Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:2.7.11.13 (protein kinase C)
 49,245 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Administration of beta-adrenergic agonists to mammals can produce skeletal muscle hypertrophy in some species and muscle types. The growth-promoting effect appears to be due to suppression of protein breakdown rather than stimulation of synthesis, although evidence from turnover studies is equivocal. In ovine muscle, changes in the activity of the calcium dependent neutral proteinases (calpains I and II) and their specific inhibitor (calpastatin) accompany beta-agonist-induced hypertrophy. These observations suggest that the calpain system is involved in myofibrillar protein turnover in some way. Alternatively, the relationship with hypertrophy may be indirect, since the calpains also interact with hormone and growth-factor receptors, protein kinase C and transcription factors, in addition to a range of membrane, cytoskeletal and nuclear proteins. In the present study, attempts have been made to determine if the beta-agonist-induced effects on the calpain system are associated with corresponding changes in specific mRNA. The activity of both calpain isoforms and calpastatin was measured in bovine longissimus dorsi samples from trials in which test animals were treated with the beta agonist cimaterol. Total RNA was extracted from the muscle samples. A cDNA probe for calpastatin mRNA was generated from bovine RNA by the polymerase chain reaction. This cDNA and a human calpain-II large-subunit cDNA were used to detect specific mRNA by Northern-blot analysis. beta-agonist treatment of Friesian steers caused significant longissimus dorsi hypertrophy. Increases in muscle mass (+37%, P less than 0.005), calpain-II specific activity (+27%, P less than 0.05) and calpastatin-specific activity (+76%, P less than 0.05) were found in treated animals. Total RNA was unchanged, but there was a 96% overall increase in calpastatin mRNA and a 30% increase in calpain-II large-subunit mRNA in muscle from treated animals. The mRNA changes are similar in direction and degree to the activity changes. Both calpain-II large subunit and inhibitor expression may therefore be stimulated by agonist action at the level of transcription or mRNA stabilisation. Multiple calpastatin mRNA species were detected in steers, as reported for other species. Differential changes in these messages, induced by the beta agonist, suggest that expression or stability of alternative mRNA species may be a factor in calpastatin regulation.
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PMID:Changes in calpain and calpastatin mRNA induced by beta-adrenergic stimulation of bovine skeletal muscle. 135 30

Calpain is a Ca2(+)-dependent cysteine endopeptidase and calpastatin is a calpain-specific endogenous inhibitor protein. Both calpain and calpastatin are very widely distributed in various animal tissues and cells. Low (microM) Ca2(+)-requiring calpain I and high (mM) Ca2(+)-requiring calpain II are known to exist. Calpain consists of one heavy (80 kDa) and one light (30 kDa) subunit. The heavy subunits of calpains I and II are different genetic products, whereas the light subunits are the same for both calpains I and II. Molecular cloning as well as protein sequencing revealed that the heavy subunit has four domains, while the light subunit has two domains. The carboxyl terminal domain of each subunit is a calmodulin-like domain, whereas the catalytic site is located in domain 2 of the heavy subunit. Calpastatin has four internally repetitive inhibitory domains. A single domain, or even a truncated 27-mer fragment thereof, possesses inhibitory activity against calpains. Calpain shows a rather broad substrate specificity. It can cleave various enzymes, and cytoskeletal, membrane and receptor proteins. Calpain-catalyzed activation of protein kinase C and transglutaminase may represent a few of the physiological functions of calpain, but a great many other functions can be assigned as well to calpain. Immunohistochemical studies revealed very wide but quite diverse distribution of calpains I and II and calpastatin among various tissues and cells. The expression of the genes for calpain and calpastatin is found to be modulated by retrovirus (HTLV-I) infection to T-lymphocytes. The physiological significance of the calpain and calpastatin system is yet to be elucidated, and accumulating information definitely suggested the role of calpain/calpastatin in health and disease.
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PMID:[Calpain and calpastatin]. 219 87

Protein kinase C activity has been measured in extracts of larval brain of Drosophila melanogaster, with the synthetic nonapeptide substrate Ala-Ala-Ala-Ser-Phe-Lys-Ala-Lys-Lys-amide. Protein kinase C activity in such extracts is abolished in a Ca2+-dependent manner at 18 degrees C, and partly converted to a form independent of effectors. The decay of protein kinase C activity can be prevented by leupeptin or a crude calpastatin preparation isolated from fly heads, indicating the presence of the Ca2+-dependent neutral protease, calpain, in larval brains. The total protein kinase C levels were nearly the same in wild type and three different dunce "memory-mutant" strains. In contrast, the soluble/particulate activity ratios were different: wild-type, 0.91; dunce M11, 0.46; dunce M11/Df(1)dm75e19, 1.23; dunce2, 0.88. These data suggest that the membrane adherence of protein kinase C in larval brain is governed by the actor of genes other than dunce.
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PMID:Protein kinase C in larval brain of wild-type and dunce memory-mutant Drosophila. 250 May 6

We have examined the mechanism for the selective down-regulation of protein kinase C epsilon (nPKC epsilon) in rat pituitary GH4C1 cells responding to thyrotropin-releasing hormone (TRH) stimulation. Among various low molecular weight protease inhibitors examined, only a cysteine protease inhibitor (calpain inhibitor I, N-acetyl-Leu-Leu-norleucinal) blocked the down-regulation of nPKC epsilon. Furthermore, the introduction of a synthetic calpastatin peptide, an exclusively specific inhibitor of calpain, into the cells also reduced the down-regulation, suggesting the involvement of calpain among all the intracellular cysteine proteases in this process. In accordance, we observed TRH-induced translocation of m-calpain from the cytosol to the membrane and the concomitant up-regulation of calpastatin isoforms; presumably, the former represents activation of the protease initiating the kinase degradation, while the latter constitutes a negative feedback system protecting the cells from activated calpain. These results suggest that in GH4C1 cells, TRH mobilizes both protease (m-calpain) and inhibitor (calpastatin) as a strictly regulating system for the nPKC epsilon pathway mediating TRH signals.
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PMID:The role of the calpain-calpastatin system in thyrotropin-releasing hormone-induced selective down-regulation of a protein kinase C isozyme, nPKC epsilon, in rat pituitary GH4C1 cells. 755 44

We examined the interdependence of calpain and protein kinase C (PKC) activities on neurite outgrowth in SH-SY-5Y human neuroblastoma cells. SH-SY-5Y cells elaborated neurites when deprived of serum or after a specific thrombin inhibitor, hirudin, was added to serum-containing medium. The extent of neurite outgrowth under these conditions was enhanced by treatment of cells with the cell-permeant cysteine protease inhibitors N-acetyl-leucyl-leucyl-norleucinal ("C1") and calpeptin or by the phospholipid-mediated intracellular delivery of either a recombinant peptide corresponding to a conserved inhibitory sequence of human calpastatin or a neutralizing anti-calpain antisera. Calpain inhibition in intact cells was confirmed by immunoblot analysis showing inhibition of calpain autolysis and reduced proteolysis of the known calpain substrates fodrin and microtubule-associated protein 1. The above inhibitory peptides and antiserum did not induce neurites in medium containing serum but lacking hirudin, suggesting that increased surface protein adhesiveness is a prerequisite for enhancement of neurite outgrowth by calpain inhibition. Treatment of cells with the PKC inhibitor H7, staurosporine, or sphingosine induced neurite outgrowth independently of serum concentration. Because calpain is thought to regulate PKC activity, we examined this potential interrelationship during neurite outgrowth. Simultaneous treatment with calpain and PKC inhibitors did not produce additive or synergistic effects on neurite outgrowth. PKC activation by 2-O-tetradecanoylphorbol 13-acetate (TPA) prevented and reversed both neurite initiation by serum deprivation and its enhancement by calpain inhibitors. Treatment of cells with the calpain inhibitor C1 retarded PKC down-regulation following TPA treatment. Cell-free analyses demonstrated the relative specificity of various protease and kinase inhibitors for calpain and PKC and confirmed the ability of millimolar calcium-requiring calpain to cleave the SH-SY-5Y PKC regulatory subunit from the catalytic subunit, yielding a free catalytic subunit (protein kinase M). These findings suggest that the influence of PKC on neurite outgrowth is downstream from that of surface adhesiveness and calpain activity.
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PMID:Enhancement of neurite outgrowth following calpain inhibition is mediated by protein kinase C. 761 5

Calpain has been identified as the intracellular proteinase that catalyzes the selective down-regulation of protein kinase C (PKC) isoforms, occurring in the early stages of commitment to terminal erythroid differentiation of murine erythroleukemia (MEL) cells induced by hexamethylenebisacetamide. This conclusion has been reached through direct experiments performed with two MEL cell clones, one characterized by a high and the other by a low rate of differentiation. In both cell types, introduction of an anti-calpain antibody resulted in a significant delay in the onset of down-regulation of PKC isoforms, and in an increase in the latent period that precedes differentiation. Both cell lines also displayed reduced rates of PKC decay and accumulation of mature erythroid cells. Furthermore, in the fast-responding clone, calpastatin, the natural calpain-inhibitor protein, was found to be almost completely absent, resulting in activation and expression of proteolytic activity of calpain even at micromolar concentrations of Ca2+, a condition not sufficient to trigger calpain activation in the slowly responding clone which contains high levels of calpastatin. The fast-responding MEL cell clone, enriched with calpastatin, displayed a lower rate of cell differentiation, with a kinetics almost identical to that observed following introduction of the anti-calpain antibody. It is proposed that Ca(2+)-dependent proteolysis plays a crucial role for the progress of MEL cell differentiation through the specific degradation of PKC isozymes.
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PMID:Modulation of the intracellular Ca(2+)-dependent proteolytic system is critically correlated with the kinetics of differentiation of murine erythroleukemia cells. 792 35

Rat intoxication with a single dose of the hepatotoxin carbon tetrachloride induces a significant modification of liver protein kinase C total activity which depends on the degree of the intrahepatocyte oxidative unbalance provoked by various concentrations of the haloalkane. Low carbon tetrachloride amounts stimulate total protein kinase C activity, while one order of magnitude higher amounts exert strong enzyme inhibition. The latter effect is due to an early inactivation followed with progress of time by a proteolytic degradation of the enzyme. A pathological recruitment of the calcium-dependent protein kinase C regulatory enzymes calpain and calpastatin appears responsible for protein kinase C loss. The prolonged excess of cytosolic calcium which characterizes the single high dose carbon tetrachloride poisoning also leads to inactivation of calpain II and calpastatin in a time-dependent manner.
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PMID:Modulation of rat liver protein kinase C during "in vivo" CC14-induced oxidative stress. 834 50

Calcium influx into SH-SY5Y human neuroblastoma cells after ionophore treatment or transient permeabilization in calcium-containing medium increased ALZ-50 immunoreactivity markedly. This increase was prevented by inhibitors active against calpain or against protein kinase C (PKC), suggesting that both of these enzymes were required to mediate the effect of calcium influx on ALZ-50 immunoreactivity. Treatment with PKC activator TPA increased ALZ-50 immunoreactivity in the absence of calcium influx or after intracellular delivery of the specific calpain inhibitor calpastatin, indicating that the influence of PKC was downstream from that of calpain. Calcium influx also resulted in mu-calpain autolysis (one index of calpain activation) and the transient appearance of PKM (i.e., free PKC catalytic subunits, generated by calpain-mediated cleavage of the regulatory and catalytic PKC domains). Inhibition of calpain within intact cells resulted in a dramatic increase in steady-state levels of total tau (migrating at 46-52 kDa) but resulted in a relatively minor increase in 68-kDa ALZ-50-immunoreactive tau isoforms. Although calcium influx into intact cells resulted in accumulation of ALZ-50 immunoreactivity, total tau levels were, by contrast, rapidly depleted. Incubation of isolated fractions with calpain in the presence of calcium indicated that ALZ-50-immunoreactive tau isoforms were more resistant to calpain-mediated proteolysis than were non-ALZ-50 reactive tau isoforms. These data therefore indicate that calpain may regulate tau levels directly via proteolysis and indirectly through PKC activation. A consequence of the latter action is altered tau phosphorylation, perhaps involving one or more kinase cascades, and the preferential accumulation of ALZ-50-immunoreactive tau isoforms due to their relative resistance to degradation. These findings provide a basis for the possibility that disregulation of calcium homeostasis may contribute to the pathological levels of conversion of tau to A68 by hyperactivation of the calpain/PKC system.
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PMID:Calcium influx into human neuroblastoma cells induces ALZ-50 immunoreactivity: involvement of calpain-mediated hydrolysis of protein kinase C. 862 10

Calpains are Ca-activated neutral proteases present in all cells together with an endogenous inhibitor, calpastatin. Proposed substrates are; cytoskeletal proteins like microtubules and actin, protein kinases such as PKC and membrane-bound enzymes like Ca-ATPase and the Ca-channel. In lenses from different species calpains have been detected in decreasing amounts from the epithelium to the cortex to the nucleus. Several substrates for calpain in the lens have been demonstrated: crystallins, vimentin, actin, beaded filaments and MP26 among others. Both studies on animal models and capsulorhexis indicate that calpains are mainly involved in cortical cataract.
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PMID:Calpains in the human lens: relations to membranes and possible role in cataract formation. 872 65

Vertebrate m-calpain, calpastatin, constitutive nitric oxide synthase, myelin basic protein, and dynamin I are substrates of protein kinase C (PKC). The presence/absence of similar/related protein in nonvertebrate was investigated by immunological methods, including (1) affinity chromatography on agarose-secondary antibodies and agarose IgG for removal of nonspecific immunoreactivities from crude extracts; (2) omitting beta-mercaptoethanol treatment and boiling prior to SDS-PAGE to increase the immunoreactivity; (3) immunoreactivity comparisons of nonspecific IgG as controls with specific anti-(vertebrate PKC-substrates/related proteins) in Western blots. It was found that (a) m-calpain and dynamin I were absent in baker's yeast, wheat germ and lobster tail muscle, (b) m-calpain, nitric oxide synthase, myelin basic protein and dynamin II were present in all three samples, and (c) calpastatin was present in baker's yeast and lobster tail muscle. The presence and absence of these proteins suggest evolutionary conservation and divergence, respectively, of these PKC substrates.
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PMID:Immunoreactivities of m-calpain, calpastatin, nitric oxide synthase, myelin basic protein and dynamin II in baker's yeast, wheat germ and lobster tail muscle. 921 26


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