UMLS:C0151744 - FACTA Search

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Query: UMLS:C0151744 (myocardial ischemia)
31,282 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The development of atherosclerosis is a multifactorial process in which both elevated plasma cholesterol levels and proliferation of smooth muscle cells play a central role. Numerous studies have suggested the involvement of oxidative processes in the pathogenesis of atherosclerosis and especially of oxidized low density lipoprotein. Some epidemiological studies have shown an association between high dietary intake and high serum concentrations of vitamin E and lower rates of ischemic heart disease. Cell culture studies have shown that alpha-tocopherol brings about inhibition of smooth muscle cell proliferation. This takes place via inhibition of protein kinase C activity. alpha-Tocopherol also inhibits low density lipoprotein induced smooth muscle cell proliferation and protein kinase C activity. The following animal studies showed that vitamin E protects development of cholesterol induced atherosclerosis by inhibiting protein kinase C activity in smooth muscle cells in vivo. Elevated plasma levels of homocysteine have been identified as an important and independent risk factor for cerebral, coronary and peripheral atherosclerosis. However the mechanisms by which homocysteine promotes atherosclerotic plaque formation are not clearly defined. Earlier reports have been suggested that homocysteine exert its effect via H2O2 produced during its metabolism. To evaluate the contribution of homocysteine in the pathogenesis of vascular diseases, we examined whether the homocysteine effect on vascular smooth muscle cell growth is mediated by H2O2. We show that homocysteine induces DNA synthesis and proliferation of vascular smooth muscle cells in the presence of peroxide scavenging enzyme, catalase. Our data suggest that homocysteine induces smooth muscle cell growth through the activation of an H2O2 independent pathway and accelerate the progression of atherosclerosis. The results indicate a cellular mechanism for the atherogenicity of cholesterol or homocysteine and protective role of vitamin E in the development of atherosclerosis.
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PMID:Molecular mechanisms of cholesterol or homocysteine effect in the development of atherosclerosis: Role of vitamin E. 1475 78

Cytosolic Ca(2+) overload is a critical mediator of myocardial damage following cardiac ischemia-reperfusion. It has therefore been proposed that normalization of sarcoplasmic reticulum Ca(2+) cycling through inhibition or ablation of the Ca(2+) ATP-ase inhibitor phospholamban (PLN), which shows promise as a treatment for heart failure, could be beneficial in ischemic heart disease. However, a recent study has shown that globally ischemic PLN-deficient hearts exhibit increased ischemic injury, with impaired contractile, ATP, and phosphocreatine recoveries, compared to wild-type hearts. Since protein kinase C (PKC) family members are widely recognized as mediators of both post-ischemic injury and ischemic preconditioning, we assessed PKC levels in PLN-deficient hearts. Compared to genetically normal hearts, PLN-deficient hearts exhibited diminished particulate partitioning of PKC, a known cardioprotective PKC isoform, without alterations in the levels of membrane-associated PKC delta nor PKC alpha. To determine if decreased particulate partitioning of cardioprotective PKC epsilon was a cause of increased ischemic injury in PLN-deficient hearts, PLN-deficient mice were mated with mice expressing a myocardial-specific PKC epsilon translocation activator peptide, pseudo-epsilon receptor for activated kinase C (psi epsilon RACK). In psi epsilon RACK/PLN knockout (KO) hearts, PKC epsilon translocation to membranous cellular structures was augmented and this was associated with a significant acceleration of post-ischemic contraction and relaxation rates, as well as reduction of creatine phosphokinase release, compared to PLN-deficient hearts. Importantly, post-ischemic functional recovery reached pre-ischemic hyperdynamic values in psi epsilon RACK/PLN KO hearts, indicating super-rescue by the combination of PLN ablation and psi epsilon RACK expression. These findings suggest that diminished PKC epsilon particulate partitioning in PLN-deficient hearts is associated with attenuated contractile recovery upon ischemia-reperfusion and that increased translocation of PKC to membranous cellular structures confers full cardioprotection.
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PMID:Increased particulate partitioning of PKC epsilon reverses susceptibility of phospholamban knockout hearts to ischemic injury. 1487 59

Myocardial ischemia and ischemia/reperfusion activate several protein kinase pathways. Protein kinase activation potentially regulates the onset of myocardial cell injury and the reduction of this injury by ischemic and pharmacologic preconditioning. The primary protein kinase pathways that are potentially activated by myocardial ischemia/reperfusion include: the MAP kinases, ERK 1/2, JNK 1/2, p38 MAPKalpha/beta; the cell survival kinase, Akt; and the sodium-hydrogen exchanger (NHE) kinase, p90RSK. The literature does not support a role for ischemia/reperfusion in the activation of the tyrosine kinases, Src and Lck, or the translocation and activation of PKC. This review will detail the role of these protein kinases in the onset of myocardial cell death by necrosis and apoptosis and the reduction of this injury by preconditioning.
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PMID:Protein kinase activation and myocardial ischemia/reperfusion injury. 1496 74

Erythropoietin is protective against cardiac ischemia, but the underlying mechanisms are unknown. We determined whether erythropoietin (0.5 - 10.0 U/ml) confers acute cardioprotection in infant rabbit hearts and the contribution of protein kinases, nitric oxide synthase and potassium channels to the underlying mechanism. Hearts from normoxic infant New Zealand White rabbits (n=8/group) were isolated and perfused in the Langendorff mode. Biventricular function was recorded under steady-state conditions prior to 30 min global no-flow ischemia and 35 min reperfusion. Administration of erythropoietin for 15 min immediately prior to ischemia resulted in a concentration-dependent increase in recovery of left and right ventricular developed pressure in rabbit hearts following myocardial ischemia and reperfusion. The optimal concentration of erythropoietin that afforded maximum recovery of developed pressure was manifest at 1.0 U/ml. Erythropoietin (1.0 U/ml) treatment resulted in phosphorylation of PKC, p38 MAP kinase and p42/44 MAP kinase. The cardioprotective effects of erythropoietin were abolished by the protein kinase inhibitors SB203580 (p38 MAP kinase), PD98059 (p42/44 MAP kinase) and chelerythrine (PKC) as well as the potassium channel blockers glibenclamide, HMR 1098, 5-HD and Paxilline. Nitrite and nitrate release from hearts before (2.3 +/- 0.9 nmol/min/g) and after (2.4 +/- 1.9 nmol/min/g) 15 min treatment with erythropoietin (1.0 U/ml) were not different. L-NAME and L-NMA did not block the cardioprotective effect of erythropoietin. We conclude the rapid activation of potassium channels and protein kinases by erythropoietin represents an important new mechanism for increasing cardioprotection.
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PMID:Acute cardioprotective effects of erythropoietin in infant rabbits are mediated by activation of protein kinases and potassium channels. 2751 2

Chronic arsenic exposure is associated with an increased risk for cancer, cardiovascular disease (including ischemic heart disease and hypertension), peripheral vascular disease, and diabetes. Arsenic causes blood vessel growth and remodeling in vivo and cell specific, dose-dependent induction vascular endothelial growth factor-A (VEGF), which is essential for both processes. The current study examined the hypothesis that low, environmentally relevant levels of trivalent arsenic (AsIII) activate discrete signaling pathways in vascular smooth muscle cells (SMC) to induce expression of VEGF. AsIII caused a progressive increase in VEGF mRNA levels over a 48 h period in primary porcine SMC with a threshold of 1-2.5 microM. VEGF protein levels increased with a similar concentration dependence and time course. Hypoxia inducible factor-1alpha (HIF-1alpha) protein and mRNA levels also increased in response to AsIII. However, unlike the response to an iron chelator, AsIII-induced VEGF was not inhibited by siRNA directed toward HIF-1alpha. Instead, a novel protein kinase C, PKCdelta, was activated by AsIII to induce VEGF and stabilize HIF-1alpha. Consistent with this activation, AsIII caused coordinate increases in the levels of the intracellular second messenger diacyglycerol (DAG). These data suggest that AsIII induced divergent signaling pathways in SMCs that lead to independent increases in VEGF expression and HIF-1alpha signaling. However, these pathways both require initial increases in DAG levels and PKC activity.
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PMID:Signaling pathways for arsenic-stimulated vascular endothelial growth factor-a expression in primary vascular smooth muscle cells. 1508 98

For the first time the involvement of C-Reactive protein (CRP) in early (acute) and delayed ischemic (IPC) and pharmacological (chemical) preconditioning (CPC) in an in vivo model of rat myocardial infarction was presented. Acute IPC was produced by three 5 minute occlusion (ischemia) periods interspersed with 5 minute reperfusion, followed by 30 minute occlusion of the left coronary artery and 2 hour reperfusion injury. Acute CPC was produced by a k-opioid receptor agonist U50488H (5 mg/kg) applied i.v. 15 minutes before 30 minute ischemia/ 2 hour reperfusion. Delayed preconditioning was produced by 30 minute ischemia/ 2 hour reperfusion, induced 24 hour after either ischemic or pharmacological preconditioning. The myocardial ischemia/reperfusion injury was evaluated on the basis of total and cardiac creatine kinase isoenzyme activity, functional recovery of the heart (ECG), infarct size (% IS/RA) and mortality at the end of the experiments. The results obtained showed that: k-opioid receptor agonist U50488H mimics both the acute and delayed IPC in the above experimental protocol; Both acute IPC and most probably CPC act by opening of K(ATP) channels (the effects were blocked by nonspecific ATP-sensitive K channel blocker glybenclamide), and via activation of protein kinase C (a selective protein kinase C inhibitor chelerythrine blocked the efects); C-reactive protein (CRP) was significantly elevated by 54% in non-preconditioned acute ischemia/reperfusion injury. The elevation was more pronounced (82% increase) 24 hour after non-preconditioned ischemia/reperfusion injury. It reflected very well the increase in cardiac isoenzymes, infarct size and mortality of the rats, and can be used as a marker of the severity of myocardial injury in this model; The increase of CRP was prevented by both IPC and CPC in early, and especially in late preconditioning. This confirms the involvement of CRP as a marker in cardiac ischemic/reperfusion injury. It was concluded that in addition to the established involvement of adenosine, bradykinin, opioid and other receptors, a suppression of myocardial CRP/complement production might be involved in the biological mechanism of preconditioning. This could be a promising perspective in clinical interventions against ischemia/reperfusion injuries of the heart.
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PMID:The role of C-reactive protein in ischemia/reperfusion injury and preconditioning in a rat model of myocardial infarction. 1519 50

PKC-delta is believed to play an essential role in cardiomyocyte growth. In the present study, we investigated the effect of PKC-delta on cardiac metabolism using PKC-delta knockout mice generated in our laboratories. Proteomic analysis of heart protein extracts revealed profound changes in enzymes related to energy metabolism: certain isoforms of glycolytic enzymes, e.g., lactate dehydrogenase and pyruvate kinase, were absent or decreased, whereas several enzymes involved in lipid metabolism, e.g., phosphorylated isoforms of acyl-CoA dehydrogenases, showed a marked increase in PKC-delta(-/-) hearts. Moreover, PKC-delta deficiency was associated with changes in antioxidants, namely, 1-Cys peroxiredoxin and selenium-binding protein 1, and posttranslational modifications of chaperones involved in cytoskeleton regulation, such as heat shock protein (HSP)20, HSP27, and the zeta-subunit of the cytosolic chaperone containing the T-complex polypeptide 1. High-resolution NMR analysis of cardiac metabolites confirmed a significant decrease in the ratio of glycolytic end products (alanine + lactate) to end products of lipid metabolism (acetate) in PKC-delta(-/-) hearts. Taken together, our data demonstrate that loss of PKC-delta causes a shift from glucose to lipid metabolism in murine hearts, and we provide a detailed description of the enzymatic changes on a proteomic level. The consequences of these metabolic alterations on sensitivity to myocardial ischemia are further explored in the accompanyingpaper (20).
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PMID:Loss of PKC-delta alters cardiac metabolism. 1527 8

The catalytic activity of calcium-independent phospholipase A2 (iPLA2), which is classified as a group VI PLA2, is regulated by protein kinase C, calmodulin, and others such as reactive oxygen species. Numerous findings have shown that iPLA2 is involved in stimulus-induced arachidonic acid release and lysophospholipid generation, although the participation is dependent upon the cell type and stimulus. The catalytic action of iPLA2 is known to be responsible for phospholipid remodeling as a housekeeping function. However, it has been widely accepted that arachidonic acid and lysophospholipid generated by iPLA2 act as a signaling molecule in cellular functions. Those include eicosanoid production, glucose-induced insulin secretion, Fas-induced apoptosis, cellular proliferation, membrane traffic in fusion, contribution to myocardial ischemia, and others. In this review, the functional role of iPLA2 in cellular responses upon stimulation is the focus.
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PMID:Cellular function of calcium-independent phospholipase A2. 1530 16

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.
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PMID:Ischemic preconditioning: emerging evidence, controversy, and translational trials. 1545 94

Iron chelation by deferoxamine (DFO) blocks the Fenton reaction, but also inhibits prolyl hydroxylases and thereby activates certain hypoxia-inducible transcription factors (HIFs) that trigger cellular adaptation to hypoxia. Because both mechanisms may alleviate tissue damage in ischemia and reperfusion, we tried to differentiate their contribution to DFO-induced cardioprotection. Myocardial ischemia and reperfusion were induced in anesthetized Wistar rats. Infarct size was related to the ischemic area. Myocardial mRNA expression was determined by real-time PCR. Radical reactivity was probed in myocardial tissue slices with the redox-sensitive dye CM-H(2)DCFDA. Single ip applications of DFO (200 mg/kg) administered 2 h to 3 days before infarction reduced infarct size from 55 +/- 7% to 22-26%. Protection was abolished by the radical scavenger N-(2-mercaptopropionyl)glycine and the protein kinase C inhibitor chelerythrine when either was given 30 min before DFO, whereas subsequent application was ineffective. DFO did not alter the expression of various HIF target genes, whereas mRNAs of HIF-independent genes, aldose reductase and glucose transporter-4, were increased in infarcted myocardium 2 days after DFO treatment. Enhancement of superoxide activity by DFO could be demonstrated in vitro. Acute and prolonged myocardial preconditioning is triggered by DFO in response to accumulation of oxygen radicals and activation of protein kinase C.
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PMID:Deferoxamine induces prolonged cardiac preconditioning via accumulation of oxygen radicals. 1558 80

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