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

The effect of acidic phospholipids on proteolysis of protein kinase C (PKC) by mu-calpain was examined at Ca++ concentrations ranging from 10(-7) to 10(-4) M. The gamma species, among the molecular species of PKC, was more susceptible to calpain than the alpha and beta (beta I/beta II) and was hydrolysed at Ca++ concentrations greater than or equal to 10(-6) M. Acidic phospholipids enhanced proteolysis of PKC gamma and lowered Ca++ concentrations required for it to the level below 10(-6) M. Among the phospholipids tested, phosphatidylinositol-bisphosphate showed the most prominent effect; phosphatidylinositol and phosphatidylserine were less effective. Polyphosphoinositides, hence, may constitute an essential structure in cell membranes for positive regulation of calpain activity.
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PMID:Proteolysis of protein kinase C by calpain: effect of acidic phospholipids. 166 83

The degradation of troponin (Tn) subunits by calpain was studied by incubating either isolated cardiac Tns or myocardial cryosections with two different calpain isoenzymes isolated from rat skeletal muscle. Western-blot analysis with monoclonal antibodies against TnI and TnT showed that mu-calpain was at least ten times more active than m-calpain in degrading TnI and TnT both in vitro and in situ. TnC was completely resistant to both proteinase forms. Phosphorylation by cyclic AMP-dependent protein kinase (PKA) isolated from rat skeletal muscle reduced the sensitivity of TnI to degradation. This effect in combination with an increased efficiency of the endogenous inhibitor [Salamino, De Tullio, Michetti, Mengotti, Melloni and Pontremoli (1994) Biochem. Biophys. Res. Commun. 199, 1326-1332] probably reduces the proteolytic activity of calpain in cells on PKA stimulation. Conversely, phosphorylation by protein kinase C (PKC) resulted in a twofold increase in the degradation of TnI. Degradation by m-calpain was not modified by Tn phosphorylation. The different sensitivity to mu-calpain might be related to changes in TnI oligomeric structure. Indeed, on PKC phosphorylation, the apparent molecular mass of TnI calculated from the distribution coefficient of Tn complex in Sephadex G-100 matrix was reduced from 90 to 30 kDa suggesting dissociation of the Tn complex.
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PMID:Specific degradation of troponin T and I by mu-calpain and its modulation by substrate phosphorylation. 775 88

A mu-calpain-PKC complex was isolated from rabbit skeletal muscle by ultracentrifugation and by anion-exchange chromatography. The PKC associated to mu-calpain was stimulated by calcium, phosphatidylserine and diacylglycerol, and corresponds to a conventional PKC (cPKC). This complex presents an apparent molecular mass close to 190 kDa and is composed of one mu-calpain molecule and of one cPKC molecule. Using monoclonal antibodies specific for the different cPKC isoforms, the isoenzyme associated to mu-calpain was identified as cPKC alpha. Immunofluorescence staining reveals a co-localization of mu-calpain and cPKC alpha on the muscle fibre plasma membranes.
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PMID:Isolation and identification of a mu-calpain-protein kinase C alpha complex in skeletal muscle. 785 31

Isolated connexin-32s from rat and mouse liver are proteolyzed in vitro by the intracellular Ca(2+)-dependent neutral proteases, mu-calpain and m-calpain, producing a major fragment of 26 kDa. Connexin-26 is not proteolyzed by calpain. Calpain cleaves connexin-32 at its C-terminal end as shown by 125I-calmodulin binding experiments. Connexin-32, but not connexin-26, is phosphorylated by both protein kinase A and protein kinase C in serine residues and the sites of phosphorylation by both kinases remain in the major 26-kDa fragment resulting from calpain proteolysis. Phosphorylation of connexin-32 by protein kinase C, but not by protein kinase A, prevents the proteolytic attack of mu-calpain and m-calpain. Phosphorylation of connexin-32 by protein kinase A and protein kinase C does not prevent its proteolysis by papain, alpha-chymotrypsin, proteinase K, and trypsin.
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PMID:Phosphorylation of connexin-32 by protein kinase C prevents its proteolysis by mu-calpain and m-calpain. 839 Sep 88

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

Phosphorylation by adenosine-3',5'-cyclic monophosphate (cAMP)-dependent protein kinase (PKA), but not by Ca(++)-calmodulin-dependent protein kinase II (CaMK II), was shown earlier to protect microtubule-associated protein 2 (MAP2) from cleavage by m-calpain (Johnson and Foley: J Neurosci Res 34: 642-647, 1993). We reinvestigated this phenomenon with the physiologically more relevant mu-calpain and found a qualitatively similar but quantitatively different picture. We further demonstrate that 1) protection is biphasically dependent on the degree of phosphorylation; 2) Ca(++)-phospholipid-dependent protein kinase (PKC) has about the same effect as PKA; 3) the effects of kinases A and C are not additive; and 4) stripping of native MAP2 from its phosphate content (17.8 +/- 2.3 mol/mol) enhances calpainolysis 3.6-fold. A reciprocal effect between kinase A and MAP2 was found: the RII, but not the RI, regulatory subunit of kinase A, which was shown to bind specifically to MAP2, is protected by MAP2 from mu-calpain attack. It is suggested that the specific anchoring of kinase A-II on MAP2 may serve not only kinase targeting in the dendrites, but also protection from calpainolytic degradation.
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PMID:Mutual protection of microtubule-associated protein 2 (MAP2) and cyclic AMP-dependent protein kinase II against mu-calpain. 877 65

Intracellular proteolysis by the calpains, a family of Ca2+ activated cysteine proteases, is a ubiquitous yet poorly understood process. Their action is implicated in an array of cellular and pathologic processes, including long-term potentiation, synaptic remodeling, protein kinase C and steroid receptor activation, ischemic cellular injury, and apoptosis. Unlike most proteases, the calpains display unusually strict substrate specificity, often cleaving only one or two bonds in proteins with hundreds of potential sites. Studies of synthetic peptides have defined sequences that modulate their specificity, but little data exist in the context of a bona fide protein. A prominent substrate for mu-calpain is alpha II spectrin (fodrin, brain spectrin), which is cleaved between Tyr1176 and Gly1177 within spectrin's 11th structural repeat unit. We have cloned and characterized human fetal brain alpha II spectrin (GenBank no. U26396) and identified a new Thr1300 to Ile polymorphism. From this clone, recombinant GST-fusion proteins representing repeat units 8-14 have been prepared and used to systematically explore the in vitro determinants of mu-calpain sensitivity. Twenty different amino acids were substituted by site-directed mutagenesis for wild-type Val1175, the penultimate (P2) residue flanking the major calpain cleavage site in alpha II spectrin. Gly, Pro, and Asp, and to a lesser extent Phe and Glu, substantively inhibited the susceptibility of this site to mu-calpain; other substitutions yielded lesser effects. Dynamic molecular modeling of the 11th structural repeat of human alpha II spectrin incorporating the various mutations suggests that the calpain cleavage site with its flanking calmodulin binding domain interrupts helix C of alpha II spectrin's 11th repetitive unit without significantly disrupting the repeat's triple-helical motif. This model predicts that the critical Tyr1176-Gly1177 bond occurs in a highly exposed loop juxtaposed between helix C and the calmodulin binding domain and that mutations at the P2 position subtly alter the conformation about this site. We conclude that secondary and tertiary conformational features surrounding the cleavage site, rather than the linear sequence itself, dominate the determinants that define alpha II spectrin's mu-calpain susceptibility.
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PMID:Site-directed mutagenesis of alpha II spectrin at codon 1175 modulates its mu-calpain susceptibility. 899 18

In previous studies of topical application of calphostin C, a specific inhibitor of the regulatory domain of protein kinase C (PKC), and calpeptin, a selective inhibitor of calpain, to spastic canine basilar artery (BA) researchers have suggested that the catalytic fragment of PKC (known as PKM) is probably formed by a limited proteolysis of continuously activated mu-calpain, but there has been no direct evidence for PKM formation in vasospasm. The present immunoblot study with anti-PKCalpha antibody shows a significant decrease in cytosolic 80-kD PKCalpha and a concomitantly significant increase in membrane PKCalpha in the spastic canine BA. In addition, an immunoblot study in which cleavage site-directed antibodies were used demonstrated a significant increase in immunoreactive 45-kD PKM. The changes in membrane PKCalpha and PKM were enhanced with the lapse of time after subarachnoid hemorrhage. The cleavage site-directed antibodies distinguish the proteolyzed from the unproteolyzed forms of PKC for in situ analyses of enzyme regulation mediated by proteolysis. The data indicate that PKCalpha in spastic canine BA is translocated to the cell membrane, where PKCalpha is rapidly cleaved into PKM as a result of proteolysis of the isozyme by mu-calpain but not by m-calpain. The authors hypothesize that mu-calpain is continuously activated in spastic canine BA and produces PKM by limited proteolysis of PKCalpha.
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PMID:Generation of the catalytic fragment of protein kinase C alpha in spastic canine basilar artery. 934 85

Subarachnoid hemorrhage (SAH) often leads to a long-term narrowing of cerebra! artery called vasospasm. To understand the molecular mechanisms in vasospasm, signal transduction of tyrosine kinase pathway and phosphorylation of myosin light chain (MLC) and calponin (CaP) in the basilar artery were studied. Vasospasm was produced in the canine basilar artery by a two-hemorrhage method, and vasocontraction was induced by a local application of KCI or serotonin to the basilar artery after a transclival exposure. Intracellular substrates of tyrosine kinase pathway, including Shc, Rafl, and extracellular-regulated kinases in the basilar artery, were activated after SAH, and the activation of Shc suggests stimulation of signal transductions from tyrosine kinase receptors, G-coupled receptors, or both. The activation of tyrosine kinase pathway in vasospasm also was supported by dose-dependent dilation of the spastic basilar artery on days 0 and 7 by topical application of genistein, a tyrosine kinase inhibitor, and associated marked inhibition of tyrosine phosphorylation of intracellular substrates, including Shc. In addition, the generation of protein kinase M, catalytic fragment of protein kinase C(alpha) (PKC alpha), in vasospasm on days 0 and 7 was inhibited in response to genistein, indicating an inactivation of mu-calpain. It is suggested, therefore, that the reversal of vasospasm by genistein is closely associated with the restoration of intracellular Ca2+ levels. However, the increased activities of Raf1 and extracellular-regulated kinases in vasospasm were declined on day 7 compared with those on day 0 or 2, suggesting that the activation of tyrosine kinase pathway is more closely associated with the early stage of vasospasm than with the late stage of vasospasm. The analysis by pyrophosphate polyacrylamide gel electrophoresis (PPi-PAGE) demonstrated three MLC bands in vasospasm on days 2 and 7, as well as in KCI- and serotonin-induced vasocontraction. Since PPi-PAGE resolves smooth muscle MLC into three bands in the MLC kinase (MLCK)-mediated phosphorylation and into a single band in the PKC-mediated phosphorylation based on the phosphorylation state, the current results suggest that MLC in vasospasm is phosphorylated by MLCK but not by PKC. In basilar artery, CaP was significantly down-regulated, and in addition, significantly phosphorylated on serine and threonine residues only in vasospasm on days 2 and 7. Although the significance of CaP phosphorylations in vivo still is controversial, CaP down-regulation and phosphorylation may attenuate the inhibition of Mg(2+)-ATPase activity by CaP and induce a potential enhancement of smooth muscle contractility in delayed vasospasm. Since CaP is phosphorylated in vivo by PKC, activated PKC in vasospasm may phosphorylate CaP. Thus, SAH stimulates tyrosine kinase pathway to increase intracellular Ca2+ and activate PKC, and the former activates MLCK to phosphorylate MLC, whereas the latter phosphorylates CaP but not MLC.
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PMID:Activation of protein kinases in canine basilar artery in vasospasm. 988 54

In previous studies, we isolated and identified a mu-calpain-PKCalpha complex from rabbit skeletal muscle. At the same time we pointed out that an association between mu-calpain and PKCalpha could occur at the level of the plasma membrane of muscle cells, and that PKCalpha could thus be considered as a potential mu-calpain substrate. In the present study, using the mu-calpain-PKCalpha complex as a model, we report that mu-calpain is activated in the combined presence of physiological calcium concentrations (less than 1 microM) and phosphatidylserine. Furthermore our data also show that: (1) there exists a correlation between the appearance of autolyzed mu-calpain forms and PKCalpha hydrolysis which leads to the formation of PKMalpha; (2) in certain experimental conditions, autolyzed mu-calpain forms are able to hydrolyze PKMalpha independently of the presence of diacylglycerol.
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PMID:Degradation of protein kinase Malpha by mu-calpain in a mu-calpain-protein kinase Calpha complex. 1008 42


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