UMLS:C0022116 - FACTA Search

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Query: UMLS:C0022116 (ischemia)
91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Calcium/calmodulin-dependent protein kinase II (CaM-kinase) is a central enzyme in regulating neuronal processes. Imbalances in the activity and distribution of this enzyme have been reported following in vivo ischemia, and sustained decreases in activity correlate with subsequent neuronal death. In this report, mice that had been rendered deficient in the alpha subunit of CaM-kinase using gene knock-out technology were utilized to determine whether this enzyme is causally related to ischemic damage. Using a focal model of cerebral ischemia, we showed that homozygous knock-out mice lacking the alpha subunit exhibited an infarct volume almost twice that of wild-type litter mates. Heterozygous mice exhibited slightly less damage following ischemia than did homozygous mice, but infarct volumes remained significantly larger than those of wild-type litter mates. We conclude that reduced amounts of the alpha subunit of CaM-kinase predisposes neurons to increased damage following ischemia and that any perturbation that decreases the amount or activity of the enzyme will produce enhanced susceptibility to neuronal damage.
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PMID:Ischemia-induced neuronal damage: a role for calcium/calmodulin-dependent protein kinase II. 853 May 41

The change in the subcellular distribution of Ca2+/calmodulin-dependent protein kinase II was studied in the rat hippocampus following normothermic and hypothermic transient cerebral ischemia of 15 min duration. A decrease in immunostaining of Ca2+/calmodulin-dependent protein kinase II was observed at 1 h of reperfusion which persisted until cell death in the CA1 region. In the CA3 and dentate gyrus areas immunostaining recovered at one to three days of reperfusion. The CA2+/calmodulin-dependent protein kinase II was translocated to synaptic junctions during ischemia and reperfusion which could be due to a persistent change in the intracellular calcium ion homeostasis. The expression of the messenger RNA of the alpha-subunit of Ca2+/calmodulin-dependent protein kinase II decreased in the entire hippocampus during reperfusion, and was most marked in the dentate gyrus at 12 h of reperfusion. This decrease could be a feedback downregulation of the mRNA due to increased Ca2+/calmodulin-dependent protein kinase II activation. Intraischemic hypothermia protected against ischemic neuronal damage and attenuated the ischemia-induced decrease of Ca2+/calmodulin-dependent protein kinase II immunostaining in all hippocampal regions. Hypothermia also reduced the translocation of Ca2+/calmodulin-dependent protein kinase II and restored Ca2+/calmodulin-dependent protein kinase II alpha messenger RNA after ischemia. The data suggest that ischemia leads to an aberrant Ca2+/calmodulin-dependent protein kinase II mediated signal transduction in the CA1 region, which is important for the development of delayed neuronal damage. Hypothermia enhances the restoration of the Ca2+/calmodulin-dependent protein kinase II mediated cell signalling.
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PMID:Alterations of Ca2+/calmodulin-dependent protein kinase II and its messenger RNA in the rat hippocampus following normo- and hypothermic ischemia. 854 77

Cardiac arrest induced rat brain ischemia of 15 min duration produces a rapid and profound decrease in activity of calcium/calmodulin stimulated protein kinase (CaM-KII). In contrast to that, the total amount of enzyme protein remains stable as revealed by Western blotting (alpha subunit specific) analysis. Ischemic insult also results in translocation of the enzyme toward plasmatic membranes, reducing its content in soluble (cytosolic) fraction down to 7% with respect to 50% of control. The qualitatively similar translocation can be achieved by autophosphorylation of the control enzyme in vitro. Moreover, severely reduced response of immunoprecipitated enzyme to autophosphorylation observed after ischemia ex vivo probably reflects the higher level of its endogenous phosphorylation during the insult. The results strongly suggest that among various possible mechanisms of postischemic CaM-KII inhibition the most probable would be that involving abnormal or irreversible phosphorylation of the enzyme molecule. It would consequently block or inhibit the autophosphorylation/dephosphorylation cycle of endogenous CaM-KII interconversion necessary for its full catalytic activity.
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PMID:Autophosphorylation as a possible mechanism of calcium/calmodulin-dependent protein kinase II inhibition during ischemia. 871 6

The activity of Ca2+/calmodulin-dependent protein kinase II (CaM-KII) during short-term global ischaemia was investigated in the gerbil brain hippocampus and cortex. Ischaemia of 0.5 min duration significantly stimulated Ca(2+)-independent 'autonomous' activity, indicating activation of the first step of intramolecular enzyme phosphorylation just after ischaemia has developed. Prolongation of the ischaemic period up to 5 min inhibited both Ca(2+)-dependent and, to a lesser extent, Ca(2+)-independent activities of CaM-KII. These last events coincide with an extensive translocation of CaM-KII protein from the soluble to the membranous fraction. In effect, in spite of inhibition of total CaM-KII activity, its Ca(2+)-independent, persistently active component can still remain more abundant at specific membrane regions.
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PMID:Brain ischaemia transiently activates Ca2+/calmodulin-independent protein kinase II. 873 Aug 47

The putative osmoregulatory agent, taurine, is lost from the brain during hypo-osmotic stress or ischemia, but the regulatory mechanisms involved in this loss have not been fully elucidated. In this study, we have examined taurine transport by the isolated rat choroid plexus, one element of the brain-blood interface, and examined how it may be regulated as part of brain volume regulation. Choroid plexus taurine uptake was Na- and Cl-dependent with a Vmax and Km of 6.5 +/- 0.3 pmol/mg/min and 232 +/- 33 microM. The latter is substantially greater than the normal CSF taurine concentration and this may be important in removing taurine released into the CSF during parenchymal cell swelling. Taurine uptake also appears calmodulin dependent as it was reduced by 84 and 91% in the presence of 25 microM trifluoperazine and 100 microM W-7, two calmodulin inhibitors. Taurine efflux from choroid plexus was stimulated by trifluoperazine, taurine, and hypo-osmotic stress. The latter two effects were reduced by niflumic acid, suggesting that taurine and hypo-osmotic stress act on the same pathway. The stimulation of efflux by hypo-osmotic stress decreased with time, whereas the effect of external taurine was sustained. If this efflux pathway is involved in the movement of taurine from choroid plexus to blood, these results suggest that changes in extracellular taurine may be more important than the direct effect of hypo-osmolality in the long-term loss of taurine from the brain.
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PMID:Choroid plexus taurine transport. 873 18

It is generally accepted that microvascular permeability is controlled by intercellular endothelial cell gap size. This process is controlled in endothelial cell monolayers and peripheral blood vessels by calmodulin (CaM)-dependent myosin light-chain kinase (MLCK), which phosphorylates MLC20 with subsequent actin-myosin interaction. In the present study both CaM and MLCK blockers were studied during ischemia-reperfusion (I/R)-induced injury in isolated buffer-perfused rat lungs. The effects of a calcium ionophore (CaI) were tested in isolated intact rat lungs to compare the effects of increasing intracellular Ca2+ to I/R-induced damage. Because protein kinase C (PKC) could also be a mediator of I/R injury, a PKC inhibitor was studied in lungs subjected to either I/R or CaI. In lungs subjected to I/R alone, a fivefold increase in microvascular permeability occurred after 30 min of reperfusion (P < 0.001), and a tenfold increase was present after an additional 60 min of reperfusion (P < 0.01). Pretreatment of the I/R lungs with a CaM inhibitor (trifluoperazine, 100 microM) or with a MLCK inhibitor (ML-7,500 nM) blocked the microvascular damage at both 30 and 90 min of reperfusion. When the CaM inhibitor was introduced into the venous reservoir after 46 min of reperfusion, after the microvascular damage was present, no further increase in microvascular permeability occurred. Pretreatment of the lungs with a PKC inhibitor (staurosporine, 100 nM) did not alter the magnitude of the increased microvascular permeability produced by I/R or the time course of the damage. The calcium ionophore A23187 (7.5 microM) caused increases in Kfc values similar to those produced by I/R. Pretreatment of A23187-treated lungs with a CaM inhibitor produced no protective effect on the microvascular injury at 30 min after administration. Pretreatment of the CaI-challenged lungs with staurosporine significantly increased the microvascular barrier injury at 30 min compared with that occurring with I/R. When a beta-adrenergic receptor agonist (isoproterenol, 10 microM) was introduced to the lung after CaI-induced damage had occurred, no further increase in microvascular permeability was observed, and a trend toward reversal of injury occurred. We conclude from these studies that CaM/MLCK/MLC20 system is involved in our model of I/R-induced rat lung injury but is not involved in lung injury associated with Ca2+ entering the cell.
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PMID:Role of calmodulin and myosin light-chain kinase in lung ischemia-reperfusion injury. 876 Jan 41

During transient cerebral ischemia, intracellular calcium increases initiating a cascade of events which leads to the delayed death of neurons located in the hippocampus. Coupled to this calcium disturbance is the rapid decrease of calcium/calmodulin kinase II (CaM kinase) activity, a protein kinase critical to neuronal functioning. The present study correlated the increased locomotor activity following ischemic insult with alterations in CaM kinase mRNA levels and immunocytochemical labeling of alpha and beta CaM kinase subunits in the hippocampus. The protective effect of hypothermia was also compared with CaM kinase mRNA levels and immunoreactivity. Levels of CaM kinase message for either alpha or beta subunits was not altered in ischemic gerbils compared to sham or hypothermic ischemic conditions. Immunoreactivity for both the alpha and beta subunits was markedly reduced in the vulnerable CA1 region of ischemic animals compared to sham controls. Gerbils that underwent the ischemic insult while hypothermic showed no decrement in staining. CaM kinase-like immunoreactivity in the ischemia-resistant CA3 sector was not altered following ischemia. These data suggest that the loss of hippocampal CaM kinase immunoreactivity observed at 24 h following ischemia is not associated with a reduction in CaM kinase mRNA levels and support the notion that the rapid decline in CaM kinase activity following ischemic insult is a result of a posttranslational modification and/or translocation of the enzyme.
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PMID:Transient cerebral ischemia decreases calcium/calmodulin-dependent protein kinase II immunoreactivity, but not mRNA levels in the gerbil hippocampus. 882 62

Compartmentalization of protein kinases and association of the enzyme with strategic cellular substrates may be important for regulating signal transduction in neurons. Cerebral ischemia produced by transient 20 min occlusion of common carotid and vertebral arteries in rats caused a dramatic (3-fold) increase in Ca2+/Calmodulin-dependent protein kinase II (CaM-KII) in the fraction enriched in postsynaptic density (PSDf), the compartment of the neuron that is involved in signal transduction. This change in compartmentalization was not reversible for up to 24 h after termination of the occlusion and was followed by reduction of CaM-KII to 50% of control content one week after the insult. The observed changes in CaM-KII content did not represent general protein redistribution in PSDf after ischemia since there were no parallel changes in PSDf actin concentration. The redistribution of CaM-KII coincided with gradual (up to 80%) reduction of its activity in PSDf as tested using specific peptide substrate and endogenous CaM-KII substrates. This work provides evidence that ischemia disturbs CaM-KII distribution and activity in PSDf and this may lead to long lasting disruption of signal transduction at the synaptic level.
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PMID:Ca2+/calmodulin-dependent protein kinase II in postsynaptic densities after reversible cerebral ischemia in rats. 886 62

Not all possible mediators of lung I/R injury that have been studied, such as cyclooxygenase and lipoxygenase products, have been presented in this review, but it is very clear that oxygen free radicals are the primary mediators of the damage, regardless of their origin. Oxygen radicals are generated by neutrophils, which are sequestered and activated in the ischemic-reperfused pulmonary tissue, and by xanthine oxidase, which is upregulated by ischemia and/or activated neutrophils. The contributions to lung injury by different species of oxygen radicals may very depending upon the lung model used to study I/R. Also, nitric oxide may be injurious or protective in lung I/R injury, depending upon some critical alveolar PO2 level present either during ischemia or at reperfusion. I/R-induced lung microvascular injury ultimately depends upon some balance between lung metabolic stress, the extent of the I/R-induced inflammatory response, endogenous antioxidant levels, and the timing, magnitude, and duration of oxygen free radical generation during both periods of ischemia and reperfusion. The final common pathway causing microvascular permeability to increase after lung I/R is the activation of the endothelial cell's contractile machinery. Particularly, endothelial contraction may occur in a MLCK-dependent fashion. Endothelial contraction may also be related to an intracellular Ca++ increase and subsequent calmodulin activation. The initiating event causing increased intracellular Ca++ is not known, but may be due to endothelial cell/leukocyte interactions, oxygen radical-mediated Ca++ transients, mobilization of intracellular Ca++ pools by various second messengers, or stimulation of Ca++ influx secondarily to changes in the activity of membrane ion pumps such as the Na+/H+ antiport. Increasing cAMP levels in the postischemic lung can prevent and actually reverse I/R-induced microvascular injury, by affecting MLCK, the endothelial cell cytoskeleton, and/or the function of sequestered leukocytes. Also, cAMP elevation aids the resolution of pulmonary edema by facilitating capillary fluid reabsorption. Whatever the mechanism, elevation of cAMP in the setting of lung I/R injury represents a potentially useful therapy for improving early lung function following lung transplantation. Finally, additional studies are necessary to elucidate the complete mechanisms responsible for producing microvascular injury during lung I/R. Specifically, a better understanding of the relationships between the many factors required to produce lung damage is needed. Many interventions into the lung I/R process provide protection against microvascular injury, suggesting that regulation of the endothelial barrier permeability to fluid, protein, and leukocytes is accomplished by several redundant systems. This situation may be similar to mechanisms reported to regulate the immune response mediated by T cells (62a), where T cell activation depends upon multiple signal inputs for the full immune response to occur. Thus, multiple signals in a correct sequence delivered to the endothelium may be necessary to produce the microvascular injury associated with lung ischemia and reperfusion.
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PMID:Endothelial damage caused by ischemia and reperfusion and different ventilatory strategies in the lung. 890 6

Ischemia-reperfusion injury increases vascular permeability in part by generating reactive oxygen species that disassemble the endothelial cell actin dense peripheral band. This is followed by an increase in the number and diameter of intercellular gaps. Millimolar concentrations of reactive oxygen metabolites lead to nonspecific endothelial cell injury, but micromolar concentrations activate inflammatory second messenger cascades which produce distributional changes in endothelial cell cytoskeletal proteins. H2O2 (100 microM) causes translocation of filamin, from the membrane to the cytosol within 1 min. Subsequently, gap formation occurs within 10-25 min, which is attributed to rearrangement of the dense peripheral band of F-actin. Plasma membrane blebbing occurs after 90 min and decreases in mitochondrial activity occur after 1-2 h. Deferoxamine (iron chelator) and TEMPO (nonspecific free radical scavenger) inhibit these changes. H2O2 (100-1000 microM) does not increase endothelial cell intracellular Ca2+ through 30 min and pretreating cells with a Ca2+-calmodulin kinase inhibitor or an intracellular Ca2+ chelator does not prevent filamin translocation. Filamin redistribution and actin rearrangement are early events in H2O2-mediated endothelial cell injury that appear to occur through Ca2+-independent pathways.
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PMID:Filamin redistribution in an endothelial cell reoxygenation injury model. 903 34

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