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)

GAP-43 is a neuronal protein that is believed to be important to neuronal growth and nerve terminal plasticity. It is enriched on the inner surface of growth cone membranes, a localization that may depend upon palmitoylation of Cys3 and Cys4. It is a major substrate for protein kinase C, which phosphorylates Ser41. Isolated GAP-43 can bind to actin and to calmodulin, and can activate the heterotrimeric GTP-binding proteins, G(o) and Gi. A peptide consisting of the GAP-43 sequence 39-55 binds calmodulin, and an amino-terminal GAP-43 (1-10) peptide activates G(o), suggesting that these stretches may be functional domains of the intact protein. When expressed in non-neuronal cells, GAP-43 enhances filopodial extension and has effects upon cell spreading. We have examined the effects of various GAP-43 domains upon this assay, by expression of GAP-43, GAP-43 mutant proteins, and GAP-43-CAT fusion proteins in COS-7 cells. We find that the amino terminus (Met-Leu-Cys-Cys-Met-Arg-Arg-Thr-Lys-Gln) is an important contributor to these effects on cell shape. A GAP-43 protein mutant in Cys3 and Cys4 does not bind to the membrane, and is inactive. Mutants in Arg6 or Lys9 also are inactive, although they remain localized to particulate fractions; Arg7 mutants are active. A chimeric gene consisting of GAP-43 (1-10) fused to chloramphenicol acetyl transferase (CAT) also causes cell shape changes. As for GAP-43, the effects of this fusion protein are abolished by mutations of Cys3, Cys4, Arg6 or Lys9, but not by mutation of Arg7. Therefore, the cell surface activity of transfected GAP-43 depends upon its amino terminus, although other domains may regulate it in this regard. Since the amino-terminal domain includes the peptide stretch known to be capable of activating G(o) and Gi, we examined the effect of GAP-43 on a Gi-regulated second messenger system, the inhibition of cAMP production in A431 cells. A431 cells stably transfected with GAP-43 spread less well than do controls. In addition, they evidence decreased levels of forskolin-stimulated cAMP, consistent with chronic stimulation of Gi. Stimulation of adenylate cyclase by isoproterenol reverses the GAP-43-induced changes in cell shape. This suggests that G protein stimulation is involved in GAP-43 effects upon cell shape.
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PMID:An amino-terminal domain of the growth-associated protein GAP-43 mediates its effects on filopodial formation and cell spreading. 817 8

The data presented in this chapter are summarized in the schematic shown in Figure 9. Insulin binds to and stimulates autophosphorylation of neuronal insulin receptors, whereas, IGF-I and IGF-II binds to and stimulate autophosphorylation of neuronal IGF-I receptors. IGF-II is also capable of binding to the insulin receptor. Whether or not it activates the insulin receptor kinase remains to be clarified. Activated insulin and IGF-I receptor kinases phosphorylate a 70-kDa protein at early times in culture. This protein may mediate some actions of insulin, but we speculate that there are other intermediary proteins involved in the transduction pathway resulting in the activation of S6 kinase and PKC epsilon. The stimulation of S6 kinase by insulin and IGF-I may be associated with the translational activation of protein synthesis by these peptides. The stimulation of PKC epsilon appears to be a necessary step in the transcriptional regulation of the c-fos gene by insulin and IGF-I. The regulation of neuronal protein synthesis at a translational step and the initiation of transcriptional programs regulated by AP-1 represent two mechanisms by which insulin and IGFs alter neuronal growth and differentiation.
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PMID:Insulin and IGF-I receptor signaling in cultured neurons. 821 46

Previous reports using various protein kinase inhibitors have suggested that protein kinase activity is necessary for both the induction and maintenance of hippocampal long-term potentiation (LTP), a cellular phenomenon likely to contribute to mammalian memory formation. We designed and characterized a selective peptide substrate for protein kinase C (PKC), corresponding to amino acids 28 to 43 of the neuronal protein neurogranin, and used the substrate to obtain direct biochemical evidence for activation of PKC in both the induction and maintenance phases of LTP. As the effect cannot be accounted for by either of two well-known mechanisms for persistent PKC activation, membrane insertion, or proteolysis, the persistent activation of PKC in the maintenance phase of LTP appears to occur via another mechanism. The maintenance phase of LTP is associated with decreased immunoreactivity of PKC, an effect that can be reversed with phosphatase treatment. Thus, PKC appears to be both phosphorylated and persistently activated in the maintenance phase of LTP.
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PMID:Mechanism of protein kinase C activation during the induction and maintenance of long-term potentiation probed using a selective peptide substrate. 810 34

The neuronal protein neurogranin, also known as RC3, is a selective substrate for protein kinase C (PKC). We synthesized a peptide corresponding to the phosphorylation domain of neurogranin (amino acids 28-43) and characterized its properties as a PKC substrate. Neurogranin(28-43) was phosphorylated by purified PKC with a Km of 150 nM. No significant phosphorylation of the peptide by either cAMP-dependent protein kinase or by calcium/calmodulin-dependent protein kinase II could be detected. Thus, neurogranin(28-43) is a potent and selective substrate for PKC. We tested several peptide analogues of neurogranin(28-43) for their substrate potency and specificity as kinase substrates, in order to help elucidate the structural determinants involved in the phosphorylation of substrates by PKC. Substituting Arg36 with Ile caused a significant reduction in the affinity for PKC. Replacing Lys30 with Arg enhanced the catalytic efficiency (Vmax/Km) for PKC but diminished the selectivity of the substrate for PKC. These results support the generally held model that basic amino acids on both sides of the phosphorylated Ser are important structural determinants in PKC substrates. However, the data also suggest that the presence of particular basic amino acids (Arg vs Lys) can contribute to the degree of selectivity of a substrate for PKC. Replacement with Ala of Phe35, the amino acid adjacent to the Ser34 phosphorylation site, resulted in a peptide with greatly diminished potency as a PKC substrate. This finding indicates a critical role of Phe35 in modulating binding and phosphorylation of neurogranin-derived peptides by PKC.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Studies with synthetic peptide substrates derived from the neuronal protein neurogranin reveal structural determinants of potency and selectivity for protein kinase C. 842 32

A peptide corresponding to the neuronal protein neurogranin (NG) residues 28-43, NG(28-43), and its analog, [A35]NG(28-43), have been investigated by NMR, electron paramagnetic resonance (EPR), and circular dichroism (CD) spectroscopies. The peptides existed in aqueous solution predominantly in random form. However, a nascent helical structure was detected in the central region of the parent peptide from NMR data. Furthermore, a helical structure can be detected for both peptides with greater induced secondary structure for the parent peptide in the presence of sodium dodecyl sulfate (SDS) micelle. The formation of micelles for SDS was confirmed by results from EPR as well as 13C NMR. As shown by CD experiments, helical conformer was induced for NG(28-43) in vesicular solution containing phosphatidyl serine (PS), whereas no helix can be discerned for the peptide in phosphatidyl choline (PC)-containing vesicular solution. Together with the induction of the peptide into helix in SDS micellar solution as suggested by both NMR and CD data, these results underscored the electrostatic contribution to the interaction of the PKC substrate peptides and proteins with membrane. According to NMR and CD data, a dynamic equilibrium existed between free and micelle-bound states for the peptide. Moreover, proton-deuterium exchange results and SDS-induced linewidth broadening of proton resonances allowed delineation of the orientation of the amphipathic helix on the surface of SDS micelle. The result was supported by spin label experiments that indicated F35 of NG(28-43) interacted strongly with the hydrocarbon interior of micelle. Based on the experimental findings, a working model was proposed that attempted to partly explain the roles played by the nonpolar amino acid near the phosphorylation site, by the negatively charged phospholipids, and by the basic amino acids of the substrate.
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PMID:Conformation of a protein kinase C substrate NG(28-43), and its analog in aqueous and sodium dodecyl sulfate micelle solutions. 901 86

The neuronal protein GAP-43 is concentrated at the growth cone membrane, where it is thought to amplify the signal transduction process. As a model for its neuronal effects, GAP-43 protein injection into Xenopus laevis oocytes strongly augments the calcium-sensitive chloride current evoked by the G protein-coupled receptor stimulation. We have now examined a series of GAP-43 mutants in this system and determined those regions of GAP-43 required for this increase in current flux. As expected, palmitoylation inhibits signal amplification in oocytes by blocking G protein activation. Unexpectedly, a second domain of GAP-43 (residues 35-50) containing a protein kinase C phosphorylation site at residue 41 is also necessary for augmentation of G protein-coupled signals in oocytes. This region is not required for activation of isolated Go but is necessary for GAP-43 binding to isolated calmodulin and to isolated protein kinase C. Substitution of Asp for Ser41 inactivates GAP-43 as a signal facilitator in oocytes. This mutation blocks GAP-43 binding to both protein kinase C and calmodulin. Thus, GAP-43 regulates an oocyte signaling cascade via coordinated, simultaneous G protein activation and interaction with either calmodulin or protein kinase C.
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PMID:GAP-43 augmentation of G protein-mediated signal transduction is regulated by both phosphorylation and palmitoylation. 948 17

The SNARE hypothesis proposes that synaptic vesicles dock at presynaptic membranes via interactions among the vesicular, integral membrane proteins VAMP (vesicle-associated membrane protein) and synaptotagmin and the target membrane proteins SNAP25 (synaptosome-associated protein with an Mr of 25 kDa) and syntaxin-1. Non-neuronal cells express isoforms of these proteins, believed to mediate secretory vesicle docking and/or fusion. Secretion in neuronal and non-neuronal systems differs in time course, Ca2+ dependence, and regulatory input. It is not known whether the non-neuronal protein isoforms form complexes akin to those of their neuronal counterparts. In this study, we defined the binding characteristics of three SNARE proteins: SNAP23, VAMP-2, and syntaxin-4. Binary, saturable interactions among all three partners (VAMP-2-syntaxin-4, VAMP-2-SNAP23, and SNAP23-syntaxin-4) were measured in vitro. Unlike its neuronal counterpart, SNAP23 did not potentiate VAMP-2 binding to its putative t-SNARE partner, syntaxin-4. The susceptibility of SNARE proteins to phosphorylation by exogenous kinases and their impact on binary interactions were explored. Syntaxin-4 was efficiently phosphorylated by casein kinase II (CKII) and cAMP-dependent protein kinase (PKA) (incorporating 0.8 and 3.9 mol of phosphate/mol of syntaxin-4, respectively), while syntaxin-1 was only strongly phosphorylated by CKII. Each of the syntaxin isoforms was weakly phosphorylated by protein kinase C (PKC) (<0.05 mol of phosphate/mol of syntaxin-4). Importantly, PKA but not casein kinase II phosphorylation of syntaxin-4 disrupted its binding to SNAP23. We hypothesize that PKA may modulate syntaxin-4-dependent SNARE complex formation to regulate exocytosis in non-neuronal cells.
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PMID:Binary interactions of the SNARE proteins syntaxin-4, SNAP23, and VAMP-2 and their regulation by phosphorylation. 969 5

Neurogranin/RC3 (Ng), a postsynaptic neuronal protein kinase C (PKC) substrate, binds calmodulin (CaM) at low level of Ca2+. In vitro, rat brain Ng can be oxidized by nitric oxide (NO) donors and by oxidants to form an intramolecular disulfide bond with resulting downward mobility shift on nonreducing SDS-polyacrylamide gel electrophoresis. The oxidized Ng, as compared with the reduced form, is a poorer substrate of PKC but like the PKC-phosphorylated Ng has a lower affinity for CaM than the reduced form. To investigate the physiological relevance of Ng oxidation, we tested the effects of neurotransmitter, N-methyl-D-aspartate (NMDA), NO donors, and other oxidants such as hydrogen peroxide and oxidized glutathione on the oxidation of this protein in rat brain slices. Western blot analysis showed that the NMDA-induced oxidation of Ng was rapid and transient, it reached maximum within 3-5 min and declined to base line in 30 min. The response was dose-dependent (EC50 approximately 100 microM) and could be blocked by NMDA-receptor antagonist 2-amino-5-phosphonovaleric acid and by NO synthase inhibitor NG-nitro-L-arginine methyl ester and NG-monomethyl-L-arginine. Ng was oxidized by NO donors, sodium nitroprusside, S-nitroso-N-acetylpenicillamine, and S-nitrosoglutathione, and H2O2 at concentrations less than 0.5 mM. Oxidation of Ng in brain slices induced by sodium nitroprusside could be reversed by dithiothreitol, ascorbic acid, or reduced glutathione. Reversible oxidation and reduction of Ng were also observed in rat brain extracts, in which oxidation was enhanced by Ca2+ and the oxidized Ng could be reduced by NADPH or reduced glutathione. These results suggest that redox of Ng is involved in the NMDA-mediated signaling pathway and that there are enzymes catalyzing the oxidation and reduction of Ng in the brain. We speculate that the redox state of Ng, similar to the state of phosphorylation of this protein, may regulate the level of CaM, which in turn modulates the activities of CaM-dependent enzymes in the neurons.
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PMID:N-methyl-D-aspartate induces neurogranin/RC3 oxidation in rat brain slices. 988 Apr 98

Several lines of evidence indicate that a rapid loss of neuronal protein kinase C (PKC) activity is a characteristic feature of cerebral ischemia and is a necessary step in the NMDA-induced death of cultured neurons. Exposing embryonic day 18 primary rat cortical neurons to 50 microM NMDA or 50 microM glutamate for 10 min caused approximately 80% cell death over the next 24 h, but excitotoxic death was largely averted, i.e., by 70-80%, in cells pretreated with brain-derived neurotrophic factor (BDNF). An 8-h preexposure to BDNF (50-100 ng/ml) maximally protected cortical cells from the effects of NMDA and glutamate, although the transient application of BDNF between 8 and 4 h before NMDA was equally protective. These effects of BDNF were abolished at supralethal, i.e., >100 microM, NMDA concentrations. It is significant that BDNF pretreatment prevented the inactivation of PKC in cortical cells normally seen 30 min to 2 h following lethal NMDA or glutamate exposure. This BDNF effect did not arise from changes in NMDA channel activity because neither whole-cell NMDA current amplitudes nor increases in intracellular free Ca2+ concentration were altered by the 8-h BDNF pretreatment. Furthermore, BDNF offered no neuroprotection to cells treated with the PKC inhibitors staurosporine (10-20 nM), calphostin C (1-2.5 microM), or GF-109203X (100 nM) at the time of NMDA addition. These results underscore the importance of PKC inactivation in glutamate-induced neuronal death. They also suggest that BDNF neuroprotection arises, at least in part, via its ability to block the mechanism by which pathophysiological Ca2+ influx through the NMDA receptor causes membrane PKC inactivation.
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PMID:Evidence that brain-derived neurotrophic factor neuroprotection is linked to its ability to reverse the NMDA-induced inactivation of protein kinase C in cortical neurons. 988 60

We investigated activation of the two major neuronal protein kinase C (PKC) isoforms in Aplysia, Ca(2+)-activated Apl I and Ca(2+)-independent Apl II, during the induction and maintenance of behavioral sensitization of Aplysia defensive reflexes. Activation of PKC occurred during the training stimulus and persisted for at least 2 hr thereafter but was not maintained for 24 hr. The persistent activation required protein synthesis and was blocked by cyproheptidine, an agent that also blocked the initial activation of PKC. Persistent activation involved both an increase in membrane-associated Apl I and an increase in an autonomous kinase activity that may be related to a post-translational modification of Apl II. These results are consistent with the hypothesis that in addition to its role in producing the presynaptic facilitation of mechanosensory-motor neuron synapses that underlie short-term facilitation, PKC is needed for maintaining synaptic changes in an intermediate period that precedes the modifications accompanying consolidation of memory.
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PMID:Persistent activation of protein kinase C during the development of long-term facilitation in Aplysia. 1046 96


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