Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.11.1 (protein kinase)
 81,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

One of the most important mechanisms for regulating neuronal functions is through second messenger cascades that control protein kinases and the subsequent phosphorylation of substrate proteins. Ca2+/calmodulin-dependent protein kinase II (CaM-kinase II) is the most abundant protein kinase in mammalian brain tissues, and the alpha-subunit of this kinase is the major protein and enzymatic molecule of synaptic junctions in many brain regions. CaM-kinase II regulates itself through a complex autophosphorylation mechanism whereby it becomes calcium-independent following its initial activation. This property has implicated CaM-kinase II as a potential molecular switch at central nervous system (CNS) synapses. Recent studies have suggested that CaM-kinase II is involved in many diverse phenomena such as epilepsy, sensory deprivation, ischemia, synapse formation, synaptic transmission, long-term potentiation, learning, and memory. During brain development, the expression of CaM-kinase II at both protein and mRNA levels coincides with the active periods of synapse formation and, therefore, factors regulating the genes encoding kinase subunits may play a role in the cell-to-cell recognition events that underlie neuronal differentiation and the establishment of mature synaptic functions. Recent findings have demonstrated that the mRNA encoding the alpha-subunit of CaM-kinase II is localized in neuronal dendrites. Current speculation suggests that the localized translation of dendritic mRNAs encoding specific synaptic proteins may be responsible for producing synapse-specific changes associated with the processing, storage, and retrieval of information in neural networks.
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PMID:Calmodulin-dependent protein kinase II. Multifunctional roles in neuronal differentiation and synaptic plasticity. 166 84

In this report we describe changes in the intracellular redistribution of raf serine/threonine protein kinase (product of the raf proto-oncogene family) in hippocampal neurons following cerebral ischemia in Mongolian gerbils. For immunohistochemical localization studies polyclonal antisera specific for each of the A, B, and Raf-1 isotypes of raf, as well as a pan-raf antisera, were employed. Of these, only sera recognizing B-raf, as well as the general v-raf (raised against the conserved C-terminal region) were positive, indicating that B-raf is the major isotype in this neuronal region. Three different ischemic models were used (repeated 3 times for two min and single 5 or 15 min occlusions, of the common carotid arteries) to demonstrate that ischemic insult causes redistribution of raf protein kinase into the cell nucleus of hippocampal neurons. Increased amounts of raf protein in the nuclei of pyramidal cells following ischemia was confirmed by Western blot analysis of isolated nuclear fractionations. Moreover, an elevation in the level of nuclear raf protein also was detected in the contralateral (i.e. non-occluded hemisphere) neurons of CA1 and CA3 subfields 4 days after the ischemic insult indicating a possible transsynaptic increase in the amount of raf protein along with redistribution. The intranuclear translocation of the immunoreactive material started from the perinucleolar rim and with time extended throughout the nucleus. Enhanced levels and altered redistribution of the raf polypeptide in the nuclei of pyramidal cells of the CA3 subfield appears to be reversible and returns to the normal level 12 days following the ischemic insult.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Cerebral ischemia induces transient intracellular redistribution and intranuclear translocation of the raf proto-oncogene product in hippocampal pyramidal cells. 206 47

The possible activation of protein kinase C (PKC) during total cerebral ischemia was investigated in the rat. Translocation of PKC activity from the soluble to the particulate fraction was used as an index of PKC activation. There was a drop in the proportion of particulate PKC activity from 30% for controls to 20% by 30 min of ischemia (p less than 0.01). By 20 min of cardiac arrest, there was a 40% decline of the total cellular PKC activity (p less than 0.01). This was not accompanied by an increase in activator-independent activity, a finding indicating PKC was not being converted to protein kinase M. These data suggest that PKC was not activated during ischemia, but rather that ischemia causes a reduction in cellular PKC activity. Translocation of PKC activity to the particulate fraction was not observed in the cerebral cortex or hippocampus of reperfused brain for up to 6 h of recovery following 11-13 min of total cerebral ischemia. The level of total, soluble, and particulate PKC activity in the cerebral cortex was reduced (p less than 0.05), corresponding to the decrease observed by 15 min of ischemia without reflow. A similar decline in activity was also observed in the hippocampus. No increase in activator-independent activity was observed. These data suggest that PKC was inhibited during cerebral ischemia and that this reduced level of PKC activity was maintained throughout 6 h of recovery. We conclude that pathological activation of PKC was not responsible for the evolution of ischemic brain damage.
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PMID:Decreased protein kinase C activity during cerebral ischemia and after reperfusion in the adult rat. 223 Aug 6

Complete obstruction of the maternal blood flow to fetal rats at 20 days of gestation for a period of 10 min causes a significant shift of approximately 22% in protein kinase C (PKC) activity from a cytosolic to a membrane-bound form in the fetal brain. This translocation can be entirely reversed without losses in activity by a single intraperitoneal injection into the gravid rat of either a mixture of disialo- and trisialoganglioside [polysialoganglioside (PSG)] or by GM1 (50 mg/kg of body weight) given 3 h before onset of the ischemic episode. Cessation of blood flow for 15 min followed by a reperfusion period of 24 h results in a 47% loss in total PKC activity. This down-regulation can be almost entirely prevented upon intraperitoneal administration of GM1 3 h before, but also during and even 90 min after the onset of ischemia. The PSG mixture is also effective, particularly when given 3 h before the insult. Down-regulation of PKC is accompanied by an increase in a Ca2(+)-phosphatidylserine-independent kinase [protein kinase M (PKM)] activity, which rises from 30 pmol/min/mg of protein in control animals to a maximal value of 83.1 pmol/min/mg of protein after 15 min of ischemia and 6 h of reperfusion. By 24 h, PKM activity is 46.8 pmol/min/mg of protein. Administration of GM1 blocks completely the appearance of PKM, a result suggesting that PKC down-regulation and PKM activity elevation are intimately associated events and that both are regulated by GM1 ganglioside.
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PMID:Gangliosides prevent ischemia-induced down-regulation of protein kinase C in fetal rat brain. 223 Aug 13

The protective effects of protein kinase inhibitors and a calmodulin kinase inhibitor (W-7) against ischemic neuronal damage were examined in the CA1 subfield of the hippocampus. Staurosporine, KT5720, and KT5822 were used as inhibitors of protein kinase C (PKC), cyclic AMP-dependent protein kinase, and cyclic GMP-dependent protein kinase, respectively. All test compounds were injected topically into the CA1 subfield of the hippocampus. In the gerbil ischemia model, staurosporine (0.1-10 ng) administered 30 min before ischemia prevented neuronal damage in a dose-dependent manner. However, KT5720, KT5822, and W-7 were ineffective, even at a dose of 10 ng. In the rat ischemia model, staurosporine (10 ng) also prevented neuronal damage when administered before ischemic insult, although staurosporine administered 10 or 180 min after recirculation was ineffective. These results suggest the involvement of PKC in CA1 pyramidal cell death after ischemia and that the fate of vulnerable CA1 pyramidal cells through PKC-mediated processes could be determined during the early recirculation period.
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PMID:Staurosporine, a novel protein kinase C inhibitor, prevents postischemic neuronal damage in the gerbil and rat. 238 38

The present study was designed to examine the relation between the loss of Ca2+ uptake activity and the change of protein phosphorylation in sarcoplasmic reticulum from ischemic myocardium. Ischemic (0.5, 1 and 2 h duration) and non-ischemic tissue samples were taken from the coronary-ligated porcine left ventricle and sarcoplasmic reticulum fractions were isolated. The membranes were tested for Ca2+ uptake and ATPase activities and phosphorylation of phospholamban. The in vitro 32P incorporation into phospholamban in the presence of cAMP plus the catalytic subunit of cyclic AMP dependent protein kinase became markedly reduced depending on the duration of ischemia. The activities of the Ca2+ pump (Ca2+ uptake and ATPase) were also decreased. The 32P incorporation into the myofibrillar component troponin I, which is also a specific substrate for catalytic subunit, was not affected by ischemia. The reduction of the Ca2+ pump activity correlated with the reduction of 32P incorporation into phospholamban. It is postulated that the ischemia induced inactivation of the Ca2+ pump is not only a consequence of specific loss of enzyme activity, but it is also caused by altered characteristics of phospholamban.
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PMID:Calcium transport and phospholamban in sarcoplasmic reticulum of ischemic myocardium. 252 77

Protein phosphorylation was evaluated in a rabbit spinal cord ischemia model under conditions where cyclic AMP-dependent protein kinase (PK-A) and calcium/phospholipid-dependent protein kinase (PK-C) were activated. One hour of ischemia did not affect PK-A activity significantly; however, PK-C activity was reduced by more than 60%. In vitro phosphorylation of endogenous proteins by endogenous PK-C revealed that eight particulate and five cytosolic proteins showed stimulated phosphorylation by PK-C activators in control tissue, although this stimulation was virtually absent in ischemic samples. When control and ischemic particulate fractions were combined, the endogenous protein phosphorylation pattern under PK-C-activating conditions was similar to the ischemic sample, which suggests that inhibitory molecules may be present in the ischemic particulate fraction. In vitro phosphorylation of endogenous proteins under PK-A-activating conditions in ischemic tissue was similar to that in control tissue. The results suggest that the PK-C phosphorylation system is selectively impaired in ischemic spinal cord. In addition to reduced PK-C-dependent phosphorylation, an Mr 64,000 protein was phosphorylated in ischemic cytosolic samples, but not in control samples. The phosphorylation of the Mr 64,000 protein was neither PK-C-dependent nor PK-A-dependent. These altered phosphorylation reactions may play critical roles in neuronal death during the course of ischemia.
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PMID:Reduced protein kinase C activity in ischemic spinal cord. 254 9

The calmodulin content in cardiomyocyte cytosol of hypoxic myocardium is increased compared to normal level. This is unaccompanied by differences in the stimulating effect of calmodulin on Ca2+ transport in sarcoplasmic reticulum (SR) of ischemic heart. The decrease of the endogenous cAMP-dependent protein kinase activity in ischemia is associated with the lowered resistance to trypsinolysis of Ca2+ transport in SR (trypsin/microsomal protein ratio is 1:10) with simultaneous Ca-ATPase activation. In the presence of exogenous protein kinase and cAMP the protective effect of phosphorylation on Ca2+ transport in SR vesicles of hypoxic cardiomyocytes treated with trypsin for 10 min reaches the same level as in intact heart.
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PMID:[cAMP, calmodulin-dependent stimulation and stability to proteolysis of Ca 2+ transport in the heart sarcoplasmic reticulum]. 256 Dec 65

Changes in compartmentation and specific mechanism in acute myocardial failure due to global ischemia and in regional myocardial ischemia in dog hearts are described. Ischemic failure was produced by periodic arrest of flow to supported heart preparations perfused with a fluorocarbon (FC-43). Sarcolemmal vesicles (SL) prepared from ischemic failing heart preparations exhibited diminished Ca++ binding and phosphorylation. TA-064, a beta-1-agonist partially abolished the reduction in Ca++ binding and phosphorylation of SL vesicles. The addition of cyclic-AMP (cAMP) and of protein kinase (PK) increased phosphorylation of SL vesicles obtained from non failing heart preparations. Combination of cAMP and of PK had the greatest effect. In contrast to myocardial failure, myocardial infarction is known to produce a large variety of specific disturbances in intermediary cardiac metabolism. Apparently in ischemic failing heart preparations, Ca++ binding and phosphorylation by SL are deficient. The results with TA-064 and isoproterenol suggest that phosphorylation of SL may play a role in the positive inotropic effect of beta-1-agonists.
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PMID:Compartmentation and functional mechanisms in myocardial failure and myocardial infarction. 352 63

Catecholamines play a major role in the induction of cardiac rhythm disorders. The effects of catecholamines are caused by activation of beta-receptors in the heart and appear to be mediated by the cyclic AMP/protein kinase system. Increased rate of spontaneous diastolic depolarization of cardiac fibers on exposure to endogenous or exogenous catecholamine activity leads to tachyarrhythmias. Because of non-uniform distribution of sympathetic nerve endings, activation of the sympathetic nerve system may result in non-uniform reduction in the refractory period leading to re-entrant excitation. Under abnormal conditions myocardium may become more sensitive to catecholamines. In ischemia, sympathetic stimulation causes more local differences in refractory period and a greater tendency to fibrillate. Following acute coronary ligation there is a direct relationship between rhythm disturbance and levels of myocardial catecholamines. Catecholamines not only cause arrhythmia but also contribute to the development of digitalis-induced arrhythmias. The role of catecholamines in the genesis of certain cardiac arrhythmias is further supported by the fact that beta-blocking drugs which antagonize sympathetic activity are effective for treating various types of acute arrhythmias and for prevention of recurrent arrhythmias.
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PMID:Role of catecholamines in the genesis of arrhythmias. 625 84


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