UMLS:C0022116 - FACTA Search

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Query: UMLS:C0022116 (ischemia)
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Thresholds of induction of heat shock protein (HSP) 70 and heat shock cognate protein (HSC) 70 mRNAs after transient global ischemia in gerbil brain were investigated by in situ hybridization using cloned cDNA probes selective for each mRNA species. In sham control brain, HSP70 mRNA was little present, while HSC70 mRNA was present in most cell populations. A 0.5-min occlusion of bilateral common carotid arteries did not affect the amount of HSP70 and HSC70 mRNAs. The selective induction of HSC70 mRNA was observed in dentate granule cells at 1 h, and in most cells of hippocampus especially dentate gyrus at 3 h after 1 min of ischemia when induction of HSP70 mRNA was not evident in the identical brain. The selective induction diminished by 2 days. However, after 2 min of ischemia, HSP70 and HSC70 mRNAs were induced together in hippocampal cells from 1 h of the reperfusion, and the co-induction prolonged in CA1 cells until 2 days. Body temperatures monitored at rectum increased after the reperfusion with a peak at 30 min. The degree of increase of the body temperature was significantly higher in the case after 2-min ischemia than in the cases after 0.5- and 1-min ischemia. Although HSP70 and HSC70 mRNAs are generally co-induced in stressful conditions, our results suggest the different thresholds of the induction between HSP70 and HSC70 mRNAs after transient brain ischemia. The selective induction of HSC70 mRNA which is not accompanied by the induction of HSP70 mRNA may relate to the differences of the duration of ischemia and the degree of the increase of body temperature after ischemia.
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PMID:Different thresholds of HSP70 and HSC70 heat shock mRNA induction in post-ischemic gerbil brain. 129 Oct 30

Distributions of heat shock protein (HSP)-70 mRNAs and heat shock cognate protein (HSC)-70 mRNAs after 10 min of transient global ischemia were investigated in gerbil forebrain by in situ hybridization using cloned cDNA probes selective for the mRNAs. Expression of HSP70 immunoreactivity was also examined in the same brains. In hippocampal CA1 neuronal cells, in which only a minimal induction of immunoreactive HSP70 protein was found, the strong hybridization for HSP70 mRNA disappeared at around 2 days before the death of CA1 cells became evident. Furthermore, in hippocampal CA3 cells, a striking induction of HSP70 mRNA was sustained even at 2 days along with a prominent accumulation of HSP70 immunoreactivity. In contrast to the case of HSP70 mRNA, HSC70 mRNA was present in most neuronal cells, especially dense in CA3 cells, of the sham brain. A co-induction of HSP70 and HSC70 mRNAs was observed in several cell populations after the reperfusion with a peak at 8 h, although the magnitude of HSC70 mRNA induction was lower than that of HSP70 mRNA, particularly in CA1 cells. The expression of HSC70 mRNA in CA1 cells also disappeared at around 2 days. All the induced signals of HSP70 and HSC70 mRNAs in other cell populations were diminished and returned to the sham level, respectively, by 7 days. These results are the first to show the time courses of distribution of HSP70 and HSC70 mRNAs and the immunoreactive HSP70 protein in the same gerbil brain after ischemia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Distributions of heat shock protein-70 mRNAs and heat shock cognate protein-70 mRNAs after transient global ischemia in gerbil brain. 150 43

The distribution of heat shock protein (HSP) 70 and heat shock cognate protein (HSC) 70 mRNA after 30 min of middle cerebral artery (MCA) occlusion was investigated in rat brain by in situ hybridization using cloned cDNA probes selective for the mRNAs. While HSP70 mRNA was hardly present at caudate and dorsal hippocampal levels of the sham brain this mRNA was greatly induced in cells of the MCA territory 1 h after reperfusion. Although the maximum amount of induced HSP70 mRNA in the caudate was much smaller than that in the cortex the maximum induction in the caudate (3 h) preceded that in the cortex (8 h). In contrast to the case of HSP70 mRNA, HSC70 mRNA was present in most cells of the sham brain, and was especially dense in hippocampal CA3 cells. Further induction of HSC70 mRNA was observed after reperfusion in the same cell populations, as in the case of HSP70 mRNA. HSC70 mRNA levels were significantly reduced in the caudate at 8 h when small amounts of HSP70 mRNA were still elevated. In the ipsilateral granule cells of the dentate gyrus and hippocampal CA3 cells a slight but significant induction of HSC70 mRNA was observed from 1 h to 1 day, while obvious induction of HSP70 mRNA never occurred. All the induced signals of HSP70 and HSC70 mRNA were diminished or returned to the sham level by 7 days, except for HSC70 mRNA in the caudate. These results are the first observations of the distribution of HSP70 and HSC70 mRNA after transient focal ischemia of rat brain.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Distributions of heat shock protein (HSP) 70 and heat shock cognate protein (HSC) 70 mRNAs after transient focal ischemia in rat brain. 152 56

To evaluate possible involvement of phospholipid metabolism and related second messenger systems in the selective neuronal damage after ischemia, we measured changes of polyphosphoinositides (PPIs) and free fatty acids (FFAs) in a model of 5-min or 10-min ischemia and reperfusion in gerbils. The binding activity of 3H-phorbol 12,13-dibutyrate (PDBu) for protein kinase C (PKC) and 3H-inositol 1,4,5-triphosphate (IP3) for IP3 receptors was demonstrated autoradiographically. Induction of 70 KDa heat shock protein (HSP70) mRNA and amyloid precursor protein (APP) mRNA was also examined using Northern blot analysis. In the parietal cortex (an area resistant to transient ischemia), PPIs decreased during ischemia and recovered rapidly after reperfusion. However, recovery did not occur in the hippocampal CA1 area (an area more vulnerable to transient ischemia). In the cortex, arachidonic acid (AA) increased during ischemia and returned to baseline by 7 days after reperfusion; in the CA1 area, the AA level remained elevated even after 7 days of reperfusion. PDBu binding decreased in CA1 cells after 2 days of reperfusion. IP3 binding began to decrease at 5 hr of reperfusion, which is far earlier than either the onset of decreased PDBu binding or the observation of neuronal damage by light microscopy. The induction of HSP70 mRNA occurred, but the induction of APP mRNA did not. Regional differences in the induction of HSP70 mRNA were found; CA1 cells produced less HSP70 mRNA than cortical cells 8 hr after transient ischemia. These results suggest that CA1 cell membranes may not recover after transient ischemic attack, and that the membranes of the endoplasmic reticulum, which have IP3 receptors, may undergo alterations earlier than cytoplasmic membranes. The variable induction of HSP70 mRNA may be related to regional differences in vulnerability in cortical and hippocampal CA1 cells after transient ischemia. Involvement of excitatory neurotransmission in the induction of HSP70 has been suggested. The combined data may support a role for inositol phospholipid metabolism, changes in related second messenger systems, and induction of HSP70 in the excitotoxic mechanism of hippocampal CA1 neuronal damage, death, and repair.
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PMID:Phospholipid metabolism and second messenger system after brain ischemia. 163 89

Expression of heat shock proteins (HSPs) occurs in brain after ischemia and status epilepticus. We report that induction of the heat shock response in cortical cultures protects neurons from glutamate-induced excitotoxicity. Cultures heated to 42.2 degrees C for 20 min showed an overall decrease in protein synthesis but an increase in the synthesis of approximately 72 and approximately 85 kd proteins and in the levels of HSP70 mRNA. Heat shock inhibited excitotoxicity in cells exposed to glutamate at 3 or 24 hr following heat exposure, but not when the interval between heat and glutamate exposure was shortened to 15 min or lengthened to 48 hr. Protection due to heat shock required new protein synthesis, since it did not occur when protein or RNA synthesis inhibitors were added. By ameliorating excitotoxic processes, HSPs may attenuate brain injury in certain pathologic conditions.
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PMID:Heat shock protects cultured neurons from glutamate toxicity. 172 11

Heat shock protein (HSP) plays an important role in stress responses of cells. Inductions of HSP70 mRNA, amyloid precursor protein (APP) mRNA, and tubulin mRNA within hippocampal CA1 and parietal cortex in gerbil brains were examined at 1 h to 7 days after 10 min of bilateral common carotid artery occlusion using Northern blot analyses. In contrast to the induction of HSP70 mRNA, no induction was observed in APP mRNA or tubulin mRNA. Regional differences in the induction of HSP70 mRNA were found. CA1 cells produced less amount of HSP70 mRNA than cortical cells at 8 h after the transient ischemia. Transient global ischemia is known to result in the selective neuronal death of hippocampal CA1 cells days after reperfusion. Our results suggest that the regional difference in the induction of HSP70 mRNA may relate to the regional difference of the vulnerability of neuronal cells after transient ischemia.
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PMID:Induction of HSP70 mRNA after transient ischemia in gerbil brain. 190 57

An essential part of gene expression and regulation is the binding of a regulatory protein (transcription factor) to the recognition sequence of the appropriate gene. A novel protein motif for nucleic acid recognition (called 'zinc finger') is one of such transcription factors. A relationship between gene expressions of a transcription factor and heat shock protein (HSP) 70 has been suggested. Possible inductions of mRNA for 'zinc finger' and HSP70 were examined after transient focal ischemia in rat cerebral cortex by Northern blot analysis using a synthetic oligonucleotide probe for 'zinc finger' gene expression, and a human genomic DNA probe for HSP70 gene expression. After 30 min of middle cerebral artery (MCA) occlusion, the rats recovered for 1, 3, 8h, 1, 2, and 7 days (n = 5). Zinc finger gene is normally expressed in rat cerebral cortex, and is induced by transient ischemia with a maximum at 1 h after the reperfusion. In contrast, HSP70 mRNA is not expressed in normal condition, but is greatly induced by transient ischemia with a maximum at 8 h of reperfusion. These results indicate that the gene expression for a transcription factor changes in the early stage of reperfusion after cerebral ischemia before HSP70 induction begins.
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PMID:Induction of the 'zinc finger' gene after transient focal ischemia in rat cerebral cortex. 202 39

Hyperthermia, hypoxia, and other conditions induce the appearance of heat shock or stress proteins in cells. We have previously shown that in the ischemic dog myocardium the level of a messenger RNA (mRNA) coding for a protein with migration characteristics similar to heat shock/stress protein 71 increases. Using a human heat-shock protein (hHSP) 70 genomic clone and anti-HSP70 antibodies as probes, we demonstrate in this report that heart stress protein (SP) 71 mRNA and its translational products (71 kDa polypeptides) are members of the stress protein family. In rabbit hearts, the ischemia-induced mRNAs translate into three isoforms with different isoelectric points (6.0, 6.1, and 6.15), in contrast to dog heart mRNA that translates into a protein with a pI of 5.8. The levels of SP71 mRNA in the dog and rabbit ischemic myocardium increased by sixfold and 18-fold, respectively. In the same samples, the levels of creatine kinase M mRNA decreased by about 40%, whereas those of myosin heavy chain mRNA remain unaltered. Our comparative analysis of three different mRNAs indicates that ischemia manifests its effects by differentially changing the levels of specific mRNAs coding for proteins with separate and distinct roles in the cell.
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PMID:Ischemia induces changes in the level of mRNAs coding for stress protein 71 and creatine kinase M. 340 83

Expression of vascular endothelial growth factor (VEGF), an endothelial cell-specific mitogen and a potent angiogenic factor, is upregulated in response to a hypoxic or hypoglycemic stress. Here we show that the increase in steady-state levels of VEGF mRNA is partly due to transcriptional activation but mostly due to increase in mRNA stability. Both oxygen and glucose deficiencies result in extension of the VEGF mRNA half-life in a protein synthesis-dependent manner. Viewing VEGF as a stress-induced gene, we compared its mode of regulation with that of other stress-induced genes. Results showed that under nonstressed conditions, VEGF shares with the glucose transporter GLUT-1 a relatively short half-life (0.64 and 0.52 h, respectively), which is extended fourfold and more than eightfold, respectively, when cells are deprived of either oxygen or glucose. In contrast, the mRNAs of another hypoxia-inducible and hypoglycemia-inducible gene, grp78, as well as that of HSP70, were not stabilized by these metabolic insults. To show that VEGF and GLUT-1 are coinduced in differentially stressed microenvironments, multicell spheroids representing a clonal population of glioma cells in which each cell layer is differentially stressed were analyzed by in situ hybridization. Cellular microenvironments conducive to induction of VEGF and GLUT-1 were completely coincidental. These findings show that two different consequences of tissue ischemia, namely, hypoxia and glucose deprivation, induce VEGF and GLUT-1 expression by similar mechanisms. These proteins function, in turn, to satisfy the tissue needs through expanding its vasculature and improving its glucose utilization, respectively.
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PMID:Stabilization of vascular endothelial growth factor mRNA by hypoxia and hypoglycemia and coregulation with other ischemia-induced genes. 756 86

Induction of the 70 kDa heat shock protein (HSP70) by hypoxia and/or hypoglycemia and the effects of prior heat shock on injury owing to hypoxia and/or hypoglycemia were studied in rat cerebral endothelial cells. Hypoxia and/or hypoglycemia treatment resulted in increased expression of HSP70 only when such treatment was sufficient to cause detectable injury and when the initial treatment was followed by exposure of the cells to 24 h of normoxia and normoglycemia. Heat shock induced 24 h prior to treatment with 48 h of hypoxia slightly reduced endothelial cell damage as measured by fraction of lactate dehydrogenase release (10% decrease in injury). There was a more dramatic effect of prior heat shock on the moderate damage produced by 12 h of combined hypoxia and hypoglycemia (45% decrease), whereas the severe damage produced by 24 h of hypoxia and hypoglycemia was decreased by prior heat shock by only 16%. These results indicate that the hypoxia and hypoglycemia occurring in conjunction with ischemia are more likely to result in heat shock protein expression when there is injury to the tissue. Furthermore, heat shock protects cerebral endothelial cells from hypoxia and hypoglycemia either by slowing the initial development of injury or by delaying the onset of injury.
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PMID:Amelioration of hypoxic and hypoglycemic damage to cerebral endothelial cells. Effects of heat shock pretreatment. 763 16

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