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)

Striatal enriched phosphatase (STEP) is a family of protein tyrosine phosphatases enriched within the CNS. A member of this family, STEP61, is a membrane-associated protein located in postsynaptic densities of striatal neurons. In this study, we demonstrate that STEP61, is cleaved into smaller isoforms. To clarify the mechanism of cleavage, STEP61 was transiently expressed in NT2/D1 neuronal precursor cells. Exposure of transfected cells to the calcium ionophore, A23187, or to thapsigargin resulted in the rapid cleavage of STEP61. Pretreatment with the calpain inhibitor, calpeptin, or EGTA prevented proteolysis. One of the cleavage products has a relative molecular mass of 33 kDa (STEP33). A protein with the identical mobility is detected following calpain treatment of STEP61 fusion protein or postsynaptic densities purified from rat striatum. Exposure of primary neuronal cultures to glutamate also led to a significant increase in the concentration of a low molecular weight form of STEP. Taken together, these results suggest that in response to a rapid influx of calcium, STEP61, is proteolytically cleaved by calpain, leading to the release of a smaller isoform. This model may explain the rapid appearance of STEP33 in response to transient hypoxia-ischemia in the brain as cells attempt to counter the increase in tyrosine phosphorylation levels following neuronal insults.
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PMID:Calcium-dependent cleavage of striatal enriched tyrosine phosphatase (STEP). 1053 58

Tissue damage resulting from ischemia due to myocardial infarction is thought to be intensified by the proteolytic action of endogenous enzymes. Calpain (calcium dependent cysteine protease) is considered to be a highly likely candidate, since it is activated by calcium ion which increases in concentration under conditions of ischemia. We prepared a mono-specific antibody against the active site histidine stretch, Lys-Leu-Val-Lys-Gly-His-Ala-Tyr-Ser-Val, in the calpain 80 kDa large subunit. The specificity of the antibody was verified by its inhibitory effect on the caseinolytic activity of both mu- and m-calpains, western blotting analysis, and by absorption with the antigen peptide. The antibody was used to localize the intracellular distribution of activated calpains in infarcted regions of the human heart. The results showed that myocardial cells affected by ischemia were stained by the antibody, allowing damaged cells to be distinguished from cells of unaffected regions and that the immunostained regions were essentially the same regions as those identified by dense eosinophilic staining with hematoxylin and eosin. However, the staining pattern obtained with the antibody, was characteristic in denser staining at the cell periphery, whereas the damaged cells were stained homogeneously by hematoxylin and eosin. By the former method, results of staining indicated that the activation site of the calpain proenzyme was in the peri-plasma membrane, whereas by the latter method, diffusely distributed plasma proteins such as albumin and immunoglobulins were visualized as demonstrated in earlier reports.
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PMID:Activation of calpain in myocardial infarction: an immunohistochemical study using a calpain antibody raised against active site histidine-containing peptide. 1072 43

The early release of cardiac markers is influenced by a variety of factors, the most important influence being their intracellular compartmentation. In contrast to the release of cytosolic proteins, the release of structurally bound proteins requires both a leaky plasma membrane and a dissociation or degradation of the subcellular structure, which is a slower process. Another major impact is the susceptibility to the degradation by cytosolic proteases, such as the calpains. The lysosomes are stable within the first 3-4 hours after onset of ischemia, and, therefore, their enzymes are not involved in the early degradation of structurally bound proteins. Troponin I and troponin T are substrates of micro-calpain. Current experimental as well as clinical results suggest that the molecular mass seems to be of minor importance for the pattern of appearance of myocardial proteins in blood after myocardial infarction. However, within the family of molecules with a certain intracellular compartmentation, the molecular mass is an influence on the appearance in blood, because heavier molecules diffuse at a slower rate, and particularly smaller molecules, such as myoglobin, may enter the vascular system to an even larger extent directly via the microvascular endothelium. The higher the concentration gradient of a marker between the cardiomyocytes and the interstitial space, the faster a parameter will translocate from sarcoplasma to the interstitial space as soon as the plasma membrane permeability is increased. Another influence is local blood and lymphatic flow. Recent experimental studies showed that reperfusion causes a true acceleration of cellular protein leakage by an acute manifestation of plasmalemmal disruptions and not just an enhanced wash out. Marker protein time-courses after myocardial damage are also markedly influenced by their disappearance rate from blood. Most proteins appear to be catabolized in organs with a high metabolic rate, such as liver, pancreas, kidneys, and the reticuloendothelial system. Smaller molecules, such as myoglobin, also pass the glomerular membranes of the kidneys and are reabsorbed and subsequently metabolized in tubular epithelial cells.
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PMID:Tissue release of cardiac markers: from physiology to clinical applications. 1072 15

Calpains are ubiquitous Ca(2+)-activated neutral proteases that have been implicated in ischemic and traumatic CNS injury. Ischemia and trauma of central white matter are dependent on Ca2+ accumulation, and calpain overactivation likely plays a significant role in the pathogenesis. Adult rat optic nerves, representative central white matter tracts, were studied in an in vitro anoxic model. Functional recovery following 60 min of anoxia and reoxygenation was measured electrophysiologically. Calpain activation was assessed using western blots with antibodies against calpain-cleaved spectrin breakdown products. Sixty minutes of in vitro anoxia increased the amount of spectrin breakdown approximately 20-fold over control, with a further increase after reoxygenation to >70 times control, almost as much as 2 h of continuous anoxia. Blocking voltage-gated Na+ channels with tetrodotoxin or removing bath Ca2+ was highly neuroprotective electrophysiologically and resulted in a marked reduction of spectrin degradation. The membrane-permeable calpain inhibitors MDL 28,170 and calpain inhibitor-I (10-100 microM) were effective at reducing spectrin breakdown in anoxic and reoxygenated optic nerves, but no electrophysiological improvement was observed. We conclude that calpain activation is an important step in anoxic white matter injury, but inhibition of this Ca(2+)-dependent process in isolation does not improve functional outcome, probably because other deleterious Ca(2+)-activated pathways proceed unchecked.
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PMID:Calpain inhibitors confer biochemical, but not electrophysiological, protection against anoxia in rat optic nerves. 1080 Sep 55

Ischemic epithelial cells are characterized by disruption of intercellular junctions and loss of apical-basolateral protein polarity, which are normally dependent on the integrity of the adherens junction (AJ). Biochemical analysis of both whole ischemic kidneys and ATP-depleted Madin-Darby canine kidney (MDCK) cells demonstrated a striking loss of E-cadherin (the transmembrane protein of the AJ) with the appearance and accumulation of an approximately 80-kDa fragment reactive with anti-E-cadherin antibodies on Western blots of ATP-depleted MDCK cells. This apparent ischemia-induced degradation of E-cadherin was not blocked by either inhibitors of the major proteolytic pathways (i.e., proteasome, lysosome, or calpain), or by chelation of intracellular calcium, suggesting the involvement of a protease capable of functioning at low ATP and low calcium levels. Immunocytochemistry revealed the movement of several proteins normally comprising the AJ, including E-cadherin and beta-catenin, away from lateral portions of the plasma membrane to intracellular sites. Moreover, rate-zonal centrifugation and immunoprecipitation with anti-E-cadherin and anti-beta-catenin antibodies indicated that ATP depletion disrupted normal E-cadherin-catenin interactions, resulting in the dissociation of alpha- and gamma-catenin from E-cadherin and beta-catenin-containing complexes. Because the generation and maintenance of polarized epithelial cells are dependent upon E-cadherin-mediated cell-cell adhesion and normal AJ function, we propose that the rapid degradation of E-cadherin and dissolution of the AJ is a key step in the development of the ischemic epithelial cell phenotype. Furthermore, we hypothesize that the reassembly of the AJ after ischemia/ATP depletion may require a novel bioassembly mechanism involving recombination of newly synthesized and sorted E-cadherin with preexisting pools of catenins that have (temporally) redistributed intracellularly.
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PMID:Selective degradation of E-cadherin and dissolution of E-cadherin-catenin complexes in epithelial ischemia. 1080 98

The differentiated cells seem to share the ability to induce their own death by the activation of an internally encoded suicide program. When activated, this suicide program initiates a characteristic form of cell death called apoptosis. A central challenge in apoptosis research is understanding the mechanisms by which apoptotic cascades are initiated and affected. We tested a potential role for calpain in the programmed cell death under ischemic conditions and found that calpain is (1) activated at a time preceding morphological changes, DNA fragmentation and death, (2) that calpain is translocated to the nucleus before DNA laddering, (3) pretreatment with caspase inhibitors and/or calpain inhibitors block not only the proteolytic actions of the enzyme, but also the cell death process itself in the CA1 subfield after transient global ischemia in a synergistic manner. In conclusion, the present results contribute additional evidence that proteases may play a functional role in apoptotic cell death and extend them to include the possibility that endogenous proteases are capable of inducing the striking DNA fragmentation and chromatin condensation, which are the principle criteria currently used to define apoptotic death. Moreover, the synergistic effect of caspase and calpain inhibitors in protecting neurons form ischemic damage suggests that there is a cross-talk between caspase and calpain during apoptosis.
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PMID:mu-Calpain activation, DNA fragmentation, and synergistic effects of caspase and calpain inhibitors in protecting hippocampal neurons from ischemic damage. 1082 7

Although more than 8000 papers of apoptosis are published annually, there are very few reports concerning necrosis in the past few years. A number of recent studies using lower species animals have suggested that the cornu Ammonis (CA) 1 neuronal death after brief global cerebral ischemia occurs by apoptosis, an active and genetically controlled cell suicide process. However, the studies of monkeys and humans rather support necrosis, the calpain-mediated release of lysosomal enzyme cathepsin after ischemia conceivably contributes to the cell degeneration of CA1 neurons. This paper provides an overview of recent developments in ischemic neuronal death, presents the cascade of the primate neuronal death with particular attentions to the cysteine proteases, and also indicates selective cathepsin inhibitors as a novel neuroprotectant. Furthermore, the possible interaction of calpain, cathepsin, and caspase in the cascade of ischemic neuronal death is discussed.
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PMID:Implication of cysteine proteases calpain, cathepsin and caspase in ischemic neuronal death of primates. 1084 Jan 50

Overactivated calpain might be a key factor in destruction of cytoskeletal proteins involved in the pathophysiology of ischemia and disorders like Alzheimer's disease. Therapeutic effects imply the possible interference of Cerebrolysin (Ebewe Arzneimittel, Austria) with these molecular events. In this work several in vitro methods have been applied to investigate the interaction between Cerebrolysin and calpain [Enzyme Commission (EC) number: 3.4.22.17]. A conventional caseinolytic assay beside two flourimetric assays using a synthetic peptide substrate and a fluorescence labelled cytoskeletal protein [microtubule-associated protein 2 labelled with 5-([4,6-dichlorotriazin-2-yl]amino) fluorescein (MAP2-DTAF)] respectively for a highly sensitive fluorimetric calpain activity assay were applied for kinetic analysis. The caseinolytic assay showed that the drug inhibits both mu- and m-calpain and to a significantly lower extent also trypsin [Enzyme Commission (EC) number: 3.4.21.1] and papain [Enzyme commission (EC) number: 3.4.22.6]. Dialysis experiments revealed Cerebrolysin mediated calpain inhibition to be reversible. Kinetic analysis exhibited a non-competitive, or tight-binding competitive, mode of inhibition. This latter mode, substantiated by serial dilution experiments, and the likely existence of calpastatin in a brain derivative suggests the occurrence of calpastatin fragments or calpastatin-like fragments in Cerebrolysin. The clearly competitive inhibition of trypsin by the drug indicates distinct mechanisms and active components against different proteases.
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PMID:Inhibitory effect of a brain derived peptide preparation on the Ca++-dependent protease, calpain. 1084 56

Spinal cord injury is a devastating condition in which most of the clinical disability results from dysfunction of white matter tracts. Excessive cellular Ca(2+) accumulation is a common phenomenon after anoxia/ischemia or mechanical trauma to white matter, leading to irreversible injury because of overactivation of multiple Ca(2+)-dependent biochemical pathways. In the present study, we examined the role of Na(+)-Ca(2+) exchange, a ubiquitous Ca(2+) transport mechanism, in anoxic and traumatic injury to rat spinal dorsal columns in vitro. Excised tissue was maintained in a recording chamber at 37 degrees C and injured by exposure to an anoxic atmosphere for 60 min or locally compressed with a force of 2 g for 15 s. Mean compound action potential amplitude recovered to approximately 25% of control after anoxia and to approximately 30% after trauma. Inhibitors of Na(+)-Ca(2+) exchange (50 microM bepridil or 10 microM KB-R7943) improved functional recovery to approximately 60% after anoxia and approximately 70% after traumatic compression. These inhibitors also prevented the increase in calpain-mediated spectrin breakdown products induced by anoxia. We conclude that, at physiological temperature, reverse Na(+)-Ca(2+) exchange plays an important role in cellular Ca(2+) overload and irreversible damage after anoxic and traumatic injury to dorsal column white matter tracts.
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PMID:Important role of reverse Na(+)-Ca(2+) exchange in spinal cord white matter injury at physiological temperature. 1093 36

The aim of this study was to investigate the role of secondary free radicals and calpain, a calcium-activated cysteine protease, in the development of reperfusion injury in the heart. The time course of radical generation was assessed directly by Electron Paramagnetic Resonance (EPR) and spin trapping with N-ter butyl-alpha-phenylnitrone (PBN), in isolated perfused rat heart subjected to 30 minutes of global ischemia and 30 minutes of reperfusion. The effect of leupeptin, a calpain inhibitor, was assessed on postischemic dysfunction. The antioxidant properties of leupeptin were also investigated by using allophycocyanin, a fluorescent protein sensitive to oxidative stress generated by the H2O2 + Cu++ system. Moreover, we measured the capacities of leupeptin to scavenge hydroxyl (.OH) and superoxide (O2-.) radicals using EPR technique. Our results show that myocardial reperfusion is associated with an increase of alkyl, alkoxyl free radicals release; the administration of catalase 5.10(5) UI/L significantly reduces this release, but didn't improve the postischemic contractile function of the heart. In our study leupeptin 50 microM possess, in vitro, antioxidant properties and scavenging abilities against .OH and O2-., in return leupeptin does not influence the cardiac functions during reperfusion period. In conclusion, our results confirm that myocardial reperfusion induces an important production of secondary free radicals associated with contractile dysfunction. The role of calpain in myocardial ischemia-reperfusion injury remains to be clarified 1) by assessing the activities of calpain and calpastain, its main endogenous inhibitor, during these periods, 2) by measuring the ability of leupeptin in inhibiting the calpain dependent proteolysis.
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PMID:[Demonstration of secondary free radicals and the role of calpain in functional changes associated with the myocardial ischemia-reperfusion sequence]. 1098 32


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