EC:2.7.11.1 - FACTA Search

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Query: EC:2.7.11.1 (protein kinase)
81,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Ecto-protein kinases have been detected as physiological constituents of cells. One feature of ecto-phosvitin/casein kinase (ecto-PK) is its release from the surface in a soluble form when cells are incubated with exogenous substrate protein. This is interesting in view of the fact that some ecto-enzymes are anchored to the plasma membrane via glycosylphosphatidylinositol (GPI). Such enzymes are known to be released from the surface through cleavage by a phospholipase activity. We therefore investigated whether bacterial phospholipase C (PI-PLC) was able to release ecto-PK from intact HeLa cells. The data show that whereas alkaline phosphatase, known to be GPI-anchored, was solubilized, the ecto-PK was neither released nor affected in its activity. Another effect of treatment of cells with phospholipases was the formation of diacylglycerol or phosphatidic acid which, however, did not occur when cells were incubated with phosvitin, the condition which induces ecto-PK release. These results coherently indicate that cellular phospholipases are not involved in the release mechanism of ecto-PK. Also, the presence of various protease inhibitors did not affect ecto-PK release. Cross-linking of cell-surface proteins by bifunctional agents of the succinimidyl-type suggest a protein-protein interaction responsible for membrane anchoring of the ecto-PK.
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PMID:Ecto-protein kinase release differs from cleavage by phospholipases of a glycosyl-phosphatidylinositol membrane anchor. 153 99

The role of protein kinase-C (PKC) in control of the function of rat adrenal glomerulosa cells was studied. Phorbol 12-myristate 13-acetate (PMA), an activator of PKC, inhibited the stimulation of aldosterone production induced by K+ (5.4 mM) or ACTH (5 pM) in a dose-dependent manner. Phorbol 12,13-dibutyrate, another phorbol ester that activates PKC, also exerted an inhibitory effect, while the inactive 4 alpha-phorbol 12,13-didecanoate failed to affect aldosterone production. The inhibitory effect of PMA (5 nM) was reversed by preincubation of the cells with staurosporine (ST; 50 nM), an inhibitor of PKC. These data suggest that pharmacological activation of PKC initiates an inhibitory mechanism in rat glomerulosa cells. To elucidate whether PKC is activated by physiological stimuli, the effects of ST and down-regulation of PKC by prolonged pretreatment with PMA on stimulation of aldosterone production were studied. The effects of angiotensin-II (AII) and K+, but not that of ACTH, were enhanced by ST pretreatment. This potentiation was prompt and transient in the case of AII (2.5 nM), while it developed gradually when the cells were stimulated with K+ (5.4 or 18 mM). Long term pretreatment (6 h) of glomerulosa cells with PMA also enhanced the stimulatory effect of AII (300 pM) and K+ (5.4 mM). These data together suggest that the actions of AII and K+ on aldosterone production involve a PKC-mediated inhibition. Activation of PKC by AII is probably due to formation of diacylglycerol via receptor-mediated activation of phosphoinositide-specific phospholipase-C. Stimulation with K+ caused a moderate accumulation of [3H]inositol phosphate in a concentration-dependent manner. Since this effect was abolished by nifedipine, activation of phospholipase-C may have been secondary to Ca2+ entry. The concomitant formation of diacylglycerol may contribute to activation of PKC in K+ stimulated cells. In conclusion, our data support the view that PKC participates in the physiological control of aldosterone production by rat adrenal glomerulosa cells. In addition to AII, K+ may activate PKC. Regardless of whether the enzyme is activated by phorbol esters or physiological stimuli, it exerts an inhibitory, rather than stimulatory, action on steroid production.
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PMID:The role of protein kinase-C in control of aldosterone production by rat adrenal glomerulosa cells: activation of protein kinase-C by stimulation with potassium. 154 36

Thrombin, the key regulatory protein of hemostasis, has been implicated in a variety of important endothelial cell processes closely linked to endothelial signal transduction mechanisms. An initial event, following receptor binding by catalytically active alpha-thrombin, appears to be the activation of a G-protein-coupled, PI-specific PLC, with resultant generation of IP3 and DAG, with increases in [Ca2+]i, and activation and translocation of PKC (Fig. 9). PKC activation results in down-regulation of PLC, as demonstrated by inhibition of agonist-induced increases in [Ca2+]i, whereas PLA2 activity is up-regulated, with a resultant increase in endothelial PGI2 synthesis. Recently, we have demonstrated that activity of membrane-bound, endothelial PLD, is also up-regulated by PKC activation. In addition to its modulatory role in endothelial cell phospholipase activities, PKC activation appears to play a critical role in thrombin-mediated endothelial barrier dysfunction, likely via specific cytoskeletal protein phosphorylation. A temporal relationship between alpha-thrombin-mediated signal transduction and specific cellular responses, such as PGI2 synthesis and barrier dysfunction, can be established (Fig. 2). Further investigations are ongoing to identify more clearly the precise biochemical intermediates involved in the endothelial cell response to thrombin, as well as the role of differential phosphorylation by various protein kinase systems in thrombin-mediated signal transduction in vascular endothelium.
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PMID:The role of protein kinase C in alpha-thrombin-mediated endothelial cell activation. 157 13

In the present work we evaluated the interactions of adrenergic receptors with phospholipase-C (PLC) and protein kinase-C (PKC), using an in vitro system of hypothalamic neurons and astroglial cells in primary cultures. The study was performed on immature neurons after 7 days in vitro (7 Div), that is before synaptogenesis, as well as on mature cells (14 Div). Comparisons were made between neurons and glial cells at the corresponding developmental stages. Norepinephrine (NE) increased inositol phosphates (IPs) formation in a dose- and time-dependent manner. The NE effect was mediated by alpha 1-receptor (alpha 1R) and was observed in young cells before synaptogenesis as well as in mature neuronal cultures; its amplitude was enhanced during the latter stage of the neuronal development. The coupling of alpha 1R with PLC was partially sensitive to pertussis toxin treatment and did not implicate the activation of calcium voltage-dependent channels. Activation of PKC by 12-O-Tetradecanoylphorbol 13-acetate (TPA) inhibited in a time-dependent manner the NE-stimulated production of IPs in young and mature hypothalamic neurons; however, in PKC depleted cells NE-induced IPs formation remained unchanged. In hypothalamic astroglial cell cultures the adrenergic stimulus of IPs generation was also mediated by alpha 1R. The effect was observed at both developmental stages, with a greater response in 14 Div cultures, and was insensitive to pertussis toxin treatment. As in neurons, activation of PKC resulted in inhibition of NE-induced IPs formation. These data indicate that functional interrelation between alpha 1R, PLC, and PKC is already present in immature neurons and glial cells and progressively develops in culture.
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PMID:Alpha 1-adrenergic receptor coupling with phospholipase-C is negatively regulated by protein kinase-C in primary cultures of hypothalamic neurons and glial cells. 165 54

When applied to rat anterior pituitary cells, angiotensin-II (AII) exerted two opposite effects on adenylate cyclase (AC) activity: a pertussis toxin (PTX)-sensitive inhibition of the enzyme with a maximal effect of -42 +/- 2% in crude cell membrane preparations, and, in contrast, a non-PTX-sensitive stimulation of cAMP production (maximal effect = 38 +/- 3%) in intact cells. The apparent affinity of both effects was equal to 1.8 nM. The stimulation of cAMP formation parallels the stimulation of PRL release. Under the same conditions, dopamine (DA) inhibited both membrane AC activity and cAMP formation in intact cells by a PTX-sensitive mechanism. After separation of pituitary cell types by sedimentation at unit gravity, the effects of AII and DA on intracellular cAMP and membrane AC activity coincided in the same fractions (those enriched in PRL cells). The stimulatory effect of AII on cAMP formation was about 5 times weaker than that of peptides positively coupled to AC as vasoactive intestinal peptide in total as well as in PRL-enriched cells. Since the AII receptor is also coupled to phospholipase-C (PLC) in a non-PTX-sensitive manner, we investigated whether protein kinase-C (PKC) could indirectly account for the positive effect of AII on cAMP formation. 12-O-Tetradecanolylphorbol 13-acetate (TPA), a stimulator of PKC was indeed able to increase intracellular cAMP; this effect was not additive with that of AII. conversely, application of the PKC inhibitors H7 [1-(5-isoquinolylsulfonyl)2-methyl-piperazine] and staurosporine or desensitization of PKC by long exposure of the cells to TPA abolished the cAMP response to TPA as well as that to AII. In addition, thyreoliberin, another activator of the PLC pathway, was able to stimulate cAMP formation in a PKC-dependent manner. DA inhibition of intracellular cAMP was not affected by any PKC inhibition. We conclude that in lactotroph cells, 1) the AII inhibitory coupling to AC observed in membrane preparations does not exist in intact cells, at least under basal conditions; and 2) the AII intracellular cAMP stimulation observed is not accounted for by a direct coupling with AC; it is due to a cross-talk of the PLC pathway mediated by PKC, an effect that might be shared by other PLC-stimulating mediators and may participate in the regulation of PRL release.
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PMID:Involvement of protein kinase-C in the effect of angiotensin-II on adenosine 3',5'-monophosphate production in lactotroph cells. 165 95

Purified plasma membranes from the yeast Saccharomyces cerevisiae bind about 1.2 pmol of cAMP/mg of protein with high affinity (Kd = 6 nM). By using photoaffinity labeling with 8-N3-[32P]cAMP, we have identified in plasma membrane vesicles a cAMP-binding protein (Mr = 54,000) that is present also in bcy1 disruption mutants, lacking the cytoplasmic R subunit of protein kinase A (PKA). This argues that it is genetically unrelated to PKA. Neither high salt, nor alkaline carbonate, nor cAMP extract the protein from the membrane, suggesting that it is not peripherally bound. The observation that (glycosyl)phosphatidylinositol-specific phospholipases (or nitrous acid) release the amphiphilic protein from the membrane, thereby converting it to a hydrophilic form, indicates anchorage by a glycolipidic membrane anchor. Treatment with N-glycanase reduces the Mr to 44,000-46,000 indicative of a modification by N-linked carbohydrate side chain(s). In addition to the action of a phospholipase, the efficient release from the membrane requires the removal of the carbohydrate side chain(s) or the presence of high salt or methyl alpha-mannopyranoside, suggesting complex interactions with the membrane involving not only the glycolipidic anchor but also the glycan side chain(s). Topological studies show that the protein is exposed to the periplasmic space, raising intriguing questions for the function of this protein.
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PMID:A cAMP-binding ectoprotein in the yeast Saccharomyces cerevisiae. 165 42

We have recently reported that His-D-Trp-Ala-Trp-D-Phe-Lys-NH2 (GHRP-6) synergizes with GH-releasing factor (GRF) to increase GH release and cAMP accumulation in rat pituitary cells in vitro. This study was undertaken to further investigate the mechanism of action of GHRP-6 on GH release, particularly the involvement of protein kinase-C. Forskolin (10(-5) M), A23187 (10(-6) M), and phorbol 12-myristate 13-acetate (PMA; 10(-7) M) all stimulated GH release. However, only PMA can mimic the synergistic effects of GHRP-6 on GRF-stimulated GH release and intracellular cAMP accumulation. 4 alpha-Phorbol 12,13-didecanoate, an inactive phorbol ester, was unable to stimulate GH release or potentiate the effect of GRF. Extracellularly added phospholipase-C not only stimulated GH release in a dose-dependent manner, but also potentiated GRF-induced GH release. Phloretin, a protein kinase-C inhibitor, in a concentration range of 10-250 microM had very little or no effect on basal and GRF-stimulated GH release, but markedly inhibited the stimulatory effects induced by either PMA or GHRP-6. Incubation of rat pituitary cells with 10(-6) M PMA for 24 h completely down-regulated protein kinase-C, since such PMA-pretreated cells did not release GH in response to a second dose of PMA. The protein kinase-C-depleted cells had an attenuated GHRP-6 response, but they responded normally to GRF. Moreover, the synergistic effects of GHRP-6 and GRF on GH release and cAMP accumulation were also greatly inhibited by protein kinase-C down-regulation. These data suggest that the effects of GHRP-6 on GH release, either alone or together with GRF, are at least partially mediated via the activation of protein kinase-C.
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PMID:Evidence for a role of protein kinase-C in His-D-Trp-Ala-Trp-D-Phe-Lys-NH2-induced growth hormone release from rat primary pituitary cells. 165 29

Fluoride elicited in liver macrophages a release of arachidonic acid and prostaglandins but not formation of inositol phosphates or superoxide. The effects of fluoride required extracellular calcium and were inhibited by staurosporine and by phorbol ester treatment of the cells. Furthermore, fluoride led to a translocation of protein kinase C from the cytosol to membranes. This indicates that the calcium-dependent protein kinase C is involved in the action of fluoride. Cholera toxin decreased the zymosan-induced release of arachidonic acid and prostaglandins but not of inositol phosphates or superoxide. Pertussis toxin ADP-ribosylated a 41,000 molecular weight membrane protein; enhanced specifically the zymosan-induced formation of prostaglandin(PG)E2 but did not affect the zymosan-induced release of arachidonic acid, PGD2, inositol phosphates or superoxide. These data suggest that activation of phospholipase (PL)A2, phosphoinositide (PI)-specific PLC and NADPH oxidase in liver macrophages is most probably not mediated by activation of guanine nucleotide binding (G)-proteins coupled directly to these enzymes.
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PMID:Effect of fluoride, pertussis and cholera toxin on the release of arachidonic acid and the formation of prostaglandin E2, D2, superoxide and inositol phosphates in rat liver macrophages. 166 39

Mastoparan, a tetradecapeptide purified from wasp venom, stimulates insulin and glucagon release by rat pancreatic islets in a dose-related manner. In perifusion experiments, mastoparan produces monophasic hormone release, which ceases within 10 min of removal of the peptide. After exposure of the isles to mastoparan, glucose-induced insulin release is clearly retained. In incubation experiments, mastoparan-induced insulin release is greatly blocked by pretreatment of the islets with pertussis toxin or neomycin (inhibitor of phosphoinositide turnover) or by lowering the ambient temperature to 17 C. Pretreatment of the islets with nifedipine (calcium channel blocker), H-7 (inhibitor of A- and C-kinase), somatostatin, or divalent cation-free medium does not affect the response to mastoparan. Pretreatment with parabromophenacylbromide (phospholipase-A2 inhibitor) does not block the response induced by a high concentration of (58 microM) mastoparan. The peptide does not stimulate insulin synthesis during 30 min of incubation. Mastoparan raises the cytosolic free Ca2+ concentration, measured by fura-2, in isolated islet cells at normal (1.9 mM) and very low (6.5 microM) extracellular Ca2+ concentrations. Intravenous administration of mastoparan in rats causes a significant elevation of both insulin and glucagon. Together with the previous data, we conclude that mastoparan stimulates islet hormone release through a temperature-dependent process mediated by pertussis toxin-sensitive GTP-binding protein(s). Activation of phospholipase-C and liberation of intracellular Ca2+ are likely to be coupled to exocytosis. Ca2+ influx through the Ca2+ channel and protein kinase-A and -C appear not to be involved in mastoparan's hormone-releasing action. Phospholipase-A2 may be involved in the hormone release induced by low, but not high, concentrations of the peptide.
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PMID:Mastoparan-induced hormone release from rat pancreatic islets. 172 98

Recent evidence indicates that after PTh interaction with its receptor, both protein kinase-A (PKA) and protein kinase-C (PKC) are activated. To investigate the relationship between PTH structure and protein kinase stimulation, we have analyzed the effects of synthetic PTH fragments on PKA and PKC in the rat osteogenic sarcoma cells, UMR 106-01. Activation of PKA by 10(-7) M bovine (b) PTH-(1-34) was maximal (2.7-fold of control) at 5 min and remained elevated 15 min after hormone exposure. bPTH-(2-34), at equimolar doses, also stimulated PKA, but with a lower potency (1.4-fold of control), whereas propionyl bPTH-(2-34) [pbPTH-(2-34)], bPTH-(3-34), [Tyr34]bPTH-(7-34) amide [bPTH-(7-34)], and bPTH-(30-34) were ineffective. On the other hand, translocation of PKC activity from the cytosol to the membrane after exposure to bPTH-(1-34) was transient, with a peak at 1 min (1.9-fold of control), and returned to basal levels after 5 min. Other fragments, bPTH-(2-34), pbPTH-(2-34), bPTH-(3-34), and bPTH-(7-34), were also active on PKC, with relative potencies of 81%, 67%, 62%, and 51% of bPTH-(1-34), respectively, whereas bPTH-(30-34) was inactive. bPTH-(1-34), bPTH-(2-34), pbPTH-(2-34), and bPTH-(3-34) also induced inositol 1,4,5-trisphosphate production, with a potency order of 1.6-, 1.6-, 1.5-, and 1.6-fold over the control value, respectively, thus indicating activation of phospholipase-C. Neither bPTH-(7-34) nor bPTH-(30-34) caused a statistically significant increase in inositol 1,4,5-trisphosphate production. These results demonstrate that PTH signal transduction through the two different pathways can be dissociated; while activation of the cAMP/PKA system requires amino acids 1 and 2, the phospholipase-C/PKC system is coupled to a longer domain of the hormone's N-terminus.
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PMID:Structure-function relationship of parathyroid hormone: activation of phospholipase-C, protein kinase-A and -C in osteosarcoma cells. 172 5

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