Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:2.7.11.13 (protein kinase C)
 49,245 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Modulation of ion channels is an essential step for understanding the regulation of cellular functions. 1,4-Dihydropyridines (nitrendipine, nifedipine, PN 200-110, etc.) are potent inhibitors of voltage-dependent calcium channels and are important therapeutic agents in the treatment of various cardiovascular disorders such as angina and cardiac arrhythmias. In this work a new procedure is employed to determine the density of surface dihydropyridine receptors in contracting muscle cells in culture. Activation of endogenous protein kinase C (the Ca2+/phospholipid-dependent enzyme) by the tumor promoter phorbol-12-myristate or 1-oleoyl-2-acetylglycerol enhanced the number of dihydropyridine receptors without significant change in the receptor affinity. The increase in the number of receptors was associated with stimulation of the dihydropyridine-sensitive 45Ca uptake as well as activation of protein kinase C in myotubes treated with phorbol esters. These data strongly suggest that activation of protein kinase C promotes the appearance of dihydropyridine receptors in the plasma membrane.
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PMID:Modulation of [3H]dihydropyridine receptors by activation of protein kinase C in chick muscle cells. 243 14

Direct clinical evidence for the classical preconditioning phenomenon, with infarct size limitation as an endpoint, cannot be obtained. However, a number of patient groups have been identified in which adaptation to ischaemia has been demonstrated by enhanced recovery of function or preservation of high energy phosphates in models of repeated ischaemia, such as atrial pacing stress tests, percutaneous transluminal coronary angioplasty and aortic cross-clamping during cardiac surgery. Evidence is accumulating that mechanisms which are operative in experimental ischaemic preconditioning (infarct size limitation) are also operative in these clinical models of repeated reversible ischaemia. Insight into the mechanisms responsible for ischaemic preconditioning could potentially help to develop pharmacological agents which mimic preconditioning. This is especially attractive as several of the ischaemic episodes maybe too short or insufficiently severe to trigger preconditioning. By a synergistic or additive action, the combination of such a stimulus with a low dose of pharmacological agent might result in protective action. If these agents were also to be used for treating cardiovascular conditions, such as the K+ATP channel activator nicorandil for the treatment of angina pectoris, the cardioprotective effect could be a beneficial side effect. The currently available protein kinase C activators are oncogenic, but with the recognition and better understanding of the different subtypes possibly involved in preconditioning, new protein kinase C activators may become available without these side-effects. On the other hand, hearts of patients who regularly experience episodes of ischaemia may be in a more or less permanent state of preconditioning afforded by one of these stimuli or have developed tolerance. In this situation it is likely that (additional) protection by a pharmacological agent cannot be accomplished at that time. It is reassuring, however, that in the animal, preconditioning can be reinstated immediately after the cardioprotection is lost and that it can also be demonstrated in hearts with pathological conditions such as hypertrophy. Finally, in view of the observations that cardioprotection may also be produced by transient ischaemia in other organs, and even by some forms of stress which do not lead to myocardial ischaemia, it could be envisioned that ischaemic preconditioning is only one component of a general form of adaptation.
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PMID:Ischaemic preconditioning: is it clinically relevant? 858 77

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

Ischemic preconditioning has been shown to be one of the most powerful means of protecting the myocardium from ischemic injury in experimental animal models, although the mechanism is incompletely understood. In this review we discuss the evidence for preconditioning occurring in ischemic syndromes in humans, whether the human myocardium can be preconditioned, and whether preconditioning would have a place as a therapeutic tool in clinical practice. Some studies evaluating patients after acute myocardial infarction have shown a better outcome in patients reporting angina before the onset of the infarction, but this is not a universal finding, and it is difficult to exclude other confounding factors, such as collateral flow, from influencing the results. More controlled prospective studies have evaluated patients undergoing percutaneous transluminal coronary angioplasty and have found less ST-segment change and less reported angina during the second balloon inflation when compared with the first. Again, it is impossible to completely exclude other causes for this effect, but the dependence on mechanisms that are known to be important for preconditioning in animal models does suggest the phenomena are the same. Further experiments using isolated human atrial muscle have shown that human myocardium can be preconditioned and that the mechanisms involved are similar to those elucidated in animal models (adenosine, protein kinase C, and ATP-dependent potassium channels). In clinical medicine preconditioning is most likely to benefit patients when it is used to protect against the ischemia induced by cardiac surgery. In this respect, a study has shown that in patients undergoing coronary artery bypass grafts, the reduction in ATP occurring during the first ischemic period is attenuated in those given an ischemic preconditioning protocol beforehand. Despite these advances, it is likely that the full potential of preconditioning in clinical practice will not be realized until the whole mechanism of protection is understood and a safe pharmacological "preconditioning" agent becomes available.
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PMID:Preconditioning the human myocardium: recent advances and aspirations for the development of a new means of cardioprotection in clinical practice. 885 Mar 77

Myocardial preconditioning describes the profound myocardial protection that follows a short episode of sublethal ischaemia. Adenosine is produced in ischaemic myocardium and is thought to be an important trigger of the protective mechanism. The exact pathway awaits full elucidation but activation of G proteins and subsequently protein kinase C appear to be important signals. End effectors responsible for delaying cell death include opening of K+ATP ion channels and the transcription of a family of cytoprotective proteins. Absolute proof that preconditioning occurs in man is still awaited, although cross clamping of the aorta during cardiac surgery, balloon inflation during coronary angioplasty, warm-up angina and preinfarction angina are surrogate models supporting its existence. A clearer understanding of the protective mechanisms involved could lead to the development of novel therapeutic agents that could save the infarcting myocardium.
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PMID:Myocardial preconditioning: mechanisms and man. 989 76

The phenomenon of ischaemic preconditioning, highlights a new and endogenous route to myocardial protection, which we believe could be exploited in our search for new therapeutic ways to protect the infarcting myocardium. Ischaemic preconditioning has been shown to be associated with both an early, or acute phase of protection lasting approximately 1-2 hours, as well as a delayed phase or "second window of protection" seen at least 24 hours following the initial sublethal ischaemic insult, and lasting up to 72 hours. We believe that both responses are triggered by similar receptor mediated events in addition to using the similar signalling pathways involving kinase cascades. However it is thought that the ultimate target or end-effector through which the protection is manifest may be different for the early vs. late effects. Some evidence exists that the end-effector involved in early preconditioning may be via the ATP-sensitive potassium channel (K(ATP)). With respect to the second window of protection, the cellular mechanisms underlying this are not fully understood at present, however we believe that they may be dependent upon a similar signalling transduction pathway with upregulation of cytoprotective proteins such as the heat stress proteins, and/or anti-oxidant proteins. Evidence demonstrating that preconditioning can occur in the human myocardium is also accumulating. In this respect cultured human ventricular myocytes as well as human atrial muscle have been shown to be preconditioned with brief episodes of simulated ischemia. These human preparations also respond to the known triggers and possible end-effectors of preconditioning, (e.g. adenosine receptor stimulation and K(ATP) channel opening) as well as being able to elicit their responses through the PKC signalling pathway. Further support for this phenomenon, in man, comes from PTCA studies demonstrating that this invasive procedure can put patients into a "preconditioned state"; this effect being associated with reduced ischaemic symptoms as well as the involvement of the adenosine receptor and K(ATP) channel. Of further interest is the observation that patients with a previous history of angina, prior to a MI, sustain smaller infarcts and have an improved survival. However the most direct evidence that preconditioning occurs in man comes from studies in patients undergoing coronary artery bypass surgery. The above evidence that preconditioning can occur in man makes it now possible to begin to design clinical studies investigating cardioprotective properties of drugs that can specifically mimic this phenomenon.
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PMID:Myocardial adaptation to ischaemia--the preconditioning phenomenon. 1032 17

In experimental studies in the dog, total proximal coronary artery occlusions of up to 15 minutes result in reversible injury, meaning that the myocytes survive this insult. The 15 minutes of ischemia, however, induce numerous changes in the myocardium, including certain monuments to the brief episode of ischemia that may persist for days. One of these monuments is stunned myocardium, which represents "prolonged postischemic contractile dysfunction of myocardium salvaged by reperfusion." The mechanism of stunning involves generation of oxygen radicals as well as alteration in calcium homeostasis and possibly alteration in contractile protein structure. Stunning has been observed in several clinical scenarios, including after percutaneous transluminal coronary angioplasty, unstable angina, stress-induced ischemia, after thrombolysis, and after cardiopulmonary bypass. Oxygen radical scavengers and calcium channel blockers have been shown to enhance function of stunned myocardium in experimental studies, and in a few clinical studies, calcium channel blockers have been shown to ameliorate stunning. Although brief periods of ischemia can contribute to prolonged left ventricular dysfunction and even heart failure, they paradoxically play a cardioprotective role. Episodes of ischemia as short as 5 minutes, followed by reperfusion, protect the heart from a subsequent longer coronary artery occlusion by markedly reducing the amount of necrosis that results from the test episode of ischemia. This phenomenon, called ischemic preconditioning, has been observed in virtually every species in which it has been studied and is a powerful cardioprotective effect. The mechanism of ischemic preconditioning involves both triggers and mediators and involves complex second messenger pathways that appear to involve such components as adenosine, adenosine receptors, the epsilon isoform of protein kinase C, the ATP-dependent potassium channels, as well as others, including a paradoxical protective role of oxygen radicals. Both an early and a late phase of preconditioning have been described, and the mechanisms underlying their induction are under investigation. That preconditioning may occur in humans is suggested by the observations that repetitive balloon inflations in the coronary artery are associated with progressively less chest pain, ST-segment elevation, lactate production, the protective effects of preinfarction angina, the anginal "warm-up phenomenon," and studies performed on human cardiac biopsies that show metabolic properties suggesting preconditioning. Development of pharmacological agents that stimulate second messenger pathways thought to be involved in preconditioning, but without causing ischemia, could result in novel approaches to treating ischemia. Hence, on one hand, brief episodes of ischemia can have a negative effect on the heart: stunning; and on the other hand, they have a protective effect: preconditioning. The future challenge is how to minimize the stunning phenomenon and maximize the preconditioning phenomenon in clinical practice.
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PMID:Consequences of brief ischemia: stunning, preconditioning, and their clinical implications: part 1. 1173 16

In experimental studies in the dog, total proximal coronary artery occlusions of up to 15 minutes result in reversible injury, meaning that the myocytes survive this insult. The 15 minutes of ischemia, however, induce numerous changes in the myocardium, including certain monuments to the brief episode of ischemia that may persist for days. One of these monuments is stunned myocardium, which represents "prolonged postischemic contractile dysfunction of myocardium salvaged by reperfusion." The mechanism of stunning involves generation of oxygen radicals as well as alteration in calcium homeostasis and possibly alteration in contractile protein structure. Stunning has been observed in several clinical scenarios, including after percutaneous transluminal coronary angioplasty, unstable angina, stress-induced ischemia, after thrombolysis, and after cardiopulmonary bypass. Oxygen radical scavengers and calcium channel blockers have been shown to enhance function of stunned myocardium in experimental studies, and in a few clinical studies, calcium channel blockers have been shown to ameliorate stunning. Although brief periods of ischemia can contribute to prolonged left ventricular dysfunction and even heart failure, they paradoxically play a cardioprotective role. Episodes of ischemia as short as 5 minutes, followed by reperfusion, protect the heart from a subsequent longer coronary artery occlusion by markedly reducing the amount of necrosis that results from the test episode of ischemia. This phenomenon, called ischemic preconditioning, has been observed in virtually every species in which it has been studied and is a powerful cardioprotective effect. The mechanism of ischemic preconditioning involves both triggers and mediators and involves complex second messenger pathways that appear to involve such components as adenosine, adenosine receptors, the epsilon isoform of protein kinase C, the ATP-dependent potassium channels, as well as others, including a paradoxical protective role of oxygen radicals. Both an early and a late phase of preconditioning have been described, and the mechanisms underlying their induction are under investigation. That preconditioning may occur in humans is suggested by the observations that repetitive balloon inflations in the coronary artery are associated with progressively less chest pain, ST-segment elevation, lactate production, the protective effects of preinfarction angina, the anginal "warm-up phenomenon," and studies performed on human cardiac biopsies that show metabolic properties suggesting preconditioning. Development of pharmacological agents that stimulate second messenger pathways thought to be involved in preconditioning, but without causing ischemia, could result in novel approaches to treating ischemia. Hence, on one hand, brief episodes of ischemia can have a negative effect on the heart: stunning; and on the other hand, they have a protective effect: preconditioning. The future challenge is how to minimize the stunning phenomenon and maximize the preconditioning phenomenon in clinical practice.
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PMID:Consequences of brief ischemia: stunning, preconditioning, and their clinical implications: part 2. 1174 17

Brief periods of non-lethal ischemia and reperfusion render the myocardium more resistant to subsequent ischemia. This adaption occurs in a biphasic pattern: the first being active immediately and lasting for 2-3 hrs (early preconditioning), the second starting at 24 hrs until 72 hrs after the initial ischemia (delayed preconditioning) and requiring genomic activation with de novo protein synthesis. Early preconditioning is more potent than delayed preconditioning in reducing infarct size; delayed preconditioning also attenuates myocardial stunning. Early preconditioning depends on the ischemia-induced release of adenosine and opioids and, to a lesser degree, also bradykinin and prostaglandins. These molecules activate G-protein coupled receptors, initiate the activation of KATP channels and generation of oxygen radicals, and stimulate a series of protein kinases with essential roles for protein kinase C, tyrosine kinases and members of the MAP kinase family. Delayed preconditioning is triggered by a similar sequence of events, but in addition essentially depends on eNOS-derived NO. Both early and pharmacological preconditioning can be pharmacologically mimicked by exogenous adenosine, opioids, NO and activators of protein kinase C. Newly synthetized proteins associated with delayed preconditioning comprise iNOS, COX-2, manganese superoxide dismutase and possibly heat shock proteins. The final mechanism of protection by preconditioning is yet unknown; energy metabolism, KATP channels, the sodium-proton exchanger, stabilisation of the cytoskeleton and volume regulation will be discussed. For ethical reasons, evidence for ischemic preconditioning in humans is hard to provide. Clinical findings that parallel experimental ischemic preconditioning are reduced ST-segment elevation and pain during repetitive PTCA or exercise tests, a better prognosis of patients in whom myocardial infarction was preceded by angina, and reduced serum markers of myocardial necrosis after preconditioning protocols during cardiac surgery with cardiac arrest. The most promising approach to apply principles of ischemic preconditioning therapeutically appears to be the pharmacological recruitment of delayed protection, as recently demonstrated with intravenous nitroglycerine in patients undergoing PTCA 24 hrs later.
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PMID:Ischemic preconditioning. Experimental facts and clinical perspective. 1247 80

Certain angina and coronary artery disease forms do not respond to Ca2+ channel blockers, and a role for vasoactive eicosanoids such as PGF2alpha in Ca2+ antagonist-insensitive coronary vasospasm is suggested; however, the signaling mechanisms are unclear. We investigated whether PGF2alpha-induced coronary smooth muscle contraction is Ca2+ antagonist insensitive and involves activation of a PKC-dependent pathway. We measured contraction in single porcine coronary artery smooth muscle cells and intracellular free Ca2+ concentration ([Ca2+]i) in fura 2-loaded cells and examined cytosolic and particulate fractions for PKC activity and reactivity with isoform-specific PKC antibodies. In Hanks' solution (1 mM Ca2+), PGF2alpha (10-5 M) caused transient [Ca2+]i increase followed by maintained [Ca2+]i increase and 34% cell contraction. Ca2+ channel blockers verapamil and diltiazem (10-6 M) abolished maintained PGF2alpha-induced [Ca2+]i increase but only partially inhibited PGF2alpha-induced cell contraction to 17%. Verapamil-insensitive PGF2alpha contraction was inhibited by PKC inhibitors GF-109203X, calphostin C, and epsilon-PKC V1-2. PGF2alpha caused Ca2+-dependent alpha-PKC and Ca2+-independent epsilon-PKC translocation from cytosolic to particulate fractions that was inhibited by calphostin C. Verapamil abolished PGF2alpha-induced alpha-but not epsilon-PKC translocation. PMA (10-6 M), a direct activator of PKC, caused 21% contraction with no significant [Ca2+]i increase and epsilon-PKC translocation that were inhibited by calphostin C but not verapamil. Membrane depolarization by 51 mM KCl, which stimulates Ca2+ influx, caused 36% cell contraction and [Ca2+]i increase that were inhibited by verapamil but not GF-109203X or calphostin C and did not cause alpha- or epsilon-PKC translocation. Thus a significant component of PGF2alpha-induced contraction of coronary smooth muscle is Ca2+ antagonist insensitive, involves Ca2+-independent epsilon-PKC activation and translocation, and may represent a signaling mechanism of Ca2+ antagonist-resistant coronary vasospasm.
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PMID:Ca2+ antagonist-insensitive coronary smooth muscle contraction involves activation of epsilon-protein kinase C-dependent pathway. 1460 78


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