Protein Kinase C Activity Ratio Research Articles

Protein Kinase C Activity and Delayed Recovery of Sleep-Wake Cycle in Mouse Model of Bipolar Disorder

ObjectivePrevious studies reported the delayed recovery group after circadian rhythm disruption in mice showed higher quinpiroleinduced locomotor activity. This study aimed to compare not only Protein Kinase C (PKC) activities in frontal, striatal, hippocampus and cerebellum, but also relative PKC activity ratios among brain regions according to recovery of circadian rhythm. MethodsThe circadian rhythm disruption protocol was applied to eight-week-old twenty male Institute Cancer Research mice. The circadian rhythm recovery patterns were collected through motor activities measured by Mlog system. Depressive and manic proneness were examined by forced swim test and quinpirole-induced open field test respectively. Enzyme-linked immunosorbent assay was employed to measure PKC activities. ResultsThe delayed recovery group presented greater locomotor activities than the early recovery group (p=0.033). The delayed recovery group had significantly lower frontal PKC activity than the other (p=0.041). The former showed lower frontal/cerebellar PKC activity ratio (p=0.047) but higher striatal/frontal (p=0.038) and hippocampal/frontal (p=0.007) PKC activities ratios than the latter. ConclusionThese findings support potential mechanism of delayed recovery after circadian disruption in bipolar animal model could be an alteration of relative PKC activities among mood regulation related brain regions. It is required to investigate the PKC downstream signaling related to the delayed recovery pattern.

α- and ϵ-Protein Kinase C Activity during Smooth Muscle Cell Apoptosis in Response to γ-Radiation

The use of gamma-radiation in treatment of pelvic cancer is associated with injury of healthy surrounding tissues and disorders of intestinal motility; however, the cellular mechanisms involved are unclear. We tested the hypothesis that exposure of visceral smooth muscle cells (SMCs) to gamma-radiation induces apoptosis via activation of specific protein kinase C (PKC) isoforms. Cultured SMCs and slices from guinea pig ileum smooth muscle longitudinal layer (GPISMLL) were exposed to 10 to 50 Gy. Flow cytometry in gamma-radiated SMCs showed increased percentage of cells in the sub-G(0)/G(1) phase, a hallmark of apoptosis. gamma-Radiation-induced reduction in cell survival was partially but significantly alleviated with the PKC inhibitors. Sections of gamma-irradiated GPISMLL showed DNA fragmentation and apoptotic bodies analyzed by the terminal deoxynucleotidyl transferase dUTP nick-end labeling method, whereas the plasma and nuclear membranes were preserved. Confocal microscopy in gamma-radiated SMCs labeled with annexin V-fluorescein showed an increase in apoptotic cells and phosphatidylserine externalization. Contraction of GPISMLL strips in response to KCl and acetylcholine was reduced in tissues exposed to 30 and 50 Gy. gamma-Radiation of GPISMLL caused an increase in PKC activity in the particulate fraction, a decrease in the cytosolic fraction, and increased particulate/cytosolic PKC activity ratio. Western blot analysis revealed significant amounts of alpha- and epsilon-PKC in the cytosolic fraction of control GPISMLL. gamma-Radiation caused an increase in the amount of alpha- and epsilon-PKC in the particulate fraction and a decrease in the cytosolic fraction. Data suggest that gamma-radiation induces apoptosis, growth arrest, and contractile dysfunction in visceral SMCs of GPISMLL via activation and translocation of alpha- and epsilon-PKC isoforms.

Endothelin-1 enhances eicosanoids-induced coronary smooth muscle contraction by activating specific protein kinase C isoforms.

Endothelin-1 (ET-1), a potent vasoconstrictor, has been implicated in the pathogenesis of coronary vasospasm by enhancing coronary vasoconstriction to vasoactive eicosanoids; however, the cellular mechanisms involved are unclear. We investigated whether physiological concentrations of ET-1 enhance coronary smooth muscle contraction to vasoactive eicosanoids by activating specific protein kinase C (PKC) isoforms. Cell contraction was measured in single smooth muscle cells isolated from porcine coronary arteries, intracellular free Ca(2+) ([Ca(2+)](i)) was measured in fura-2-loaded cells, and the cytosolic and particulate fractions were examined for PKC activity and reactivity with isoform-specific anti-PKC antibodies using Western blots. In Hanks' solution (1 mmol/L Ca(2+)), ET-1 (10 pmol/L) did not increase basal [Ca(2+)](i) (81+/-2 nmol/L), but it did cause cell contraction (9%) that was inhibited by GF109203X (10(-6) mol/L), an inhibitor of Ca(2+)-dependent and Ca(2+)-indpendent PKC isoforms. The vasoactive eicosanoid prostaglandin F(2alpha) (PGF(2alpha), 10(-7) mol/L) caused increases in cell contraction (11%) and [Ca(2+)](i) (108+/-7 nmol/L) that were inhibited by the Ca(2+) channel blocker diltiazem (10(-6) mol/L). Pretreatment with ET-1 (10 pmol/L) for 10 minutes enhanced cell contraction to PGF(2alpha) (35%) with no additional increase in [Ca(2+)](i) (112+/-8 nmol/L). Direct activation of PKC by phorbol 12,13-dibutyrate (PDBu, 10(-7) mol/L) caused cell contraction (10%) and enhanced PGF(2alpha) contraction (33%) with no additional increase in [Ca(2+)](i) (115+/-7 nmol/L). The ET-1-induced enhancement of PGF(2alpha) contraction was inhibited by Gö6976 (10(-6) mol/L), an inhibitor of Ca(2+)-dependent PKC isoforms. Both ET-1 and PDBu caused an increase in PKC activity in the particulate fraction and a decrease in the cytosolic fraction and increased the particulate/cytosolic PKC activity ratio. Western blots revealed the Ca(2+)-dependent alpha-PKC and the Ca(2+)-independent delta-, epsilon-, and zeta-PKC isoforms. In resting tissues, alpha- and epsilon-PKC were mainly cytosolic, delta-PKC was mainly in the particulate fraction, and zeta-PKC was equally distributed in the cytosolic and particulate fraction. ET-1 (10 pmol/L) alone or PDBu (10(-7) mol/L) alone caused translocation of epsilon-PKC from the cytosolic to the particulate fraction, localized delta-PKC more in the particulate fraction, but did not change the distribution of zeta-PKC. PGF(2alpha) (10(-7) mol/L) alone did not change PKC activity. In tissues pretreated with ET-1 or PDBu, PGF(2alpha) caused additional increases in alpha-PKC activity. Thus, the enhancement of PGF(2alpha)-induced coronary smooth muscle contraction by physiological concentrations of ET-1 involves activation and translocation of alpha-PKC in addition to delta- and epsilon-PKC isoforms, and this may represent one possible cellular mechanism by which ET-1 could enhance coronary vasoconstriction to vasoactive eicosanoids in coronary vasospasm.

Oxidized-LDL enhances coronary vasoconstriction by increasing the activity of protein kinase C isoforms alpha and epsilon.

Oxidized low-density lipoprotein (ox-LDL) plays a critical role in the development of atherosclerotic coronary vasospasm; however, the cellular mechanisms involved are not fully understood. We tested the hypothesis that ox-LDL enhances coronary vasoconstriction by increasing the activity of specific protein kinase C (PKC) isoforms in coronary smooth muscle. Active stress was measured in de-endothelialized porcine coronary artery strips; cell contraction and [Ca(2+)](i) were monitored in single coronary smooth muscle cells loaded with fura-2; and the cytosolic and particulate fractions were examined for PKC activity and reactivity with isoform-specific anti-PKC antibodies with Western blots. Ox-LDL (100 microgram/mL) caused slow but significant increases in active stress to 1.3+/-0.4x10(3) N/m(2) and cell contraction (10%) that were completely inhibited by GF109203X (10(-6) mol/L), an inhibitor of Ca(2+)-dependent and -independent PKC isoforms, with no significant change in [Ca(2+)](i). 5-Hydroxytryptamine (5-HT; 10(-7) mol/L) and KCl (24 mmol/L) caused increases in cell contraction and [Ca(2+)](i) that were inhibited by the Ca(2+) channel blocker verapamil (10(-6) mol/L). Ox-LDL enhanced coronary contraction to 5-HT and KCl with no additional increases in [Ca(2+)](i). Direct activation of PKC by phorbol 12-myristate13-acetate (PMA; 10(-7) mol/L) caused a contraction similar in magnitude and time course to ox-LDL-induced contraction and enhanced 5-HT- and KCl-induced contraction with no additional increases in [Ca(2+)](i). The ox-LDL-induced enhancement of 5-HT and KCl contraction was inhibited by Gö6976 (10(-6) mol/L), an inhibitor of Ca(2+)-dependent PKC isoforms. Both ox-LDL and PMA caused an increase in PKC activity in the particulate fraction, a decrease in the cytosolic fraction, and an increase in the particulate/cytosolic PKC activity ratio. Western blots revealed the Ca(2+)-dependent PKC-alpha and the Ca(2+)-independent PKC-delta, -epsilon, and -zeta isoforms. In unstimulated tissues, PKC-alpha- and -epsilon were mainly cytosolic, PKC-delta was mainly in the particulate fraction, and PKC-zeta was equally distributed in the cytosolic and particulate fractions. Ox-LDL alone or PMA alone caused translocation of PKC-epsilon from the cytosolic to particulate fraction, whereas the distribution pattern of PKC-alpha, -delta, and -zeta remained unchanged. 5-HT (10(-7) mol/L) alone and KCl alone did not change PKC activity. In tissues pretreated with ox-LDL or PMA, 5-HT and KCl caused additional increases in PKC-alpha activity. Native LDL did not significantly affect coronary contraction, [Ca(2+)](i), or PKC activity. These results suggest that ox-LDL causes coronary contraction via activation of the Ca(2+)-independent PKC-epsilon and enhances the contraction to [Ca(2+)](i)-increasing agonists by activating the Ca(2+)-dependent PKC-alpha. Activation of PKC-alpha and -epsilon may represent a possible cellular mechanism by which ox-LDL could enhance coronary vasospasm.

Oxidized-Ldl Enhances Coronary Vasoconstriction by Increasing the Activity of α and ε Protein Kinase C Isoforms

31 Oxidized low density lipoprotein (ox-LDL) plays a critical role in the development of atherosclerotic coronary vasospasm; however, the cellular mechanisms involved are not fully understood. We tested the hypothesis that ox-LDL enhances coronary vasoconstriction by increasing the activity of specific protein kinase C (PKC) isoforms in coronary smooth muscle. Active stress was measured in de-endothelialized porcine coronary artery strips, [Ca 2+ ] i was monitored in single coronary smooth muscle cells loaded with fura-2, and the whole tissue, cytosolic and particulate fractions were examined for PKC activity and reactivity with isoform-specific anti-PKC antibodies using Western blot analysis. Ox-LDL (100 μg/ml) caused a slow but significant increase in active stress to 1.2±0.2 x10 3 N/m 2 , that was completely inhibited by the PKC inhibitors staurosporine and calphostin C, with no significant increase in [Ca 2+ ] i . Ox-LDL enhanced coronary contraction to increasing concentrations of 5-hydroxytryptamine (5-HT) and extracellular KCl with no additional increases in [Ca 2+ ] i . Direct activation of PKC by phorbol 12,13-dibutyrate (PDBu, 0.1 μM) caused a contraction similar in magnitude and time course to ox-LDL induced contraction. PDBu also enhanced 5-HT and KCl-induced contraction with no additional increases in [Ca 2+ ] i . Both ox-LDL and PDBu caused an increase in PKC activity in the particulate fraction and a decrease in the cytosolic fraction and increased the particulate/cytosolic PKC activity ratio. Western blot analysis revealed α-, δ-, ε- and ζ-PKC isoforms. In unstimulated tissue, α- and ε-PKC were mainly cytosolic, δ-PKC was mainly in the particulate fraction, while ζ-PKC was equally distributed in the cytosolic and particulate fractions. Ox-LDL and PDBu caused translocation of α- and ε-PKC from the cytosolic to particulate fraction, with minimal effect on the distribution of δ-PKC and ζ-PKC. Native LDL did not significantly affect coronary contraction, [Ca 2+ ] i or PKC activity. These results suggest that ox-LDL enhances coronary vasoconstriction via activation and translocation of α- and ε-PKC isoforms in coronary smooth muscle.

Isoform-specific protein kinase C activity at variable Ca2+ entry during coronary artery contraction by vasoactive eicosanoids

Vasoactive eicosanoids have been implicated in the pathogenesis of coronary vasospasms. The signaling mechanisms of eicosanoid-induced coronary vasoconstriction are unclear, and a role for protein kinase C (PKC) has been suggested. Activated PKC undergoes translocation to the surface membrane in the vicinity of Ca2+ channels; however, the effect of Ca2+ entry on the activity of the specific PKC isoforms in coronary smooth muscle is unknown. In the present study, 45Ca2+ influx and isometric contraction were measured in porcine coronary artery strips incubated at increasing extracellular calcium concentrations ([Ca2+]e) and stimulated with prostaglandin F2α (PGF2α) or the stable thromboxane A2 analog U46619, while in parallel, the cytosolic (C) and particulate (P) fractions were examined for PKC activity and reactivity with anti-PKC antibodies using Western blot analysis. At 0-300 µM [Ca2+]e, both PGF2α and U46619 (10-5 M) significantly increased PKC activity and contraction in the absence of a significant increase in 45Ca2+ influx. At 600 µM [Ca2+]e, PGF2α and U46619 increased P/C PKC activity ratio to a peak of 9.52 and 14.58, respectively, with a significant increase in 45Ca2+ influx and contraction. The 45Ca2+ influx - PKC activity - contraction relationship showed a 45Ca2+-influx threshold of ~7 µmol·kg-1·min-1 for maximal PKC activation by PGF2α and U46619. 45Ca2+ influx > 10 µmol·kg-1·min-1 was associated with further increases in contraction despite a significant decrease in PKC activity. Western blotting analysis revealed α-, δ-, ε-, and ζ-PKC in porcine coronary artery. In unstimulated tissues, α- and ε-PKC were mostly distributed in the cytosolic fraction. Significant eicosanoid-induced translocation of ε-PKC from the cytosolic to the particulate fraction was observed at 0 [Ca2+]e, while translocation of α-PKC was observed at 600 µM [Ca2+]e. Thus, a significant component of eicosanoid-induced coronary contraction is associated with significant PKC activity in the absence of significant increase in Ca2+ entry and may involve activation and translocation of the Ca2+-independent ε-PKC. An additional Ca2+-dependent component of eicosanoid-induced coronary contraction is associated with a peak PKC activity at submaximal Ca2+ entry and may involve activation and translocation of the Ca2+-dependent α-PKC. The results also suggest that a smaller PKC activity at supramaximal Ca2+ entry may be sufficient during eicosanoid-induced contraction of coronary smooth muscle.Key words: protein kinase C, isoform, calcium influx, eicosanoids, vascular smooth muscle, contraction.

Diacylglycerol-induced protection against injury during ischemia and reperfusion in the rat heart:: Comparative studies with ischemic preconditioning

The role of protein kinase C (PKC) activation in ischemic preconditioning remains controversial. Since diacylglycerol is the endogenous activator of PKC and as such might be expected cardioprotective, we have investigated whether: (i) the diacylglycerol analog 1,2-dioctanoyl- sn-glycerol (DOG) can protect against injury during ischemia and reperfusion; (ii) any effect is mediated via PKC activation; and (iii) the outcome is influenced by the time of administration. Isolated rat hearts were perfused with buffer at 37°C and paced at 400 bpm. In Study 1, hearts ( n=6/group) were subjected to one of the following: (1) 36 min aerobic perfusion (controls); (2) 20 min aerobic perfusion plus ischemic preconditioning (3 min ischemia/3 min reperfusion+5 min ischemia/5 min reperfusion); (3) aerobic perfusion with buffer containing DOG (10 μM) given as a substitute for ischemic preconditioning; (4) aerobic perfusion with DOG (10 μM) during the last 2 min of aerobic perfusion. All hearts then were subjected to 35 min of global ischemia and 40 min reperfusion. A further group (5) were perfused with DOG (10 μM) for the first 2 min of reperfusion. Ischemic preconditioning improved postischemic recovery of LVDP from 24±3% in controls to 71±2% ( P<0.05). Recovery of LVDP also was enhanced by DOG when given just before ischemia (54±4%), however, DOG had no effect on the recovery of LVDP when used as a substitute for ischemic preconditioning (22±5%) or when given during reperfusion (29±6%). In Study 2, the first four groups of study were repeated ( n=4–5/group) without imposing the periods of ischemia and reperfusion, instead hearts were taken for the measurement of PKC activity (pmol/min/mg protein±SEM). PKC activity after 36 min in groups (1), (2), (3) and (4) was: 332±102, 299±63, 521±144, and 340±113 and the membrane:cytosolic PKC activity ratio was: 5.6±1.5, 5.3±1.8, 6.6±2.7, and 3.9±2.1 ( P=NS in each instance). In conclusion, DOG is cardioprotective but under the conditions of the present study is less cardioprotective than ischemic preconditioning, furthermore the protection does not appear to necessitate PKC activation prior to ischemia.

Isoform-specific protein kinase C activity at variable Ca2+ entry during coronary artery contraction by vasoactive eicosanoids.

Vasoactive eicosanoids have been implicated in the pathogenesis of coronary vasospasms. The signaling mechanisms of eicosanoid-induced coronary vasoconstriction are unclear, and a role for protein kinase C (PKC) has been suggested. Activated PKC undergoes translocation to the surface membrane in the vicinity of Ca2+ channels; however, the effect of Ca2+ entry on the activity of the specific PKC isoforms in coronary smooth muscle is unknown. In the present study, 45Ca2+ influx and isometric contraction were measured in porcine coronary artery strips incubated at increasing extracellular calcium concentrations ([Ca2+]e) and stimulated with prostaglandin F2alpha (PGF2alpha) or the stable thromboxane A2 analog U46619, while in parallel, the cytosolic (C) and particulate (P) fractions were examined for PKC activity and reactivity with anti-PKC antibodies using Western blot analysis. At 0-300 microM [Ca2+]e, both PGF2alpha and U46619 (10(-5) M) significantly increased PKC activity and contraction in the absence of a significant increase in 45Ca2+ influx. At 600 microM [Ca2+]e, PGF2alpha and U46619 increased P/C PKC activity ratio to a peak of 9.52 and 14.58, respectively, with a significant increase in 45Ca2+ influx and contraction. The 45Ca2+ influx--PKC activity--contraction relationship showed a 45Ca2+-influx threshold of approximately 7 micromol x kg(-1) x min(-1) for maximal PKC activation by PGF2alpha and U46619. 45Ca2+ influx > 10 micromol x kg(-1) x min(-1) was associated with further increases in contraction despite a significant decrease in PKC activity. Western blotting analysis revealed alpha-, delta-, epsilon-, and zeta-PKC in porcine coronary artery. In unstimulated tissues, alpha- and epsilon-PKC were mostly distributed in the cytosolic fraction. Significant eicosanoid-induced translocation of epsilon-PKC from the cytosolic to the particulate fraction was observed at 0 [Ca2+]e, while translocation of alpha-PKC was observed at 600 microM [Ca2+]e. Thus, a significant component of eicosanoid-induced coronary contraction is associated with significant PKC activity in the absence of significant increase in Ca2+ entry and may involve activation and translocation of the Ca2+-independent epsilon-PKC. An additional Ca2+-dependent component of eicosanoid-induced coronary contraction is associated with a peak PKC activity at submaximal Ca2+ entry and may involve activation and translocation of the Ca2+-dependent alpha-PKC. The results also suggest that a smaller PKC activity at supramaximal Ca2+ entry may be sufficient during eicosanoid-induced contraction of coronary smooth muscle.

Glucocorticoid inhibition of Na-Pi cotransport in renal epithelial cells is mediated by protein kinase C.

The effect and mechanism of action of glucocorticoids (GC) on Na-Pi cotransport were evaluated in opossum kidney cells. Dexamethasone (1-1000 nM) inhibited sodium-dependent Pi uptake in a time- and concentration-dependent manner. Inhibition was maximal after a 6-h incubation with dexamethasone and was prevented by cycloheximide and actinomycin D. The effect was related to a 37% decrease of the Vmax value after incubation with 100 nM dexamethasone. The effect of dexamethasone was mimicked by cortisol and blocked by GC receptor antagonists RU38486 and progesterone. GC affected neither glucose or alanine uptake nor Na/H exchange activity. Inhibition of Pi uptake persisted when Na/H was blocked by amiloride or dimethylamiloride. GC had no effect on basal or parathyroid hormone- and forskolin-stimulated intracellular cAMP content. Dexamethasone and extracellular cAMP, parathyroid hormone, or 3-isobutyl-1-methylxanthine had additive inhibitory effects on Pi uptake. Staurosporine, GF109203X, or calphostin C (three dissimilar inhibitors of protein kinase C (PKC)) and PKC down-regulation blunted the inhibitory effect of glucocorticoids on Pi uptake. GC increased both membrane-bound PKC activity and the membrane/cytosol PKC activity ratio. This is the first report of GC activation of PKC in renal cells, which appears to mediate the steroid inhibitory effect on Pi transport.