Protein kinase C mediates the effect of vasopressin in pituitary corticotrophs

The role of protein kinase C (PKC) on vasopressin (VP) action was investigated by inhibition of endogenous PKC using prolonged incubation of the cells with phorbol ester, and by direct measurement of PKC activity in pituitary cells. Preincubation of the cells for 6 h with 100 nM TPA at 37 C resulted in a 90% decrease in total PKC activity. In the PKC-depleted cells, cAMP responses to stimulation with 100 nM CRF for 30 min were normal, but the potentiating effects of VP and PMA on CRF-stimulated cAMP production were abolished. The stimulation of ACTH secretion by VP and PMA alone was also abolished in PKC- depleted cells. PKC activity in cytosolic and detergent-solubilized membrane fractions from enriched pituitary corticotrophs obtained by centrifugal elutriation, was directly measured by enzymatic assays and by immunoblotting techniques. Basal PKC activity was higher in the cytosol than in the membranes (8.43 +/- 0.47 and 1.93 +/- 0.11 pmol 32P incorporated/10 min, respectively). After incubation of the cells with VP for 15 min or [3H] phorbol-12-myristate-13-acetate (PMA) for 30 min, PKC activity in cytosol was decreased by 40% and 89%, respectively, while the activity in the membrane was increased by 138% and 405%, respectively. Such VP- and PMA-induced translocation of PKC was also observed when the enzyme content in the cytosol and the membranes was measured by immunoblotting using a specific anti-PKC antibody and [125I]protein A. Autoradiographic analysis of immunoblots revealed an 80 kilodalton band characteristic of PKC, with OD higher in the cytosolic than in the membrane fractions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative Analysis of PKСα and PKCζ Activities in Rat and Lamprey Erythrocytes of Different Ages

The present study aimed to find out a link between ageing of rat and lamprey erythrocytes and activity of two isoforms of protein kinase C (PKC), РKСα and РKСζ. The whole cell population was separated into fractions of different ages in Percoll density gradient. The validity of separation was confirmed by the number of immature erythrocytes, reticulocytes. PKC activity was analyzed in cytosolic and membrane cell fractions. Rat erythrocytes express both PKC isoforms, РKСα and РKСζ, whereas lamprey erythrocytes express only РKСζ. РKСα is identified as a major band at ~ 80 kDa and minor bands at ~ 55–65 kDa; РKСζ is represented by a single band at ~ 80 kDa. In young rat erythrocytes, РKСα is detected mainly in cytosolic fractions, while in membrane fractions its level is by far lower. As cells age, PKCα is translocated from the cytosol to membranes and undergoes proteolytic degradation due to repeated cycles of activation. As a result, in aged erythrocytes relative total PKCα expression (as a sum of expressions in the cytosol and membranes per total protein level) diminishes, indicating a depletion of the PKCα pool and a decline in its functional activity. In both animal species, a highest PKCζ level is observed in the cytosol of young erythrocytes. Erythrocyte ageing is accompanied by a gradual decrease in expression of free cytosolic PKCζ and concurrent increase in the level of its membrane-bound forms. However, in contrast to PKCα, PKCζ is not proteolyzed; its total level in cells and perhaps functional activity do not change throughout the erythrocyte lifespan.     

Protein kinase C activity is altered in HL60 cells exposed to 60 Hz AC electric fields

We examined the effects of electric fields (EFs) on the activity and subcellular distribution of protein kinase C (PKC) of living HL60 cells. Sixty Hertz AC sinusoidal EFs (1.5–1.000 mV/cm p-p) were applied for 1 h to cells (10⁷/ml) in Teflon chambers at 37 °C in the presence or absence of 2 μM phorbol 12-myristate 13-acetate (PMA). PMA stimulation alone evoked intracellular translocation of PKC from the cytosolic to particulate fractions. In cells that were exposed to EFs (100–1,000 mV/cm) without PMA, a loss of PKC activity from the cytosol, but no concomitant rise in particulate PKC activity, was observed. In the presence of PMA. EFs (33–330 mV/cm) also accentuated the expected loss of PKC activity from the cytosol and augmented the rise in PKC activity in the particulate fraction. These data show that EFs alone or combined with PMA promote down-regulation of cytosolic PKC activity similar to that evoked by mitogens and tumor promoters but that it does not elicit the concomitant rise in particulate activity seen with those agents. © 1996 Wiley-Liss, Inc.     

Cytosolic and Nuclear Mitogen-Activated Protein Kinases Are Regulated by Distinct Mechanisms

We have investigated the regulation and localization of mitogen-activated protein kinase (MAPK) and mitogen-activated protein kinase kinase (MAPKK) in both cytosolic and nuclear fractions of glomerular mesangial cells. p42 MAPK was localized by both immunoblot and kinase activity in both cytosol and nucleus and was rapidly activated, in both fractions, by fetal bovine serum and TPA. Downregulation of protein kinase C (PKC) by TPA inhibited stimulation of cytosolic p42 MAPK, but unexpectedly had no effect on stimulated p42 MAPK in the nucleus. Next we studied the upstream kinase p45 MAPKK by indirect immunofluorescence microscopy, Western blot analysis, and kinase specific activity. Unlike MAPK, p45 MAPKK is almost exclusively cytosolic in resting cells and kinase activity stimulated by TPA is restricted to the cytosol. Interestingly, PKC downregulation for 24 h with TPA dramatically enhanced nuclear MAPKK as assessed by all three techniques. Cytosolic stimulated MAPKK was attenuated in PKC downregulation. Collectively these results show that in mesangial cells: (i) p42 MAPK and p45 MAPKK localize in both the cytosol and the nucleus, and (ii) PKC exerts a negative effect on nuclear MAPKK activity as documented by PKC downregulation, which augments p45 MAPKK nuclear mass and activity. These results indicate that the dual regulation of these two kinases is under differential control in the cytosol and the nucleus.     

Luteotrophic action of prolactin during the early luteal phase in pigs: the involvement of protein kinases and phosphatases

Prolactin (PRL) involvement in the regulation of luteal steroidogenesis in pigs during the early luteal phase and pregnancy is well documented. The intracellular mechanism of PRL action in steroidogenic cells, however, is not fully recognized yet. In the current study, we have tested the hypothesis that protein kinase C (PKC) and tyrosine kinases (PTK) as well as serine-threonine (PP) and tyrosine phosphatases (PTP) are involved in PRL signaling in luteal cells originated from the early corpora lutea (CL) of cyclic sows. Luteal cells (50 000 cells/ml M199) were incubated for 8 h (37 degrees C) with PRL (200 ng) and low density lipoproteins (LDL) to stimulate P(4) production. In addition, treatments included: PKC inhibitors--staurosporine and chelerythrine chloride; tyrosine kinase inhibitors--genistein and tyrphostin; serine-threonine phosphatase inhibitors--okadaic acid, cantharidin (inhibitors of PP1/2A) and cypermethrin (inhibitor of PP2B); and tyrosine phosphatase inhibitor--sodium orthovanadate. Moreover, after incubation (37 degrees C) with PRL (200 ng) for 2, 5, 10 or 20 min, luteal cells were homogenized and cytosolic as well as membrane fractions have been obtained. This was followed by partial purification of the subcellular fractions by DEAE-cellulose chromatography and determination of PKC activity by measuring the transfer of (32)P from [gamma-(32)P]ATP to histone III-S. In unstimulated porcine luteal cells the major proportion of PKC activity was present in the cytosol. Incubation of luteal cells with PRL resulted in a rapid, time dependent increase in the amount of PKC activity in the membrane fraction and a decrease in the amount of PKC activity in the cytosol fraction. PKC activity in the membrane fraction was maximal after 5 min of exposure the cells to PRL. Inhibitors of PKC and PTK suppressed PRL and LDL-induced P(4) production by porcine luteal cells. It is of interest that stimulated P(4) production was also reduced by inhibitors of PTP and PP1/2A (okadaic acid, cantharidin). In contrast, cypermethrin did not affect P(4) production stimulated by PRL and LDL. The results of the current study support the hypothesis that PKC and tyrosine kinases are intracellular mediators of PRL action in porcine luteal cells during the first days of the estrous cycle. The involvement of protein phosphatases in transmission of the PRL signal in early luteal cells in pigs is also suggested.     

Characterization and distribution of protein kinase C in ovarian tissue

Although protein kinase C, an enzyme dependent on calcium, phospholipid and diacylglycerol, has been found in high levels in ovarian tissues, its biologic function is yet unknown. In initial studies on the role of this enzyme in regulating ovarian functions, we compared protein kinase C activity in subcellular fractions of porcine corpora lutea and medium follicles. Highest protein kinase C-specific activities were found in the cytosol, followed by microsomes and mitochondria for both follicles and luteal tissues. Solubilization of all membrane-containing fractions by 0.2% Triton X-100 was required for full expression (a 4-fold average increase) of protein kinase activity. Extraction of membrane fractions with 0.5 M NaCl or sonication in a hypotonic medium revealed that 90% of the total mitochondrial protein kinase C activity and 50% of the microsomal activity was tightly membrane-bound. Characterization of both cytosolic and Triton X-100 extracted membrane preparations of luteal tissue by diethylaminoethyl (DEAE)-cellulose chromatography revealed a single peak of protein kinase C activity eluting at 80 mM NaCl. Cytosolic fractions of corpora lutea contained 3 times more protein kinase C-specific activity than did cytosolic fractions of follicles. In contrast, mitochondria from medium follicles contained 30% more specific protein kinase C activity than did luteal mitochondria. These higher cytosolic levels of protein kinase C-specific activity in corpora lutea suggest that the enzyme may play an important role in the process of luteinization or in the regulation of luteal function.     

Intracellular distribution of fumarase in various animals

The subcellular distribution of fumarase was investigated in the liver of various animals and in several tissues of the rat. In the rat liver, fumarase was predominantly located in the cytosolic and mitochondrial fractions, but not in the peroxisomal fraction. The amount of fumarase associated with the microsomes was less than 5% of the total enzyme activity. The investigation of the intracellular distribution of hepatic fumarase of the rat, mouse, rabbit, dog, chicken, snake, frog, and carp revealed that the amount of the enzyme located in the cytosol was comparable to that in the mitochondria of all these animals. The subcellular distribution of the enzyme in the kidney, brain, heart, and skeletal muscle of rat, and in hepatoma cells (AH-109A) was also investigated. Among these tissues, the brain was the only exception, having no fumarase activity in the cytosolic fraction, and the other tissues showed a bimodal distribution of fumarase in the cytosol and the mitochondria. The mitochondrial fumarase was predominantly located in the matrix. About 10% of the total fumarase was found in the outer and inner membrane, although it was unclear whether this fumarase was originally located in these fractions. No fumarase activity was detected in the intermembranous space.     

Insulin stimulates the activity of a novel protein kinase C, PKC-epsilon, in cultured fetal chick neurons

In this study we examined the effects of insulin on protein kinase C (PKC) activity in cultured fetal chick neurons. PKC activity, measured as 32P incorporation into histone H1 in the presence of calcium (500 microM), phosphatidylserine (100 micrograms/ml), and diolein (3.3 micrograms/ml) minus the incorporation in the presence of calcium alone, was detected in neuronal cytosolic (207 +/- 33 pmol/min/mg) and membrane (33 +/- 8 pmol/min/mg) fractions. Insulin added to intact neurons increased the activity of PKC in both cytosolic and membrane fractions by about 40%. Neurons preincubated with cycloheximide (10 micrograms/ml) 30 min prior to insulin treatment showed the same degree of stimulation of PKC activity by insulin. The activation of PKC was maximal within 5-10 min of insulin exposure and was sustained for at least 60 min. Insulin stimulated PKC in a dose-dependent manner, with a maximal response obtained at 100 ng/ml. Addition of phosphatidylserine and diolein to neuronal cell extracts resulted in the phosphorylation of four major cytosolic proteins (70, 57, 18, and 16 kDa) and one major membrane protein (75 kDa). Phosphorylation of all five proteins was increased 2-fold in extracts from insulin-treated neurons. Immunoblot analysis of whole cell extracts using antibodies against PKC-alpha, PKC-beta, PKC-gamma, PKC-delta, and PKC-epsilon revealed that cultured fetal chick neurons contained only one of these PKC isoforms, the epsilon-isoform. The enzyme was mostly cytosolic. Insulin had no effect on either the amount of distribution of PKC-epsilon in cultured neurons but induced a small change in the mobility of PKC-epsilon on sodium dodecyl sulfate-polyacrylamide gels. When assay conditions were designed to measure specifically the activity of PKC-epsilon, using a synthetic peptide substrate in the absence of calcium, activity was 50 +/- 12% higher in insulin-treated cells (p less than 0.005). PKC activity in control and insulin treated-neurons was almost completely inhibited when assays included a peptide identical to the pseudo-substrate binding site of PKC-epsilon. We conclude that PKC-epsilon is the major PKC isoform present in cultured fetal chick neurons. Insulin stimulates PKC-epsilon activity by a mechanism that does not involve translocation of the enzyme from cytosol to membrane.     

Subcellular distribution of phospholipid-sensitive calcium-dependent protein kinase in guinea pig heart,spleen and cerebral cortex,and inhibition of the enzyme by Triton X-100

The subcellular distribution of phospholipid-sensitive Ca²⁺-dependent protein kinase in guinea pig heart was found to be: cytosol, 73%; microsome, 18%; plasma membrane, 9%; nuclei and mitochondria, < 0.1%. The enzyme in spleen and cerebral cortex was distributed nearly equally in the cytosolic and total (unfractionated) particulate fractions. The particulate enzyme in heart was released by EGTA (2.5 mM) alone but not by Triton X-100 (0.3%) alone, although a combination of the two was most effective. On the other hand, the particulate enzyme in spleen and cerebral cortex was released only by a combination of Triton X-100 and EGTA. Triton X-100 inhibited the enzyme, and this inhibition was reversed by phosphatidylserine (a phospholipid cofactor for the enzyme). The detergent, however, was without effect on cyclic AMP-dependent and cyclic GMP-dependent protein kinases.     

Enhancement of protein kinase C in murine lymphokine-activated killer cells by retinoic acid.

We previously reported that retinoic acid (RA) augmented mouse (BALB/c) lymphokine (interleukin-2)-activated killer (LAK) cell activity in a dose and time dependent manner. As evidence available has suggested the role of protein kinase C (PKC) in the regulation of cell mediated cytotoxicity, the present work was to investigate whether or not PKC may mediate the enhancement of LAK cell activity by RA. Accompanied with an augmented LAK cell activity, RA increased total PKC enzyme activity, [3H]phorbol 12,13-dibutyrate binding activity, and the amount of immunoreactive PKC. A prolonged treatment (18 h) of LAK cells with 12-O-tetradecanoylphorbol-13-acetate resulted in the loss of both PKC and LAK cell activity. PKC inhibitors, 1-(5-isoquinolinesulfonyl)-2-methyl-piperazine dihydrochloride and staurosporine, also drastically reduced LAK cell activity. Although most of the total PKC activity (97%) was detected in the cytosol fraction, the increase in PKC activity was attributed to an increased enzyme activity in both cytosol and membrane fractions, and shown to be RA dose-dependent. Kinetics study revealed that the increase in PKC was a time-dependent process and the enhancement was detectable as early as 8 h after the addition of RA to LAK cell culture. By immunoblotting, the cytosol PKC of LAK cells was shown to contain alpha and beta isoforms, but not gamma. RA further increased the expression of PKC alpha. The enhanced expression of alpha isozyme of PKC by RA was also in a dose and time dependent manner. Taken together, these results indicate that the mechanism of the augmentation of LAK cell activity by RA may in part result from the increase in PKC, especially PKC alpha isozyme.     

Differential subcellular redistribution of protein kinase C isozymes in the rat hippocampus induced by kainic acid

Protein kinase C (PKC) consists of a family of Ca2+/phospholipid-dependent isozymes that has been implicated in the delayed neurotoxic effects of glutamate in vitro. In the present study, we assessed the effect of the glutamate analogue kainic acid (KA) on the subcellular expression of PKC isozymes in the hippocampus (HPC) in the period preceding (0.5, 1.5, 12, and 24 h) and during (120 h) hippocampal necrosis using western blot analysis and PKC isozyme-specific antibodies. Before subcellular fractionation (cytosol + membrane), hippocampi were microdissected into "HPC" (fields CA1-CA3) and "dentate gyrus" (DG; granule cells + hilus) regions. Four general patterns of alterations in PKC isozyme expression/distribution were observed following KA treatment. The first pattern was a relative stability in expression following KA treatment and was most apparent for cytosol PKCalpha (HPC + DG) and membrane (HPC) and cytosol (DG) PKCbetaII. The second pattern, observed with PKCgamma and PKCepsilon, was characterized by an initial increase in expression in both membrane and cytosolic fractions before seizure activity (0.5 h) followed by a gradual decrease until significant reductions are observed by 120 h. The third pattern, exhibited by PKCdelta, involved an apparent translocation, increasing in the membrane and decreasing in the cytosol, followed by down-regulation in both fractions and subsequent recovery. The fourth pattern was observed with PKCzeta only and entailed a significant reduction in expression before and during limbic motor seizures followed by a dramatic fivefold increase in the membrane fraction during the period of hippocampal necrosis (120 h). Although these patterns did not segregate according to conventional PKC isozyme classifications, they do indicate dynamic isozyme-specific regulation by KA. The subcellular redistribution of PKC isozymes may contribute to the histopathological sequelae produced by KA in the hippocampus and may model the pathogenesis associated with diseases involving glutamate-induced neurotoxicity.     

Receptor- and phorbol-ester-mediated redistribution of protein kinase C in human platelets. Evidence that aggregation promotes degradation of protein kinase C.

Translocation of Ca2+/phospholipid-dependent protein kinase (PKC) activity from cytosolic to membrane fractions was assessed in washed human platelet suspensions. Phorbol myristate acetate (PMA) induced a rapid loss of PKC activity from the cytosolic compartment in stirred platelets, which was not accompanied by measurable increases in membrane-associated activity, but was paralleled by a decrease in total cellular enzyme activity (cytosol plus membrane). When platelet aggregation was prevented by not stirring, (i) cytosolic activity was decreased by PMA, (ii) significant and maintained (1-15 min with PMA) increases in membrane-bound PKC were detected, and (iii) the decline in total enzyme activity was markedly slower. In stirred platelets, total and specific inhibition of PMA-induced aggregation by a fibrinogen-derived peptide (RGDS, i.e. Arg-Gly-Asp-Ser) promoted maximal increases in membrane-associated PKC in the presence of PMA and completely prevented the loss in cellular activity. Thrombin and collagen both induced a decrease in cytosolic PKC and a loss of total activity, but a significant rise in membrane activity was seen only with collagen; ADP had no detectable effect on enzyme distribution. These results demonstrate an agonist-induced redistribution of PKC and indicate that platelet aggregation may play an important role in the proteolysis, and hence persistence, of membrane-associated PKC. This observation has implications for the potency and duration of PKC-mediated responses induced by agonists and exogenous PKC activators.     

Phosphatidylinositol kinase,phosphatidylinositol-4-phosphate kinase and diacylglycerol kinase activities in rat brain subcellular fractions

Subcellular fractions isolated and purified from rat brain cerebral cortices were assayed for phosphatidylinositol (PI-), phosphatidylinositol-4-phosphate (PIP-), and diacylglycerol (DG-) kinase activities in the presence of endogenous or exogenously added lipid substrates and [γ-³²P]ATP. Measurable amounts of all three kinase activities were observed in each subcellular fraction, including the cytosol. However, their subcellular profiles were uniquely distinct. In the absence of exogenous lipid substrates, PI-kinase specific activity was greatest in the microsomal and non-synaptic plasma membrane fractions (150–200 pmol/min per mg protein), whereas PIP-kinase was predominantly active in the synaptosomal fraction (136 pmol/min per mg protein). Based on percentage of total protein, total recovered PI-kinase activity was most abundant in the cytosolic, synaptosomal, microsomal and mitochondrial fractions (4–11 nmol/min). With the exception of the microsomal fraction, a similar profile was observed for PIP-kinase activity when assayed in the presence of exogenous PIP (4 nmol/20 mg protein in a final assay volume of 0.1 ml). Exogenous PIP (4 nmol/20 mg protein) inhibited PI-kinase activity in most fractions by 40–70%, while enhancing PIP-kinase activity. PI- and PIP-kinase activities were observed in the cytosolic fraction when assayed in the presence of exogenously added PI or PIP, respectively, but not in heat-inactivated membranes containing these substrates. When subcellular fractions were assayed for DG-kinase activity using heat-inactivated DG-enriched membranes as substrate, DG-kinase specific activity was predominantly present in the cytosol. However, incubation of subcellular fractions in the presence of deoxycholate resulted in a striking enhancement of DG-kinase activities in all membrane fractions. These findings demonstrate a bimodal distribution between particulate and soluble fractions of all three lipid kinases, with each exhibiting its own unique subcellular topography. The preferential expression of PIP-kinase specific activity in the synaptic membranes is suggestive of the involvement of PIP₂ in synaptic function, while the expression of PI-kinase specific activity in the microsomal fraction suggests additional, yet unknown, functions for PIP in these membranes.     

Epstein-Barr病毒感染对CNE-2Z不同细胞组分中PKC和TPK活性的影响

研究EBV体外再感染CNE-2Z细胞后,不同组分中PKC(蛋白激酶C)和TPK(酪氨酸蛋白激酶)活性的影响,并探讨PKC和TPK活性与细胞增殖的关系。实验分三组即对照组、EBV组和EBV+TPA组,用免疫细胞化学(以小鼠抗EB病毒早期抗原)检测EBV在体外能否再感染CNE-2Z细胞,用特异底物法和特异激活剂法分别测定其PKC和TPK活性,MTT法检测CNE-2Z细胞体外增殖能力。结果显示未处理CNE-2Z细胞中PKC活性为膜性>胞核>胞液,TPK为胞核>膜性>胞液。EBV和EBV+TPA再感染CNE-2Z细胞后,抑制细胞增殖,同时胞液PKC和TPK活性升高,膜性和胞核TPK和膜性PKC活性降低。本研究结果提示,EBV可能通过影响不同细胞组分中PKC和TPK活性来调节CNE-2Z鼻咽癌细胞的增殖。     

Translocation of protein kinase C in rat basophilic leukemic cells induced by phorbol ester or by aggregation of IgE receptors

Rat basophilic leukemic cells contain protein kinase C (PKC), 96 +/- 1% of which is located in the cytosol in the resting state. Phorbol ester (PMA), synergistically with calcium ionophore (A23187), caused 55% of the total PKC activity to associate rapidly with membranes where it remained for at least 20 min. When IgE-loaded cells were activated by Ag, maximally 30% of the cytosolic activity associated with membranes within 15 to 30 s, but most of this returned to the cytosol by 2 min. The small amount (3%) of PKC activity that remained associated with the membranes did so for at least 20 min but only if aggregation of the receptors was maintained. PKC translocation correlated with aggregation of receptors both at 30 s and at 10 min. However, only the translocation at 10 min and not that at 30 s correlated with receptor-induced exocytosis. In the absence of extracellular calcium (no exocytosis is observed), translocation at 30 s was diminished by 30% and at 10 min was completely absent. Cells depleted of PKC by 18-h treatment with PMA failed to degranulate in response to PMA and A23187 but responded partially (35%) when receptors were aggregated. We conclude that translocation of PKC is an early event that follows aggregation of IgE receptors but may not be essential for mediating the exocytotic mechanism induced by these receptors.     

Alteration in protein kinase C activity and subcellular distribution in sickle erythrocytes

In agreement with previous data, membrane protein phosphorylation was found to be altered in intact sickle cells (SS) relative to intact normal erythrocytes (AA). Similar changes were observed in their isolated membranes. The involvement of protein kinase C (PKC) in this process was investigated. The membrane PKC content in SS cells, measured by [3H]phorbol ester binding, was about 6-times higher than in AA cells. In addition, the activity of the enzyme, measured by histone phosphorylation was also found to be increased in SS cell membranes but decreased in their cytosol compared to the activity in AA cell membranes and cytosol. The increase in membrane PKC activity was observed mostly in the light fraction of SS cells, fractionated by density gradient, whereas the decrease in cytosolic activity was only observed in the dense fraction. PKC activity, measured in cells from the blood of reticulocyte-rich patients, exhibited an increase in both membranes and cytosol, thus explaining some of the effects observed in the SS cell light fraction, which is enriched in reticulocytes. The increase in PKC activity in the membranes of SS cells is partly explained by their young age but the loss of PKC activity in their cytosol, particularly in that of the dense fraction, seems to be specific to SS erythrocytes. The relative decrease in membrane PKC activity between the dense and the light fractions of SS cells might be related to oxidative inactivation of the enzyme.     

Levels of protein kinase C activity in human gastrointestinal cancers

The protein kinase C (PKC) activities of tumor tissue and adjacent normal mucosa of human cancers of the esophagus (8 cases), stomach (1 case) and colon (3 cases) were measured. Considerable variations were found in the activity of PKC and in its subcellular distribution in these cancers. The PKC activities of the membrane and cytosolic fractions of the eight esophageal cancers were, however, similar to those of the adjacent normal mucosa: the average PKC activities of the tumor tissues and normal mucosa were 7.5 and 8.3 pmol/min/mg protein, respectively, in their membrane fractions and 7.9 and 7.8 pmol/min/mg protein, respectively, in their cytosolic fractions.     

Oxidant and angiotensin II-induced subcellular translocation of protein kinase C in pulmonary artery endothelial cells

We recently reported that nitrogen dioxide (NO₂), an environmental oxidant, alters the dynamics of the plasma membrane lipid bilayer structure, resulting in increased phosphatidylserine content and angiotensin II (Ang II) receptor binding. Angiotensin II is known to elicit receptor-mediated stimulation of diacylglycerol (DAG) production in pulmonary artery endothelial cells. Because protein kinase C (PKC) is a phosphatidylserine-dependent enzyme and is activated by DAG, we examined whether NO₂ resulted in activation and/or translocation of PKC from predominantly cytosolic to membrane fractions of these cells. We also evaluated whether NO₂ exposure resulted in increased production of DAG in pulmonary artery endothelial cells. Exposure to 5 ppm NO₂ for 1–24 hr resulted in significant increases in PKC activity in the cytosolic and membrane fractions (p < 0.05 for both fractions) compared to activities in control fractions. Exposure to Ang II resulted in translocation of PKC activity from cytosol to membrane fractions of both control and NO₂-exposed cells. This translocation of PKC from cytosolic to membrane fraction was prevented by the specific receptor antagonist [Sar¹ Ile⁸] Ang II. Exposure of 5 ppm NO₂ for 1–24 hr provoked rapid increases in [³H]glycerol labeling of DAG in pulmonary artery endothelial cells. These results demonstrate that exposure to NO₂ increases the production of second messenger DAG and activates PKC in both the cytosolic and membrane fractions, whereas Ang II stimulates the redistribution of PKC from cytosolic to membrane fractions of pulmonary artery endothelial cells.     

Characterization of calcium-dependent forms of protein kinase C in adult rat ventricular myocytes

The presence and subcellular localization of the Ca2+-dependent protein kinase C (PKC) isoforms and were investigated in freshly isolated adult rat cardiac ventricular myocytes. PKC activity was measured in cytosolic and particulate fractions prepared from control myocytes and those treated with either phorbol ester (phorbol 12-myristate 13-acetate, PMA) or a permeant synthetic diacylglycerol analog (1-oleoyl-2-acetylglycerol, OAG) in the absence or presence of an inhibitor of diacylglycerol kinase activity, compound R59022. Preliminary studies detected no Ca2+-/phospholipid-dependent histone kinase activity in either subcellular fraction. To reproducibly observe Ca2+-/phospholipid-dependent protein kinase activity, partial purification using a MonoQ HR 5/5 column and the presence of the peptide inhibitor of the cAMP-dependent protein kinase were essential. MonoQ chromatography of cytosolic and particulate fractions resulted in three peaks of Ca2+/phospholipid-dependent protein kinase activity. In the cytosolic fraction a large peak of activity eluted at 230-300 mM NaCl. Isoform-specific antisera indicated both PKC and PKC were present. In the particulate fraction two peak of Ca2+-/phospholipid-dependent protein kinase activity, both containing PKCa immunoreactivity, were observed. The larger peak eluted at 230-300 mM NaCl. In addition, a peak eluting at lower salt concentrations contained a Ca2+-/phospholipid-independent histone kinase activity. This peak of kinase activity contained PKC immunoreactive bands of 80- and 50-kDa. The 80-kDa band was the holoenzyme of PKC whereas the band of lower molecular mass was likely a proteolytic fragment. In both cytosolic and particulate fractions, the peak of kinase activity eluting at 230-300 mM NaCl contained PKC in the form of an 80-kDa doublet; this suggested the presence of autophosphorylated PKC. Incubation of the myocytes with PMA, but not OAG, resulted in translocation of PKC from the cytosolic to the particulate fraction. Curiously, a transient decrease in PKC activity was observed in both subcellular fractions following treatment with either OAG or ethanol (1%). Results from this study show that freshly isolated adult rat cardiac ventricular myocytes contain both PKC and PKC, and that these isoforms translocate to the particulate fraction in response to treatment with PMA, but not OAG. (Mol Cell Biochem 166: 11-23, 1997)     

Effect of parathyroid hormone on rat renal cAMP-dependent protein kinase and protein kinase C activity measured using synthetic peptide substrates

The actions of parathyroid hormone (PTH) on the renal cortex are thought to be mediated primarily by cAMP-dependent protein kinase (PKA) with some suggestion of a role for protein kinase C (PKC). However, present methods for assaying PKA and PKC in subcellular fractions are insensitive and require large amounts of protein. Recently, a sensitive method for measuring the activity of protein kinases has been reported. This method uses synthetic peptides as substrates and a tandem chromatographic procedure for isolating the phosphorylated peptides. We have adapted this method to study the effect of PTH on PKA and PKC activity using thin slices of rat renal cortex. PTH (250 nM) stimulated cytosolic PKA activity four- to fivefold within 30 s, and PKA activity was sustained for at least 5 min. PTH also rapidly stimulated PKC activity in the membrane fraction and decreased PKC activity in the cytosol. These changes were maximal at 30 s, but unlike changes in PKA, they declined rapidly thereafter. PTH significantly activated PKC only at concentrations of 10 nM or greater. This study demonstrates that PTH does activate PKC in renal tissue, although the duration of activation is much less than for PKA. It also demonstrates that a combination of synthetic peptides with tandem chromatography can be used as a sensitive assay procedure for protein kinase activity in biological samples.