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)

Goldfish preovulatory ovarian follicles (prior to germinal vesicle breakdown) were utilized for studies investigating the actions of activators of different signal transduction pathways on prostaglandin (PG) production. The protein kinase C (PKC) activators phorbol 12-myristate 13-acetate (PMA; 100-400 nM), 1-oleoyl-2-acetylglycerol (5 and 25 micrograms/ml), and 1,2-dioctanoylglycerol (10 and 50 micrograms/ml) stimulated PGE production; the inactive phorbol 4 alpha-phorbol didecanoate, which does not activate PKC, had no effect. Calcium ionophore A23187 (0.25-4.0 microM) stimulated PGE production and acted in a synergistic manner with activators of PKC. Although produced in lower amounts than PGE, PGF was stimulated by PMA and A23187. The direct activator of phospholipase A2, melittin (0.1-1.0 microM), stimulated a dose-related increase in PGE production, whereas chloroquine (100 microM), a putative inhibitor of phospholipase A2, blocked basal and PMA + A23187-stimulated PGE production. Several drugs known to elevate intracellular levels of cAMP including the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (0.1-1.0 mM), forskolin (10 microM), and dibutyryl cAMP (dbcAMP; 5 mM) attenuate PMA + A23187-stimulated PGE production. Melittin-stimulated production of PGE was inhibited by dbcAMP, suggesting that the action of cAMP was distal to the activation of phospholipase A2. In summary, these studies demonstrate that activation of PKC and elevation of intracellular calcium levels stimulate PG production, in part, through activation of phospholipase A2. The adenylate cyclase/cAMP signalling pathway is inhibitory to PG production by goldfish ovarian follicles.
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PMID:Multifactorial regulation of prostaglandin synthesis in preovulatory goldfish ovarian follicles. 131 82

Our current working hypothesis for the intracellular mechanism of action for LH and PGF-2 alpha is shown in Fig. 8. Luteinizing hormone appears to act primarily on the small luteal cell through the cAMP/protein kinase A effector system and thereby stimulates secretion of progesterone. Activation of the protein kinase C effector pathway is inhibitory to progesterone secretion from stimulated small luteal cells but it is not clear which hormones, if any, activate this effector system. Results from studies in whole animals suggest that LH may also stimulate differentiation of small luteal cells into large luteal cells (Donaldson & Hansel, 1965; Farin et al., 1988). Although there are LH receptors on large luteal cells, LH treatment does not stimulate progesterone secretion and does not appear to activate any of the second messenger pathways which we have examined. Prostaglandin F-2 alpha appears to act on the large luteal cell through free intracellular calcium and protein kinase C effector systems. Apparently, PGF-2 alpha-induced activation of protein kinase C results in the acute inhibition of progesterone production seen in the first 8 h after PGF-2 alpha treatment. The cytotoxic effects of PGF-2 alpha on the large luteal cell (Fitz et al., 1984; Braden et al., 1988) may be caused by a sustained elevation in free intracellular calcium concentrations. No direct effects of PGF-2 alpha on small luteal cells have been detected (no inhibition of progesterone production, no activation of protein kinase C, no increase in free intracellular calcium), which is consistent with an absence of high affinity PGF-2 alpha receptors on this cell type. The cytotoxic effects of PGF-2 alpha on small luteal cells and endothelial cells (Braden et al., 1988) may be caused by decreases in luteal blood flow (Niswender et al., 1975; Wiltbank et al., 1990b), actions of cytotoxic agents released by large luteal cells, or increases in cytotoxic white blood cells (Murdoch, 1987; Bagavandoss et al., 1988).
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PMID:Differential actions of second messenger systems in the corpus luteum. 184 52

Studies of the calcium requirement and the relationship of intracellular calcium to progesterone synthesis in highly purified preparations of bovine luteal cells reveal a remarkably close relationship between intracellular calcium levels and steroidogenesis. The differential responses of the two cell types, summarized in Table 2, are beginning to reveal how the two cell types may co-operate to produce both luteotrophic and luteolytic responses at different stages of the oestrous cycle and early pregnancy. The luteotrophic mechanisms in the small cells are fairly clear; in addition to the luteotrophic effects of LH and cAMP, activation of protein kinase C leads to increased progesterone synthesis. Accordingly, PGF-2 alpha and several other prostanoids are luteotrophic in these cells. PGF-2 alpha stimulates phospholipase C activity in the small cells but does not reduce LH-stimulated cAMP or progesterone accumulation (Davis et al., 1989). This acute stimulus of protein kinase C activation to progesterone production in bovine small luteal cells is rapidly desensitized, although its stimulus to prostanoid production continues for at least 24 h. Large cells respond to LH, but only at relatively high levels. In addition, we have no good evidence for a role for protein kinase C in the control of progesterone synthesis in the large bovine luteal cells from mid-cycle corpora lutea. Phorbol esters have no effect on steroidogenesis and it is not yet established that protein kinase C provides the same high affinity receptor for phorbol esters that is found in the small cells. Experiments with inhibitors of protein kinase C, such as staurosporine, in large cells have been inconclusive. Evidence for several species suggests that both cell types co-operate, in ways not yet fully understood, to bring about maximal progesterone production at mid-cycle. Some evidence suggests that they may also co-operate to bring about luteolysis. The concept that PGF-2 alpha initiates luteolysis by inhibiting LH stimulated progesterone production in the large cells must be revised in light of the relative insensitivity of these cells to LH and the fact that they probably constitutively express the cholesterol side-chain cleavage enzymes (P-450scc) that represent the rate-limiting step in progesterone production. Oonk et al. (1989) have reported that, once P-450scc mRNA is induced in rat granulosa cells by the LH surge, it is constitutively maintained by the luteinized cells in the absence of gonadotrophins and is no longer regulated by cAMP.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Differential origin and control mechanisms in small and large bovine luteal cells. 184 53

Corpora lutea from sheep and cows as well as human and primates contain both large and small steroidogenic cells exhibiting distinct functional properties. Only the small cells seem to be able to respond in vitro to LH stimulation by raising their progesterone secretion. However, the entire progesterone secretion of the corpus luteum has been shown to be regulated in vivo by LH in the primate. The LH steroidogenic action involves the activation of membrane adenylate cyclase whose molecular mechanism has been elucidated. Then a rise in intracellular cyclic AMP induces phosphorylation by a cyclic AMP dependent protein kinase of steroidogenic protein targets which have not yet been completely identified. In sheep and cows, luteolysis is believed to be the consequence of a series of reciprocal interactions between the corpus luteum whose large cells secrete pulses of oxytocin in response to PGF2 alpha luteolysin and the endometrium which secretes pulses of PGF2 alpha in response to oxytocin. The secretion of endometrial PGF2 alpha can only begin after the induction of endometrial receptors by estradiol, from the preovulatory follicles. Similarly in women and primates luteolysis, which does not require the presence of the uterus, could be the consequence of local reciprocal paracrine interactions between luteal cells of different types. These interactions are likely to involve PGF2 alpha' oxytocin and estradiol. The biochemical mechanism responsible for the inhibition by PGF alpha of LH induced progesterone secretion in luteal cells could involve a stimulation in the cell membrane of protein kinase C and the rise of cytosolic Ca+.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Recent concepts concerning the corpus luteum]. 307 52

Phospholipases (PL) A-2 and C stimulated the outputs of prostaglandin (PG) F-2 alpha, PGE-2 and 6-keto-PGF-1 alpha from the Day-7 and Day-15 guinea-pig uterus superfused in vitro. PLC had a more pronounced effect than PLA-2, particularly on the output of PGE-2. The ratios of the outputs of PGF-2 alpha and PGE-2 were similar after stimulation by A23187 and PLA-2, but this ratio was lower after stimulation by PLC. It appears that the stimulation of endometrial PGF-2 alpha synthesis by Ca2+ is via activation of PLA-2 rather than via activation of PLC, although the PLC used was of bacterial origin (which uses phosphatidylcholine as substrate) rather than of mammalian origin (which uses phosphatidylcholine as substrate). Forskolin (which increased endometrial and myometrial cyclic AMP levels) and phorbol 12-myristate-13-acetate had no effect on uterine PG output, indicating that cyclic AMP and protein kinase C are not involved in the stimulation of endometrial PGF-2 alpha synthesis in the guinea-pig. Uterine PG output was not stimulated by 54 mM-KCl, which shows that the pulsatile nature of endometrial PGF-2 alpha synthesis and release is not due to an intermittent, synchronous depolarization of the endometrial cells.
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PMID:Effects of various factors on prostaglandin synthesis by the guinea-pig uterus. 311 14

Corpora lutea were collected from Holstein heifers on Days 10 and 12 of the oestrous cycle and the cells were dispersed with collagenase. The dispersed cells were separated into preparations of highly purified (90-99%) small (less than 20 microns) and large (greater than 25 microns) luteal cells by unit gravity sedimentation and fluorescence-activated cell sorting. Net progesterone accumulation by 1 x 10(5) small cells and 1 x 10(3) large cells during 2 and 4 h incubations, respectively, were measured after additions of LH, PGF-2 alpha, and phorbol esters, alone and in combination. Progesterone synthesis was increased (P less than 0.05) by phorbol dibutyrate (PBt2) or PGF-2 alpha (P less than 0.05) in small, but not in large, luteal cells (10.1 +/- 3.0 and 18.1 +/- 5.0 ng/10(5) cells for 0 and 50 nM-PBt2, and 19.9 +/- 3.2 and 44.2 +/- 9.3 ng/10(5) cells for 0 and 1 microgram PGF-2 alpha/ml). The previously reported stimulatory effects of PKC activation and PGF-2 alpha addition to total dispersed cell preparations are therefore entirely attributable to the small, theca-derived cells. Small cells responded to low levels of LH (9.1 +/- 1.1, 69.0 +/- 5.4 and 154.7 +/- 41.4 ng/10(5) cells for 0, 1 and 5 ng LH/ml, respectively, P less than 0.05), while large cells responded only to high levels of LH (1635 +/- 318, 2662 +/- 459 and 3386 +/- 335 pg/10(3) cells for 0, 100 and 1000 ng LH/ml, respectively, P less than 0.05). PGF-2 alpha inhibited LH-, 8-Br-cAMP- and forskolin-stimulated progesterone synthesis in the large cells (3052 +/- 380, 3498 +/- 418, 3202 +/- 391 pg/10(3) cells for 1 microgram LH/ml, and 0.5 mM-8-Br-cAMP, and 1 microM-forskolin respectively and 1750 +/- 487, 2255 +/- 468, 2165 +/- 442 pg/10(3) cells for PGF-2 alpha + LH, PGF-2 alpha + 8-Br-cAMP and PGF-2 alpha + forskolin, respectively), indicating that the inhibitory effect of PGF-2 alpha on progesterone synthesis in large cells occurs at a site distal to cAMP generation. These results suggest that the large cells are the targets of the luteolytic effects of PGF-2 alpha, while the small cells are responsible for the previously reported luteotrophic effect of PGF-2 alpha in vitro.
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PMID:Control of progesterone production in small and large bovine luteal cells separated by flow cytometry. 316 3

The purpose of this study was to investigate, through phorbol ester-induced protein kinase C (PKC) downregulation, the role of PKC in the regulation of alpha-adrenergic agonist- and prostaglandin (PG) F2 alpha-induced contraction in vascular smooth muscle. In rat aorta, long-term phorbol ester exposure (10 microM phorbol dibutyrate for 17 h), a procedure that decreased PKC activity by > 95%, and maximal phorbol myristate acetate (PMA)-induced contraction by approximately 75%, decreased tissue sensitivity to norepinephrine (NE) and PGF2 alpha 2.8- and 4.6-fold, respectively, while maximal contraction was not significantly decreased. In contrast, long-term phorbol ester exposure did not alter tissue sensitivity to KCl, while maximal KCl contraction was decreased by 40%. Long-term phorbol ester exposure, as well as short-term phorbol ester exposure (1 microM PMA for 1 h), abolished the initial transient NE contraction elicited in Ca(2+)-free solution. In contrast, long-term phorbol ester exposure did not alter the plateau NE or PGF 2 alpha contraction elicited in Ca(2+)-free solution. Short-term phorbol ester exposure of PKC-downregulated tissues potentiated the plateau PGF2 alpha contraction elicited in Ca(2+)-free solution, although the magnitude of potentiation was less than that observed in non-PKC downregulated tissues.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effects of PKC downregulation on norepinephrine- and prostaglandin F2 alpha-induced contraction in rat aorta. 765 23

We previously reported that prostaglandin F2 alpha (PGF2 alpha) receptor is coupled to pertussis toxin (PTX)-sensitive GTP-binding protein (G protein) in osteoblast-like MC3T3-E1 cells [Miwa et al. (1990): Biochem Biophys Res Commun 171:1229-1235]. In the present study, we examined the effect of PGF2 alpha on the activation of phosphatidylcholine-hydrolyzing phospholipase D in MC3T3-E1 cells. PGF2 alpha stimulated the formation of choline in a dose-dependent manner in the range between 10 nM and 10 microM. The formation of choline was stimulated by 12-O-tetradecanoylphorbol-13-acetate (TPA), a protein kinase C (PKC)-activating phorbol ester. 4 alpha-Phorbol 12, 13-didecanoate, a PKC-nonactivating phorbol ester, had little effect on choline formation. The formation of choline stimulated by a combination of PGF2 alpha and TPA was additive. Staurosporine, an inhibitor for protein kinases, which inhibited the effect of TPA on choline formation, dose-dependently enhanced the formation of choline induced by PGF2 alpha. NaF, an activator of G protein, stimulated the formation of choline. The formation of choline stimulated by a combination of PGF2 alpha and NaF was not additive. NaF-induced formation of choline was dose-dependently enhanced by staurosporine. PTX dose-dependently inhibited the PGF2 alpha-induced formation of choline. These results strongly suggest that PGF 2 alpha activates phospholipase D independently from the activation of PKC in osteoblast-like cells and PTX-sensitive G protein is involved in the PGF2 alpha-induced phospholipase D activation.
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PMID:Prostaglandin F2 alpha activates phospholipase D independently from activation of protein kinase C in osteoblast-like cells. 796 70

We investigated the signaling pathways modulating histamine- and prostaglandin F2 alpha (PGF2 alpha)-induced contractions of human chorionic vasculature. Neomycin, a phospholipase C (PLC) inhibitor, attenuated PGF2 alpha and histamine contractile responses 40 and 60%, respectively. AIF4-, a G protein stimulant, induced a strong contraction alone but blocked histamine- and PGF2 alpha-induced contractions. Staurosporine (100 nM), a protein kinase C (PKC) inhibitor, attenuated the PGF2 alpha-dependent contractions by 50% but did not affect the histamine response. However, higher nonspecific inhibitory concentrations of staurosporine (1-2 microM) abolished histamine and PGF2 alpha contractile responses, presumably by inhibiting other protein kinases. Although, the PKC phorbol 12-myristate 13-acetate (PMA) did not affect basal tension or PGF2 alpha-dependent contractions, the histamine response was attenuated by 30%. Sodium nitroprusside (SNP), a guanylyl cyclase stimulant, strongly attenuated histamine- and PGF2 alpha-induced contractions. Tension increases were similarly attenuated by forskolin and isobutylmethylxanthine (IBMX), which increase intracellular cyclic AMP. In vessel rings prelabeled with [3H]myoinositol, PGF2 alpha and histamine increased [3H]inositol phosphate (IP) production 400 and 100%, respectively, indicating that PLC is stimulated by both agonists. Neomycin inhibited histamine- and PGF2 alpha-induced increases in [3H]IP production 60 and 40%, respectively. Staurosporine (0.1-1 microM) and PMA did not affect histamine- or PGF2 alpha-stimulated IP production. AIF4-alone increased IP production but blocked histamine- and PGF(2 alpha)-dependent IP increases. These observations suggest that at least part of the contractile responses due to PGF2 alpha and histamine are associated with stimulation of PLC through an AIF4(-)-sensitive G protein. The role of PKC is variable, because PGF2 alpha but not histamine tension responses were attenuated by PKC inhibition. In addition, therapeutic agents that increase cyclic AMP and cyclic GMP attenuated histamine- and PGF2 alpha-induced contractions in human chorionic vasculature, although histamine responses were relatively more sensitive to these agents.
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PMID:Mechanisms of prostaglandin F2 alpha and histamine-induced contractions in human chorionic vasculature. 887 81

Cellular interactions mediated by both contact-dependent and contact-independent mechanisms are probably important to maintain luteal function. The present studies were performed to evaluate the effects of luteotropic and luteolytic hormones, and also intracellular regulators, on contact-dependent gap junctional intercellular communication (GJIC) of bovine luteal cells from several stages of luteal development. Bovine corpora lutea (CL) from the early, mid and late luteal phases of the estrous cycle were dispersed with collagenase and incubated with no treatment, LH, PGF or LH + PGF (Experiment 1), or with no treatment, or agonists or antagonists of protein kinase C (TPA or H-7) or calcium (A23187 or EGTA; Experiment 2). After incubation, media were collected for determination of progester-one concentrations. Then the rate of GJIC was evaluated for small luteal cells in contact with small luteal cells, and large luteal cells in contact with small luteal cells by using the fluorescence recovery after photobleaching technique and laser cytometry. Luteal cells from each stage of the estrous cycle exhibited GJIC, but the rate of GJIC was least (P < 0.05) for luteal cells from the late luteal phase. LH increased (P < 0.05) GJIC between small luteal cells from the mid and late but not the early luteal phase. PGF increased (P < 0.05) GJIC between small luteal cells from the mid luteal phase and diminished (P < 0.05) LH-stimulatory effects on GJIC between small luteal cells from the late luteal phase. Throughout the estrous cycle, TPA decreased (P < 0.05) the rate of GJIC between large and small, and between small luteal cells, and A23187 decreased (P < 0.05) the rate of GJIC between large and small luteal cells. LH and LH + PGF, but not PGF alone increased (P < 0.05) progesterone secretion by luteal cells from the mid and late luteal phases. Agonists or antagonists of PKC or calcium did not affect progesterone secretion by luteal cells. These data demonstrate that both luteal cell types communicate with small luteal cells, and the rate of communication depends on the stage of luteal development. LH and PGF affect GJIC between small luteal cells during the fully differentiated (mid-luteal) and regressing (late luteal) stages of the estrous cycle. In contrast, at all stages of luteal development, activation of PKC decreases GJIC between small and between large and small luteal cells, whereas calcium ionophore decreases GJIC only between large and small luteal cells. Luteotropic and luteolytic hormones, and intracellular regulators, may be involved in regulation of cellular interactions within bovine CL which likely is an important mechanism for coordination of luteal function.
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PMID:Gap junctional intercellular communication of bovine luteal cells from several stages of the estrous cycle: effects of prostaglandin F2 alpha, protein kinase C and calcium. 893 84


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