Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0022116 (ischemia)
 91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Ubiquitin-protein conjugates in the hippocampus were analyzed by immunoblotting with a monoclonal anti-ubiquitin antibody. In the CA1 region, Triton X-100 insoluble ubiquitin-protein conjugates increased after 24 hr following 20 min of ischemia. When the total hippocampi were fractionated subcellularly, ubiquitin-protein conjugates increased in the particulate, especially in the mitochondrial fraction. The ubiquitin-protein conjugates were solubilized by SDS, or were partially solubilized by urea. The results indicate that insoluble ubiquitin-protein conjugates increase after ischemia.
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PMID:Subcellular distribution of ubiquitin-protein conjugates in the hippocampus following transient ischemia. 132 64

Triton X-100-, digitonin- and urea-insoluble ubiquitin conjugates (UC) in the mitochondrial fractions of the gerbil cortex and hippocampus were analysed. In the cortex, following 5 min of forebrain ischemia, UC increased at 30 min of reperfusion and returned to the control level at 24 h. Although chronological changes in UC in the hippocampus were similar to the cortex, a more sustained increase of UC was observed. Immunoblot analysis showed that UC above 50 kDa increased in both regions. The results indicate that insoluble UC increase in the early recovery stage after ischemic neuronal damages.
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PMID:Post-transient ischemia increase in ubiquitin conjugates in the early reperfusion. 132 67

Hypothermia was first applied therapeutically as a local anesthetic and later was used to achieve organ protection during procedures necessitating circulatory interruption. Profound whole-body hypothermia, typically carried out in conjunction with extracorporeal bypass, has long been employed during cardiac and neurosurgical operative procedures. More recently, studies in small-animal experimental models of cerebral ischemia have provided persuasive evidence that even small decreases in brain temperature confer striking protection against ischemic neuronal injury. By contrast, small elevations of brain temperature during ischemia accelerate and extend pathologic changes in the brain and promote early disruption of the blood-brain barrier. Hypothermia retards the rate of high-energy phosphate depletion during ischemia and promotes postischemic metabolic recovery. More importantly, mild intraischemic hypothermia markedly attenuates the release of glutamate into the brain's extracellular space and significantly diminishes the release of dopamine. Similarly, the inhibition of calcium-calmodulin-dependent protein kinase II triggered by normothermic ischemia is prevented by hypothermia, as is the ischemia-induced translocation and inhibition of the key regulatory enzyme protein kinase C. Hypothermia also appears to facilitate the resynthesis of ubiquitin following ischemia. Studies of potential clinical importance have shown that moderate hypothermia is capable of attenuating ischemic damage even if instituted early in the postischemic period. In the setting of focal cerebral ischemia, moderate brain hypothermia reduces the infarct size (particularly in the setting of reversible middle cerebral artery occlusion); conversely, hyperthermia markedly increases the infarct volume. These studies underscore the importance of monitoring and regulating the brain temperature during experimental studies of cerebral ischemia to insure a consistent pathologic outcome and to avoid the false attribution of "pharmacoprotection" to drugs that reduce the body temperature. The measurement of brain temperature is now practicable in neurosurgical patients requiring invasive monitoring, and human studies have shown that cortical and cerebroventricular temperatures may exceed systemic temperatures. Mild to moderate decreases in brain temperature are neuroprotective in cerebral ischemia, while mild elevations of brain temperature are markedly deleterious in the setting of ischemia or injury. It is anticipated that controlled clinical trials of therapeutic brain temperature modulation will be undertaken over the next several years.
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PMID:Therapeutic modulation of brain temperature: relevance to ischemic brain injury. 138 56

Recent studies have shown that the principal component of the senile plaque in Alzheimer's disease (AD), beta-amyloid protein (beta AP) can exert direct and indirect neurotoxicity in vitro. Because of the studies that demonstrated potentiation of excitatory amino acid toxicity by beta AP, we decided to test whether beta AP was able to potentiate damage in an in vivo model where excitotoxic damage is thought to be important. The present study evaluated the in vivo effects of beta AP implants in the brain of rats before and after being subjected to 10 min of transient global forebrain ischemia by 4-vessel occlusion (4-VO). Implants of either synthetic beta AP or prolactin (PRL), which was used as a control protein, were made into the striatum and the hippocampus of either the left (beta AP) or the right (PRL) cerebral hemisphere. The implants were made in a lipophilic, non-toxic vehicle so as to try and achieve sustained beta AP exposure. One group of animals was evaluated for direct in vivo effects within 1 week following implantation; the other group was subjected to 4-VO 3-4 days post-implantation for evaluation of potential indirect effects. This latter group was compared to the histopathology of animals subjected to 4-VO without prior implantation. In the group of animals evaluated for direct effects, no evidence of neurotoxicity was observed. Bielschowsky silver staining and immunostaining for ubiquitin were unremarkable in all lesions. beta AP was detected by immunocytochemistry in the parenchymal tissue that received beta AP implants. Marked glial activation was observed to be associated with experimental and control implants. Under the experimental conditions employed in this study, significant protection from ischemia rather than potentiation of damage was observed. These results suggest that beta AP may not be neurotoxic in rodents in vivo and that the lesions and/or trauma produced by the implantation procedure 3-4 days prior to 4-VO may have induced factors that were protective against ischemia-induced damage.
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PMID:In vivo effects of beta-amyloid implants in rodents: lack of potentiation of damage associated with transient global forebrain ischemia. 152 Nov 57

Ubiquitin is involved in the degradation of denatured proteins in the recovery process after various stresses. To clarify the different responses of the ubiquitin system in the hippocampal neurons after ischemia, we chose 7.5 min of sublethal forebrain ischemia in the rat. After 7.5 min of ischemia, ubiquitin-like immunoreactivity (UIR) in most of the hippocampal pyramidal cells, except for the interneurons, diminished after 3 h of reperfusion, but enhanced UIR and subsequent recovery of UIR were observed in the different hippocampal regions after 24 h of reperfusion. The most prolonged recovery of UIR in the hippocampal cells was observed in the CA1 neurons after 72 h of reperfusion. Immunoblot analysis of the proteins extracted from CA1 region showed that high-mol-wt ubiquitin conjugates (HMWUC) above 40 kDa increased, whereas free ubiquitin and ubiquitinated histone 2A decreased slightly after 4 h and 24 h of reperfusion. At 72 h of reperfusion, HMWUC decreased to the original level and free ubiquitin slightly increased beyond the control level. These results suggested that (1) diminished UIR does not always mean depletion of entire ubiquitin-protein conjugates; (2) even after sublethal ischemia, damaged proteins in the CA1 neurons may increase, and it may take a long time for elimination of these proteins.
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PMID:Changes in ubiquitin and ubiquitin-protein conjugates in the CA1 neurons after transient sublethal ischemia. 166 59

A number of studies have demonstrated increased synthesis of heat shock proteins in brain following hyperthermia or transient ischemia. In the present experiments we have characterized the time course of heat shock RNA induction in gerbil brain after ischemia, and in several mouse tissues after hyperthermia, using probes for RNAs of the 70-kilodalton heat shock protein (hsp70) family, as well as ubiquitin. A synthetic oligonucleotide selective for inducible hsp70 sequences proved to be the most sensitive indicator of the stress response whereas a related rat cDNA detected both induced RNAs and constitutively expressed sequences that were not strongly inducible in brain. Considerable polymorphism of ubiquitin sequences was evident in the outbred mouse and gerbil strains used in these studies when probed with a chicken ubiquitin cDNA. Brief hyperthermic exposure resulted in striking induction of hsp70 and several-fold increases in ubiquitin RNAs in mouse liver and kidney peaking 3 h after return to room temperature. The oligonucleotide selective for hsp70 showed equivalent induction in brain that was more rapid and transient than observed in liver, whereas minimal induction was seen with the ubiquitin and hsp70-related cDNA probes. Transient ischemia resulted in 5- to 10-fold increases in hsp70 sequences in gerbil brain which peaked at 6 h recirculation and remained above control levels at 24 h, whereas a modest 70% increase in ubiquitin sequences was noted at 6 h. These results demonstrate significant temporal and quantitative differences in heat shock RNA expression between brain and other tissues following hyperthermia in vivo, and indicate that hsp70 provides a more sensitive index of the stress response in brain than does ubiquitin after both hyperthermia and ischemia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Heat shock RNA levels in brain and other tissues after hyperthermia and transient ischemia. 168 18

The hippocampus is a brain structure specifically vulnerable to short periods of transient cerebral ischemia, and which displays delayed neuronal necrosis. Protein ubiquitination is a posttranslational modification of proteins and an important factor in heat shock response and a regulator of ATP-dependent protein degradation. Using affinity purified antibodies against ubiquitin and ubiquitin-protein conjugates we have found that the ubiquitin immunoreactivity (UIR), normally present in all neurons of the hippocampus, disappears in the early recirculation period following cerebral ischemia from all hippocampal cells except the interneurons. Later UIR reappears in the different hippocampal regions over a 72 h period in the following order: granule cells-CA3 pyramidal cells-CA2 pyramidal cells. This is the inverse order of sensitivity of these cells to ischemia. The UIR never recovers in the CA1 pyramidal neurons where a 95% neuronal necrosis is seen following three days of recovery. We propose that the loss of UIR in the pyramidal neurons in the CA1 region signifies a persistent impairment of protein ubiquitination, and thus a change in the turnover of structural and regulatory proteins, which could be an essential part of the mechanism of slow neuronal death following cerebral ischemia.
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PMID:Impairment of protein ubiquitination may cause delayed neuronal death. 254 80

The possible protective effect of heat-shock proteins (HSPs) on ischemic injury to renal cells was assessed in two different experimental models: ischemia-reflow in intact rats and medullary hypoxic injury as seen in the isolated perfused rat kidney. Heat shock was induced by raising the core temperature of rats to 42 degrees C for 15 minutes. Following this, Northern blots showed enhanced gene expression of HSP70, HSP60 and ubiquitin at one hour and reaching a maximum by six hours after heat shock in all regions of the kidney, but most prominently in medulla and papilla. The HSP70 protein in the kidney, estimated by immunohistochemical means, was detectable 24 hours following heat shock and further increased at 48 hours following heat shock. In the first set of experiments, the animals underwent uninephrectomy followed by cross clamping of the remaining renal artery for 40 minutes prior to reflow. Serum creatinine and urea nitrogen rose to 3.15 +/- 0.98 and 126.4 +/- 62.5 mg/dl at 24 hours. No significant differences were observed at 24, 48 and 72 hours after reflow between these values in control rats and rats pretreated with heat shock 48 hours earlier. Severe morphological damage to proximal tubules of the renal cortex was observed to the same extent in both groups. In a second set of experiments, the right kidney was removed either 24 or 48 hours after heat shock and perfused in isolation for 90 minutes. Functional and morphological parameters were compared with those of isolated perfused kidneys obtained from animals that had not been subjected to heat shock.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Induction of heat-shock proteins does not prevent renal tubular injury following ischemia. 764 46

Ubiquitin-conjugating activities in the soluble fractions of gerbil cortex and hippocampus following transient ischemia were examined in vitro. Ten minutes of ischemia did not affect the ubiquitination of heat-denatured lysozyme both in the cortex and in the hippocampus. No reduction of the conjugating activities following ischemia was also confirmed using the partially purified ubiquitin conjugating enzymes from the cortex. These results indicate that protein ubiquitination might not be impaired following transient ischemia.
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PMID:Lack of effect of transient ischemia on ubiquitin conjugation. 765 75

Immediate early gene (IEG) products, such as FOS and JUN, may partially mediate the long-term transcriptional response of CNS cells to specific changes in their environment. To determine whether IEG products might be involved in the immature brain's response to hypoxia-ischemia (H-I), 7-day-old rat pups were subjected to unilateral common carotid artery ligation followed by 3 h of hypoxia (8% O2/92% N2) at 37 degrees C, which results in pathological changes only in specific regions of the hemisphere ipsilateral to ligation. Time course experiments were performed, in which animals were sacrificed between 1 and 24 h after H-I. RNAs from several brain regions were analyzed by Northern blot hybridization for their relative concentrations of nine IEG mRNAs (c-fos, c-jun, junB, TIS 1 (nur77), TIS7, TIS8 (zif268), TIS10, TIS11, and TIS21). Induction of all IEGs, except TIS7 and TIS10, was observed in ipsilateral forebrain, and, less frequently, in contralateral forebrain, at 1, 2, and 3 h post-hypoxia. In some animals, lower levels of expression were also detected at 4, 18 and 24 h. With minor exceptions, co-induction of all seven IEGs was observed in a given RNA sample. Induction of two other mRNAs, representing the heat shock and astrocytic responses, were also observed. Hsp70 mRNA levels were increased only in the brains of animals exhibiting IEG induction. However, hsp70 induction was confined to the ipsilateral forebrain, implying a more direct relationship between its expression and permanent morphological damage. GFAP mRNA induction occurred predominantly in ipsilateral forebrain samples at 18 and 24 h post-hypoxia. Levels of B-actin and ubiquitin mRNAs were relatively constant in the same RNA samples. In control experiments c-fos mRNA induction was not detected after sham ligation with hypoxia, ligation with sham hypoxia, or hypoxia alone. These results suggest that the immature brain is highly responsive to H-I at the level of gene expression, involving at least three different rapid response systems.
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PMID:Immediate early gene induction after neonatal hypoxia-ischemia. 768 83


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