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)

Several lines of evidence indicate that a rapid loss of neuronal protein kinase C (PKC) activity is a characteristic feature of cerebral ischemia and is a necessary step in the NMDA-induced death of cultured neurons. Exposing embryonic day 18 primary rat cortical neurons to 50 microM NMDA or 50 microM glutamate for 10 min caused approximately 80% cell death over the next 24 h, but excitotoxic death was largely averted, i.e., by 70-80%, in cells pretreated with brain-derived neurotrophic factor (BDNF). An 8-h preexposure to BDNF (50-100 ng/ml) maximally protected cortical cells from the effects of NMDA and glutamate, although the transient application of BDNF between 8 and 4 h before NMDA was equally protective. These effects of BDNF were abolished at supralethal, i.e., >100 microM, NMDA concentrations. It is significant that BDNF pretreatment prevented the inactivation of PKC in cortical cells normally seen 30 min to 2 h following lethal NMDA or glutamate exposure. This BDNF effect did not arise from changes in NMDA channel activity because neither whole-cell NMDA current amplitudes nor increases in intracellular free Ca2+ concentration were altered by the 8-h BDNF pretreatment. Furthermore, BDNF offered no neuroprotection to cells treated with the PKC inhibitors staurosporine (10-20 nM), calphostin C (1-2.5 microM), or GF-109203X (100 nM) at the time of NMDA addition. These results underscore the importance of PKC inactivation in glutamate-induced neuronal death. They also suggest that BDNF neuroprotection arises, at least in part, via its ability to block the mechanism by which pathophysiological Ca2+ influx through the NMDA receptor causes membrane PKC inactivation.
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PMID:Evidence that brain-derived neurotrophic factor neuroprotection is linked to its ability to reverse the NMDA-induced inactivation of protein kinase C in cortical neurons. 988 60

High concentrations of glutamate, the major excitatory neurotransmitter in the mammalian brain, lead to intracellular calcium overload resulting in excitotoxic damage and death of neurons. Since protein kinase C (PKC) is involved in neuronal degeneration resulting from cerebral ischemia and from glutamate excitotoxicity, we investigated the effect of glutamate on changes in the cellular distribution of various PKC isoforms in cultured hippocampal neurons in comparison with the effects elicited by the PKC activator phorbol ester. Out of the expressed PKC isoforms alpha, gamma, epsilon, zeta and lambda only the conventional isoforms PKC alpha and gamma responded to glutamate. Using subcellular fractionation and Western blotting with isoform-specific antibodies and immunocytochemical localization with confocal laser scanning microscopy, we observed that phorbol ester and glutamate have different effects on PKC isoform redistribution: Whereas phorbol ester resulted in translocation of PKC alpha and PKC gamma toward a membrane fraction, the glutamate-mediated rise in intracellular calcium concentration induced a translocation mainly toward a detergent-insoluble, cytoskeletal fraction. Immunocytochemical analysis revealed an isoform-specific translocation following glutamate treatment: PKC gamma was translocated mainly to cytoplasmic, organelle-like structures, whereas PKC alpha redistributed to the plasma membrane and into the cell nucleus. The latter result is of special interest, as it indicates that nuclear PKC may play a role in processes of excitotoxic cell damage.
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PMID:Isoform-specific translocation of protein kinase C following glutamate administration in primary hippocampal neurons. 993 92

The exact mechanism of vasospasm is still unknown. The etiology of cerebral vasospasm is subarachnoid blood clot. Vasospasm is a multifactorial process. Oxyhemoglobin is released by erythrocyte lysis and exert several effects on the endothelium that could lead to vasoconstriction. The production of free radical and superoxide anion radical secondary to hemoglobin degradation stimulates the release of vasoconstricting products. Arterial vasoconstriction secondary to smooth muscle contraction could be related to increase in protein kinase C. Narrowing of cerebral vessels produces cerebral ischemia by hemodynamic mechanisms. Direct hypothalamic insults may be associated. Clot removal and clot lysis have been proposed to prevent vasospasm. Pharmacological treatments are targeted to the vasospasm itself (nicardipine, AT 877) or the prevention of delayed ischemic events (nimodipine, tirilazad). General measures such as the "triple H therapy" (hemodilution, hypertension, hypervolemia) are widely used in the prevention and/or treatment of cerebral vasospasm.
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PMID:[Pathophysiology and principles of treatment of vasospasm]. 1036 50

Systemic hyperglycemia and hypercapnia severely aggravate ischemic brain damage when instituted prior to cerebral ischemia. An aberrant cell signaling following ischemia has been proposed to be involved in ischemic cell death, affecting protein kinase C (PKC) and the calcium calmodulin kinase II (CaMKII). Using a cardiac arrest model of global brain ischemia of 10 min duration, we investigated the effect of hyperglycemia (20 mM) and hypercapnia (pCO(2) 300 mmHg) on the subcellular redistribution of PKC (alpha, beta, gamma) and CaMKII to synaptic membranes and to the microsomes, as well as the effect on PKC activity. We confirmed the marked translocation of PKC and CaMKII to cell membranes induced by ischemia, concomitantly with a decrease in the PKC activity in both the membrane fraction and cytosol. Hyperglycemia and hypercapnia markedly enhanced the translocation of PKC-gamma to cell membranes while other PKC isoforms were less affected. There was no effect of acidosis on PKC activity, or on translocation of CaMKII to cell membranes. Our data strongly suggest that the enhanced translocation of PKC to cell membranes induced by hyperglycemia and hypercapnia may contribute to the detrimental effect of tissue acidosis on the outcome following ischemia.
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PMID:Acidosis enhances translocation of protein kinase C but not Ca(2+)/calmodulin-dependent protein kinase II to cell membranes during complete cerebral ischemia. 1059 93

Experimental evidence suggests that the massive release of glutamate during experimental brain ischemia both directly and indirectly regulates downstream mechanisms of cell suicide. Cerebral ischemia was produced by distal, permanent occlusion of the middle cerebral artery (MCAO) in the rat. Sets of three animals and one sham-operated for each time-point were kept alive for 0-30 min, 1, 4, 12, 24, and 48 h, and 4 days. Additional animals were treated by local administration of a 10 microM (in 10 microl) cocktail of caspase inhibitors (YVAD-cmk, DEVD-fmk, IETD). Immunohistochemistry was performed on free-floating tissue sections with goat polyclonal antibodies to procaspase-1, -2, -3, -6, and -8. Some sections were processed for double-labeling procaspase immunohistochemistry and in situ end-labeling of nuclear DNA fragmentation (TUNEL method). Both immunohistochemistry and double-labeling procaspase immunohistochemistry and TUNEL method were carried out on formalin-fixed sections. For gel electrophoresis and Western blotting, we used antibodies to poly (ADP-ribose) polymerase (PARP), lamin B, and PKC-delta, as specific cleavage substrates of caspases. There was increased immunoreactivity ipsilaterally in the areas corresponding to the infarct and surrounding penumbra with the peak of immunoreactivity between 12 and 24 h for most of the procaspases. Procaspases were present early in the infarcted tissue neurones and their dendrites and axons. Additional procaspase expression occurred in astrocytes and microglial cells at different times following ischemia. Cells with positive in situ end-labeling of nuclear DNA fragmentation appeared in high number predominantly in the infarcted areas and at the edge of the infarction and colocalized with enhanced procaspase expression. These findings suggest increased procaspase expression in dying cells at the edge of the infarction. A major product of PARP degradation of about 89 kDa was found in the samples taken from the infarcted and penumbra areas. There was no difference in the intensity of the bands corresponding to lamin B or PKC-delta. Injection of procaspase inhibitors reduced the levels of major PARP products of 89 kDa and decreased the number of TUNEL-positive cells at 12 h post-MCAO. In conclusion, these results give support to further research on the use of caspase inhibitors as add-on therapeutic agents for the treatment of ischemia.
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PMID:Expression of caspases and their substrates in the rat model of focal cerebral ischemia. 1096 5

Heme oxygenase (HO) cleaves the heme ring to form biliverdin, which is rapidly reduced to bilirubin, carbon monoxide, and iron. HO1, the first form of the enzyme discovered, is an inducible protein, concentrated in tissues that are exposed to degrading red blood cells and stimulated by hemolysis and numerous other toxic perturbations to eliminate potentially toxic heme. By contrast, HO2 is constitutive and most highly concentrated in neural tissues. Carbon monoxide, formed from HO2, is a putative neurotransmitter in the brain and peripheral autonomic nervous system. HO1 regulates the efflux of potentially toxic iron from cells, as iron efflux is deficient in mice with targeted deletion of HO1 (HO1(-/-)), and transfection of HO1 facilitates iron efflux. Bilirubin appears to be a physiologic neuroprotectant. Activation of HO2 by phorbol esters, that stimulate protein kinase C to phosphorylate HO2, augments production of bilirubin which protects brain cultures from oxidative stress. Bilirubin itself in nanomolar concentrations is neuroprotective, while HO2 deletion (HO2(-/-)) leads to increased neurotoxicity in brain cultures and increased neural damage following transient cerebral ischemia in intact mice. Mechanisms whereby HO2 provides neuroprotection have not been clarified including whether protection is primarily associated with apoptotic or necrotic cell death. Moreover, the generality of neurotoxic stimuli influenced by HO2 has been unclear. We now demonstrate increased neuronal death in cerebellar granule cultures of HO2(-/-) mice with a selective augmentation of apoptotic death. We also demonstrate that HO2 transfection rescues apoptotic death. In intact mice, we show an increased incidence of apoptotic morphology in the penumbra area surrounding the infarct core in HO2(-/-) mice undergoing transient focal ischemia.
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PMID:Heme oxygenase-2 acts to prevent neuronal death in brain cultures and following transient cerebral ischemia. 1097 22

Stroke occurs due to haemorrhage or occlusive injury and results in ischaemia and reperfusion injury. A variety of destructive mechanisms are involved including oxygen radical generation, calcium overload, cytotoxicity and apoptosis as well as the generation of inflammatory mediators. Ebselen, 2-phenyl-1, 2-benzisoselenazol-3(2H)-one (PZ 51, DR3305), is a mimic of GSH peroxidase which also reacts with peroxynitrite and can inhibit enzymes such as lipoxygenases, NO synthases, NADPH oxidase, protein kinase C and H(+)/K(+)-ATPase. Ebselen is in a late stage of development for the treatment of stroke. The molecular actions of ebselen contribute to its anti-inflammatory and anti-oxidant properties, which have been demonstrated in a variety of in vivo models. Numerous in vitro experiments using isolated LDL, liposomes, microsomes, isolated cells and organs have established that ebselen protects against oxidative challenge. Unlike many inorganic and aliphatic selenium compounds, ebselen has low toxicity as metabolism of the compound does not liberate the selenium moiety, which remains within the ring structure. Subsequent metabolism involves methylation, glucuronidation and hydroxylation. Experimental studies in rats and dogs have revealed that ebselen is able to inhibit both vasospasm and tissue damage in stroke models, which correlates with its inhibitory effects on oxidative processes. Results from randomised, placebo-controlled, double-blind clinical studies on the neurological consequences of acute ischaemic stroke, subarachnoid haemorrhage and acute middle cerebral artery occlusion, have revealed that ebselen significantly enhances outcome in patients who have experienced occlusive cerebral ischaemia of limited duration. The benefit achieved with ebselen is closely related to the rapidity with which the treatment is initiated, following the onset of the stroke attack. Safety and tolerability are good and no adverse effects have become apparent. Ebselen is currently at the pre-registration stage for subarachnoid haemorrhage and stroke in Japan.
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PMID:Ebselen: prospective therapy for cerebral ischaemia. 1106 Jun 99

Tumour necrosis factor-alpha (TNF-alpha) is a major immunomodulatory and proinflammatory cytokine which is shed in its soluble form by a membrane-anchored zinc protease, identified as a disintegrin and metalloproteinase (ADAM) called TNF-alpha convertase (TACE; ADAM17). The role of this protease in the adult nervous system remains poorly understood. During cerebral ischemia and subsequent reperfusion, expression and release of TNF-alpha have been shown. We have investigated the expression and activity of TACE in an in vitro model of brain ischemia consisting of rat forebrain slices exposed to oxygen-glucose deprivation (OGD). OGD caused the release of TNF-alpha, an effect which was inhibited by a hydroxamate-based metalloprotease inhibitor, BB-3103, with an IC(50) of 0.1 microM, suggesting that TNF-alpha release results selectively from TACE activity. Assay of TACE enzymatic activity on a fluorescein-labelled peptide spanning the cleavage site in pro-TNF-alpha, as well as Western blot and RT-PCR analyses showed that TACE is present in control forebrain and, more interestingly, that TACE expression is increased in OGD-exposed tissue. TACE enzymatic activity from OGD-exposed slices was significantly inhibited by cycloheximide, suggesting that de novo synthesis of TACE contributes to TNF-alpha release after ischaemia. Moreover, it was also inhibited by bisindolylmaleimide I, indicating that TACE activity is regulated by PKC. These findings posed the question of what was its function therein. Among other actions, TNF-alpha has been described to be involved in the expression of inducible nitric oxide synthase (iNOS), a high-output NOS isoform associated to cellular damage, but the link between TNF-alpha release after brain ischaemia and iNOS expression in this condition has not been shown. We have now found that iNOS expression in OGD-subjected brain slices is inhibited by BB-3103 at concentrations below 1 microM, indicating that shedding of TNF-alpha by TACE plays a necessary part in the induction of this NOS isoenzyme after OGD. Taken together, these data demonstrate that (1) TACE/ADAM17 activity accounts for the majority of TNF-alpha shedding after OGD in rat forebrain slices, (2) an increase in TACE expression contributes, at least in part, to the rise in TNF-alpha after OGD and (3) iNOS expression in OGD-subjected brain slices results from TACE activity and subsequent increase in TNF-alpha levels.
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PMID:Up-regulation of TNF-alpha convertase (TACE/ADAM17) after oxygen-glucose deprivation in rat forebrain slices. 1140 1

The effects of transient cerebral ischemia on phosphorylation of the NR1 subunit of the NMDA receptor by protein kinase C (PKC) and protein kinase A (PKA) were investigated. Adult rats received 15 min of cerebral ischemia followed by various times of recovery. Phosphorylation was examined by immunoblotting hippocampal homogenates with antibodies that recognized NR1 phosphorylated on the PKC phosphorylation sites Ser890 and Ser896, the PKA phosphorylation site Ser897, or dually phosphorylated on Ser896 and Ser897. The phosphorylation of all sites examined increased following ischemia. The increase in phosphorylation by PKC was greater than by PKA. The ischemia-induced increase in phosphorylation was predominantly associated with the population of NR1 that was insoluble in 1% deoxycholate. Enhanced phosphorylation of NR1 by PKC and PKA may contribute to alterations in NMDA receptor function in the postischemic brain.
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PMID:Increased phosphorylation of the NR1 subunit of the NMDA receptor following cerebral ischemia. 1155 92

Mild cerebral anoxic/ischemic/stress insults promote 'tolerance' and thereby protect the brain from subsequent 'lethal' anoxic/ischemic insults. We examined whether specific activation of PKC alpha, delta, epsilon, or zeta isoforms is associated with ischemic preconditioning (IPC) in rat brain. IPC was produced by a 2-minute global cerebral ischemia. Membrane and cytosolic fractions of the hippocampi were immunoblotted using specific antibodies for PKCalpha, delta, epsilon, and zeta. PKCalpha showed a significant translocation to the membrane fraction from 30 min to 4 h and PKCdelta at 4 h following IPC. In contrast, the membrane/cytosol ratio of PKCepsilon showed a tendency to decrease at 30 min and 8 h, and the membrane/cytosol ratio of PKCzeta was significantly decreased from 30 min to 24 h following IPC. These findings indicate PKC isoform-specific membrane translocations in the hippocampus after brief global brain ischemia and suggest that activation of PKCalpha and PKCdelta may be associated with IPC-induced tolerance in the rat hippocampus.
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PMID:Isoform-specific membrane translocation of protein kinase C after ischemic preconditioning. 1170 Sep 56


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