection by preconditioning. Experimental and clinical significance-. 865 Sep 86

Indirect evidence suggests that oxygen radicals may contribute to ischemic preconditioning. We directly investigated whether exposure to oxygen radicals per se, in the absence of ischemia, could reproduce the beneficial effects of ischemic preconditioning on infarct size and on postischemic contractile dysfunction. In one branch of the study, isolated rabbit hearts underwent 30 minutes of total global ischemia and 45 minutes of reperfusion (n=6, control group). A second group, before ischemia/reperfusion, was exposed for 5 minutes to a low flux of oxygen radicals generated by purine/xanthine oxidase (P/XO), followed by a 15-minute washout (n=6). Oxygen radical pretreatment significantly improved postischemic recovery of contractile function. We then investigated in another branch of the study whether this preconditioning effect would also reduce infarct size and whether it was mediated by protein kinase C activation. Control hearts were subjected to coronary artery occlusion for 30 minutes, followed by 2.5 hours of reperfusion (n=6). A second group, before coronary occlusion, was exposed to oxygen radicals and washout as described (n=8). A third group was subjected to oxygen radical infusion, but an inhibitor of protein kinase C (polymyxin B, 50 micromol/L) was administered throughout subsequent ischemia (n=7). A fourth group was exposed to oxygen radicals in the presence of scavengers (superoxide dismutase, 250 U/mL; catalase 500, U/mL; n=8). Pretreatment with oxygen radicals markedly reduced infarct size, from 65+/-19% of risk region in controls to 12+/-4% (P<.05). Protein kinase C inhibition significantly attenuated this effect (infarct size, 37+/-9% of risk region; P<.05 versus P/XO; P=NS versus controls). Oxygen radical-induced preconditioning was prevented by scavengers (infarct size, 55+/-14% of risk region; P<.05 versus P/XO; P=NS versus P/XO+polymyxin B). Our data show that in the absence of ischemia, exposure to low concentrations of oxygen radicals can reproduce the beneficial effects of ischemic preconditioning on infarct size and postischemic recovery of left ventricular function. Thus, oxygen radicals might be potential contributors to ischemic preconditioning.
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PMID:Oxygen radicals can induce preconditioning in rabbit hearts. 913 Apr 55

The protection of ischemic preconditioning (PC) appears to be triggered by activation of receptors which couple to protein kinase C (PKC) during the brief ischemia. Previous experiments, however, suggest that phosphorylation of PKC's substrates is not required for the myocytes to enter the preconditioned state. Because of the fundamental importance of this observation, the present study was designed to stringently test when phosphorylation must occur during a PC protocol. We used an in vitro rabbit heart which permitted precise control of the timing of exposure to staurosporine (STA), a reversible blocker of PKC's kinase activity. In control hearts a 30-min regional coronary occlusion followed by 2 h of reperfusion resulted in 31.4 +/- 1.5% infarction of the region at risk, and STA (100 nM) had little effect. PC with 5 min of global ischemia and 10 min of reperfusion reduced infarction to 11.4% (P < 0.01 v control). STA starting 5 min before and ending 5 min after the 5-min PC ischemia did not block protection (14.1 +/- 1.7% infarction, P < 0.01 v control). When the PC protocol was changed to 5 min ischemia/20 min reperfusion, STA still could not block protection even though the infusion continued for 15 min after the PC ischemia. However, when a 15-min STA infusion was initiated 5 min before the 30-min ischemic period. PC's protection was totally blocked. Moreover this late infusion of STA continued to block protection even when the PC stimulus was amplified by three cycles of 5-min ischemia/10-min reperfusion. These observations indicate that kinase activity is not required to put the rabbit heart into a preconditioned state suggesting that some process upstream of PKC's kinase is responsible for the triggering and memory of PC.
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PMID:Protection of ischemic preconditioning is dependent upon a critical timing sequence of protein kinase C activation. 915 60

To examine the cardioprotective role of A3 adenosine receptors during myocardial ischemia/reperfusion injury, we tested the effect of N6-(3-iodobenzyl)adenosine-5'-N-methyluronamide (IB-MECA), a potent and selective A3 adenosine receptor agonist, in models of myocardial stunning and infarction in chronically instrumented conscious rabbits. In phase I (studies of myocardial stunning), rabbits were subjected to six 4-minute coronary occlusions, each separated by 4-minute reperfusion periods, after which the recovery of systolic wall thickening was measured (ultrasonic crystals). In phase II (studies of myocardial infarction), rabbits were subjected to a 30-minute coronary occlusion followed by 3 days of reperfusion. In both phases, IB-MECA was administered as an intravenous bolus (100 micrograms/kg) 10 minutes before the first coronary occlusion. This dose of IB-MECA was determined in pilot studies to have no effect on heart rate, arterial blood pressure, or plasma histamine concentration in rabbits. In phase I, IB-MECA markedly improved the recovery of wall thickening after the six occlusion/reperfusion cycles, and this effect was sustained throughout the 5-hour observation period; the total deficit of wall thickening (a measure of the overall severity of myocardial stunning) was reduced by 68% (control, 129 +/- 16 arbitrary units, n = 7; IB-MECA, 41 +/- 6 arbitrary units, n = 6; P < .01). The protective effects of IB-MECA against stunning were completely blocked by pretreatment with the nonselective adenosine receptor antagonist 8-p-sulfophenyl theophylline or the specific protein kinase C inhibitor chelerythrine. In phase II, IB-MECA reduced myocardial infarct size by 61%; infarct size (tetrazolium staining) was 41 +/- 4% of the risk region in control animals (n = 8) and 16 +/- 6% in IB-MECA-treated animals (n = 8, P < .01). These results demonstrate that in conscious rabbits the A3 adenosine receptor agonist IB-MECA confers a powerful protection against both reversible (stunning) and irreversible (infarction) injury during acute myocardial ischemia and reperfusion by a protein kinase C-mediated pathway, suggesting that selective activation of A3 receptors is an effective means of protecting the ischemic myocardium without hemodynamic changes.
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PMID:Selective activation of A3 adenosine receptors with N6-(3-iodobenzyl)adenosine-5'-N-methyluronamide protects against myocardial stunning and infarction without hemodynamic changes in conscious rabbits. 916 82

We have previously reported a delayed or "second window of protection" against infarction 24-72 h after ischemic preconditioning in the rabbit. This phenomenon has also been associated with the protein kinase C signalling pathway. In the present study, we expanded our investigation to ascertain whether protein tyrosine kinase was in any way associated with this phenomenon in the rabbit heart. We found that 48 h after ischemic preconditioning with 4x5 min coronary occlusions the percentage of myocardium infarcting within the risk zone following a 30-min coronary occlusion and 120-min reperfusion (I/R) was reduced from 39. 6+/-3.3% to 18.0+/-3.7% (P<0.01). However, an i.v. bolus administration of genistein (5 mg/kg), a tyrosine kinase inhibitor, 5 min before ischemic preconditioning stimulus, abolished this protection (I/R=39.0+/-3.4%). Genistein per se had no significant effect on infarction 48 h later. Risk zone volume after coronary ligation was not significantly different between intervention groups. There were no differences in hemodynamic parameters between groups throughout the experimental period. We conclude that the second window of protection, 48 h after preconditioning, is mediated by tyrosine kinase activation in the rabbit heart.
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PMID:Genistein, a tyrosine kinase inhibitor, blocks the "second window of protection" 48 h after ischemic preconditioning in the rabbit. 923 42

Previous work suggests that delayed protection against infarction following ischaemic preconditioning of rabbit myocardium may involve the activation of protein kinase C (PKC). Preconditioning in the presence of chelerythrine, an inhibitor of PKC, abolished the late anti-infarct effect of preconditioning. In the studies described here, we tested the hypothesis that direct PKC activation with an analogue of diacylglycerol, the physiological activator of PKC, would invoke an adaptive mechanism leading to enhanced myocardial tolerance to ischaemia 24 h later. Rabbits were treated with i.v. injections of 1,2-dioctanoyl-sn-glycerol (DiC8) 5 mg/kg or 15 mg/kg or an equivalent volume of vehicle solution. Twenty-four h after pretreatment, the animals were anaesthetised and underwent 30 min coronary artery occlusion with 120 min reperfusion. Infarct size was determined by triphenyltetrazolium staining. In vehicle pretreated rabbits, infarct-risk zone ratio was 32.8+/-2.6%. Pretreatment with DiC8 5 mg/kg did not significantly affect infarct size (26.3+/-4.0%), but pretreatment with DiC8 15 mg/kg resulted in a marked reduction in infarct size (18.0+/-3.4%, P<0.05, 1-way ANOVA). Reduction in infarct size with the higher dose of DiC8 was independent of myocardial risk zone size and systemic haemodynamic parameters during coronary occlusion. The haemodynamic effects of acute administration of DiC8 15 mg/kg were examined in a separate cohort of pentobarbitone-anaesthetised rabbits. The compound was found not to affect systolic blood pressure or heart rate under these conditions. We examined the possibility that increased ischaemic tolerance might be due to induction of the 27 and 72 kDa heat shock proteins (hsp27 and hsp70i) which are known to be cytoprotective and are upregulated by ischaemia and other stressful stimuli. Western blot analysis of left ventricular tissue revealed that neither protein was induced 24 h after treatment with DiC8 15 mg/kg. Thus, infarct limitation 24 h after DiC8 treatment did not appear to be due to increased tissue content of these proteins. The mechanisms of DiC8-induced delayed myocardial protection remain unclear. However, these data are compatible with the hypothesis that activation of PKC isoenzymes is an important intermediate signal of sub-acute cellular adaptation, and results in enhanced tolerance to ischaemia-reperfusion injury in myocardium many hours later.
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PMID:Attenuation of myocardial ischaemic injury 24 h after diacylglycerol treatment in vivo. 923 50

Considerable controversy surrounds the role of protein kinase C (PKC) in ischemic preconditioning (PC). Previous studies have used pharmacological agents and/or measured total myocardial PKC activity; however, no information is available regarding the effects of PC on individual isoforms in vivo. We performed a comprehensive evaluation (using Western immunoblotting) of the expression and subcellular distribution of all 11 currently known PKC isoforms in the heart of conscious rabbits subjected to four different ischemic PC protocols known to induce early and/or late PC (one, three, or six cycles of 4-minute coronary occlusion [4'O]/4-minute reperfusion [4'R]; four cycles of 5-minute occlusion [5'O]/10-minute reperfusion [10'R]). Ten PKC isoforms (alpha, beta1/beta2, gamma, delta, epsilon, zeta, eta, iota, lambda, and mu) were found to be expressed in the rabbit heart. Quantitative immunoblotting demonstrated that as a subgroup, conventional PKCs (cPKCs) are more abundant than novel PKCs (nPKCs) (1445 versus 313 pg PKC/microg tissue protein, respectively) and that PKC alpha is the predominant isoform among the cPKCs (alpha, beta1, beta2, and gamma), representing 51% of this subgroup, and PKC epsilon is the most abundant among the nPKCs (delta, epsilon, zeta, and eta), accounting for 62% of this subgroup. None of the ischemic PC protocols examined caused appreciable changes in total PKC activity, in the subcellular distribution of total PKC activity, or in the subcellular distribution of PKC isoforms alpha, beta1/beta2, gamma, delta, zeta, iota, lambda, and mu. In contrast, all PC protocols caused significant translocation of PKC epsilon and PKC eta isoforms from the cytosolic to the particulate fraction. The particulate fraction of PKC epsilon increased in a dose-dependent fashion with the number of occlusion/reperfusion cycles performed, from 35+/-2% in the control group to 43+/-2% after one 4'O/5-minute reperfusion (5'R) cycle (P<.05), 52+/-2% after three cycles (P<.05 versus one cycle), and 66+/-3% after six cycles (P<.05 versus three cycles). The particulate fraction of PKC epsilon also increased, after four 5'O/10'R cycles, to 50+/-3% (P<.05 versus control). In contrast to PKC epsilon, the translocation of PKC eta was independent of the number of occlusion/reperfusion cycles performed. The particulate fraction of PKC eta increased from 67+/-3% in the control group to 84+/-2% after one 4'O/5'R cycle (P<.05), 84+/-2% after three 4'O/4'R cycles (P<.05), 86+/-3% after six 4'O/4'R cycles (P<.05), and 83+/-2% after four 5'O/10'R cycles (P<.05). When expressed as a percentage of control values, the increases in the particulate fraction of isoform epsilon were greater than those of isoform eta. The effects of 4'O without reperfusion were similar to those of one cycle of 4'O/5'R, indicating that 5'R did not attenuate isoform translocation. This is the first study to demonstrate PKC translocation after ischemic PC in vivo. The results indicate that in the conscious rabbit, ischemic PC causes selective translocation of the epsilon and eta isoforms without demonstrable changes in total myocardial PKC activity, implying that measurements of total PKC activity are not sufficiently sensitive to detect the involvement of PKC in PC. The results are consistent with the concept that the epsilon and eta isozymes play an important role in the genesis of ischemic PC in the conscious rabbit.
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PMID:Ischemic preconditioning induces selective translocation of protein kinase C isoforms epsilon and eta in the heart of conscious rabbits without subcellular redistribution of total protein kinase C activity. 928 43

We have reported that activation of protein kinase C (PKC) increases ecto-5'-nucleotidase activity, which may contribute to the infarct size-limiting effect of ischemic preconditioning. Since we have reported that Ca(2+)- and phospholipid-sensitive PKC is activated due to ischemic preconditioning, we further tested 1) whether PKC-alpha or -beta is translocated to the cellular membrane of the preconditioned canine myocardium, and 2) whether activation of PKC contributes to the increase in ecto-5'-nucleotidase activity via phosphorylation-dependent mechanisms. Four times of 5 minutes coronary occlusion separated by 5 minutes of reperfusion (ischemic preconditioning) translocated PKC-alpha to the cellular membrane in the canine hearts, although PKC-beta, -delta, -epsilon, and -zeta were not translocated. The activity of Ca(2+)- and phospholipid-sensitive PKC increased, which was attenuated by the removal of either Ca2+ or phosphatidylserine. Ecto-5'-nucleotidase was also activated in the preconditioned myocardium compared with control. Inhibition of PKC due to GF109203X blunted the activation of myocardial ecto-5'-nucleotidase. Okadaic acid (an inhibitor of phosphatase) enhanced the increases in ecto-5'-nucleotidase activity due to preconditioning, and this enhancement was blunted by GF109203X. We conclude that ischemic preconditioning activates PKC-alpha, and thus ecto-5'-nucleotidase.
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PMID:Role of protein kinase C-alpha in activation of ecto-5'-nucleotidase in the preconditioned canine myocardium. 934 90


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