Different Modulation of Protein Kinase C Isozymes in Dibutyryl Cyclic AMP-Differentiated PC12h Cells

Abstract: PC12h cells can be differentiated into sympathetic neuron-like cells by various agents, including nerve growth factor, basic fibroblast growth factor, cyclic AMP analogues, and protein kinase C (PKC) activators. To study the involvement of PKC in the process of PC12h cell differentiation by cyclic AMP treatment, PKC isozymes (α, βI, βII, and γ) were analyzed using column chromatography and immunoblotting. Two PKC isozymes, PKC(α) and PKC(βII), were predominantly detected in PC12h cells. When stimulated by dibutyryl cyclic AMP, PKC(α) levels declined in the cytosolic fraction of the cells, whereas PKC(βII) levels increased. Increased PKC(βII) levels were also detected in the particulate fraction, whereas particulate PKC(α) levels did not change. The total PKC activity decreased in the cytosolic fraction following cyclic AMP stimulation of PC12h cells, whereas it stayed constant in the particulate fraction. Fractionation on a hydroxyapatite column showed a decreased level of PKC(α) activity and a transient increase followed by a decreased level of PKC(βII) activity. This discrepancy between increased PKC(βII) immunoreactivity and reduced PKC(βII) activity suggested the presence of nonactivatable PKC(βII) in cyclic AMP-treated PC12h extract. These findings indicate that PKC(α) and PKC(βII) are differentially regulated during the differentiation of PC12h cells. In addition, the differentiation of PC12h cells triggered by cyclic AMP seems to involve characteristic alterations of PKC isozymes.     

Activation of cPLA2, PKC, and ERKs in the Rat Cerebral Cortex During Ischemia/Reperfusion

Release of the excitotoxic amino acid, glutamate, into the extracellular space during ischemia/reperfusion contributes to neuronal injury and death. To gain insights into the signal transduction pathways involved in glutamate release we examined the time course of changes in enzyme levels and activities of cPLA₂, PKC and ERKs in the rat cerebral cortex after four vessel (4VO) ischemia followed by reperfusion. Measurement both by enzymatic assay and Western blot analysis showed significant increases in the activity and protein levels of cPLA₂ during 10–20 min of ischemia. Activity remained elevated at 10 min and 20 min of reperfusion, whereas cPLA levels had returned to base line levels after 20 min of reperfusion. PKC activity increased significantly in the particulate, but not in the cytosolic, fractions both during ischemia and reperfusion. Increases in PKC levels were recorded in the particulate fraction during ischemia and reperfusion, and in the cytosolic fraction during ischemia. Western blot analysis with a phosphospecific antibody for characterization of MAPK (ERKs) activation revealed significantly increased phosphorylation of ERK₁, and ERK₂ in the particulate fraction, of ERK₂ in the cytosolic fraction, during ischemia and of both enzymes in the particulate and cytosolic fractions after 10 min of reperfusion. The relevance of the results to glutamate release is discussed.     

Changes in the Activity of Protein Kinase C and the Differential Subcellular Redistribution of Its Isozymes in the Rat Striatum During and Following Transient Forebrain Ischemia

The changes in the levels of protein kinase C [PKC(alpha, beta II, gamma)] were studied in cytosolic and particulate fractions of striatal homogenates from rats subjected to 15 min of cerebral ischemia induced by bilateral occlusion of the common carotid arteries and following 1 h, 6 h, and 48 h of reperfusion. During ischemia the levels of PKC(beta II) and -(gamma) increased in the particulate fraction to 390% and 590% of control levels, respectively, concomitant with a decrease in the cytosolic fraction to 36% and 20% of control, respectively, suggesting that PKC is redistributed from the cytosol to cell membranes. During reperfusion the PKC(beta II) levels in the particulate fraction remained elevated at 1 h postischemia and decreased to below control levels after 48 h reperfusion, whereas PKC(gamma) rapidly decreased to subnormal levels. In the cytosol PKC(beta II) and -(gamma) decreased to 25% and 15% of control levels at 48 h, respectively. The distribution of PKC(alpha) did not change significantly during ischemia and early reperfusion. The PKC activity in the particulate fraction measured in vitro by histone IIIS phosphorylation in the presence of calcium, 4 beta-phorbol 13-myristate 12-acetate, and phosphatidylserine (PS) significantly decreased by 52% during ischemia, and remained depressed over the 48-h reperfusion period. In the cytosolic fraction PKC activity was unchanged at the end of ischemia, and decreased by 47% after 6 h of reperfusion. The appearance of a stable cytosolic 50-kDa PKC-immunoreactive peptide or an increase in the calcium- and PS-independent histone IIIS phosphorylation was not observed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inactivation and Subcellular Redistribution of Ca2+/ Calmodulin-Dependent Protein Kinase II Following Spinal Cord Ischemia

Abstract: Reversible spinal cord ischemia in rabbits induced a rapid loss of Ca²⁺/calmodulin-dependent protein kinase II (CaM kinase II) activity measured as incorporation of phosphate into exogenous substrates. About 70% of the activity was lost from the cytosolic fraction of spinal cord homogenates after 15 min of ischemia preceding irreversible paraplegia, which takes 25 min in this model. The loss of enzyme activity correlated with a loss of in situ renaturable autophosphorylation activity and a loss of CaM kinase II α and β subunits in the cytosol detected by immunoblotting. CaM kinase II activity in the particulate fraction also decreased but the protein levels of the a and β subunits increased. Thus ischemia resulted in an inactivation of CaM kinase II and a sequential or concurrent subcellular redistribution of the enzyme. However, denaturation and renaturation in situ of the CaM kinase subunits immobilized on membranes partly reversed the apparent inactivation of the enzyme in the particulate fraction. CaM kinase II activity was restored after reperfusion following short (≤25 min) durations of ischemia but not after longer durations (60 min) that result in irreversible paraplegia. The ischemia-induced inactivation of CaM kinase II, which phosphorylates proteins regulating many cellular processes, may be important in the cascade of events leading to delayed neuronal cell death.     

Hypothermia Prevents the Ischemia-Induced Translocation and Inhibition of Protein Kinase C in the Rat Striatum

The effect of hypothermia on the ischemia-induced changes in the subcellular distribution of protein kinase C (PKC) (gamma), -(beta II), and -(alpha) and the activity of PKC was studied in striatal homogenates of rats subjected to 20 min of cerebral ischemia. The effect of postischemic cooling was also studied. During normothermic ischemia, PKC(gamma) and -(beta II) increased 3.9- and 2.9-fold, respectively, in the particulate fraction, signifying a translocation of PKC to cell membranes. The levels of PKC(alpha) did not change significantly. PKC activity decreased during ischemia by 52% and 47% (p less than 0.05) in the particulate and cytosolic fractions, respectively, and remained inhibited for the 1 h recovery period. In hypothermic animals, there was no evidence of translocation, and the inhibition of PKC activity was completely abolished. Hypothermia induced in the recovery phase, however, did not affect PKC distribution or activity. The protective effect of intraischemic hypothermia may in part be due to the prevention of the ischemia-induced translocation and subsequent downregulation of PKC, possibly through a temperature-dependent modification of the cell membranes.     

Regional Alterations of Protein Kinase C Activity Following Transient Cerebral Ischemia: Effects of Intraischemic Brain Temperature Modulation

Abstract: It is well established that ischemia-induced release of glutamate and the subsequent activation of postsynaptic glutamate receptors are important processes involved in the development of ischemic neuronal damage. Moderate intraischemic hypothermia attenuates glutamate release and confers protection from ischemic damage, whereas mild intraischemic hyperthermia increases glutamate release and augments ischemic pathology. As protein kinase C (PKC) is implicated in neurotransmitter release and glutamate receptor-mediated events, we evaluated the relationship between intraischemic brain temperature and PKC activity in brain regions known to be vulnerable or nonvulnerable to transient global ischemia. Twenty minutes of bilateral carotid artery occlusion plus hypotension were induced in rats in which intraischemic brain temperature was maintained at 30°C, 37°C, or 39°C. Prior to and following ischemia, brain temperature was 37°C in all groups. Cytosolic, membrane-bound, and total PKC activities were determined in hippocampal, striatal, cortical, and thalamic homogenates at the end of ischemia and at 0.25–24 h of recirculation. PKC activity of control rats varied by region and were affected by altered brain temperature. For both membrane-bound and cytosolic PKC, there was a significant temperature effect, and for membrane-bound PKC there was also a significant effect of region. Rats with normothermic ischemia (37°C) showed extensive depressions of all PKC fractions. Hippocampus and striatum were noteworthy for depressions in PKC activity extending from the earliest (15 min) to the latest (24 h) recirculation times studied, whereas cortex showed PKC depressions chiefly during the first hour of recirculation, and the thalamic pattern was inconsistent. In contrast, in rats with hypothermic ischemia (30°C), significant overall effects were noted only for total PKC in thalamus, which showed depressed levels at both 1 and 24 h of recirculation. Rats with hyperthermic (39°C) ischemia also showed significant overall effects for the time course of membrane-bound, cytosolic, and total PKC activities in the hippocampus, striatum, and cortex. However, no significant reductions in PKC indices were observed in the thalamus. For membrane-bound PKC, significant temperature effects were noted for hippocampus, striatum, and cortex, but not for thalamus. For cytosolic, as well as total PKC, activity, significant temperature effects were noted for all four brain regions. Our results indicate that ischemia, followed by reperfusion, induces a significant reduction in PKC activity and that this process is highly influenced by the brain temperature during ischemia. Furthermore, our data also establish that differences exist in the response of PKC to ischemia/recirculation in vulnerable versus non-vulnerable brain regions. These results suggest that PKC alterations may be an important factor involved in the modulatory effects of temperature on the outcome following transient global ischemia.     

Dopamine Receptor Stimulation Decreases Cytosolic γ Protein Kinase C Immunoreactivity in Rat Hippocampal Slices: Evidence for Increased Ca2+-Dependent Proteolysis

Abstract: The effect of dopamine (DA) receptor stimulation on the distribution of γ protein kinase C (γPKC) in hippocampal slices was assessed. Nanomolar concentrations of DA decreased cytosolic γPKC (56%) without altering membrane γPKC levels, resulting in decreased total γPKC immunoreactivity. The maximal decrease in cytosolic γPKC occurred at 20 min of incubation and was significantly blocked by the D₁ DA antagonist SCH 23390 (10⁻⁶ M ) but not by the D₂ antagonist sulpiride (10⁻⁵ M ). The D₁ agonists SKF 38393 and A 77636 mimicked the effect of DA with similar responses produced at 10 µ M and 1 n M , respectively. The D₂ agonist quinpirole had no effect on γPKC immunoreactivity, thus indicating that this dopaminergic response is mediated through a D₁-like receptor. DA had no effect on α, δ, or ζPKC isozyme immunoreactivity in the same hippocampal preparations. The DA-induced decrease in cytosolic γPKC immunoreactivity was blocked by the Ca²⁺-dependent protease inhibitor N -acetyl-Leu-Leu-norleucinal (100 µ M ) and by the inorganic Ca²⁺ channel blocker Co²⁺. The data suggest that DA stimulates a D₁-like DA receptor, which increases the influx of Ca²⁺ and activates the Ca²⁺-dependent proteolysis of γPKC.     

Intermittent hypoxia protects the rat heart against ischemia/reperfusion injury by activating protein kinase C

The aim of this study was to investigate whether and how protein kinase C (PKC) was involved in the protection afforded by intermittent hypoxia (IH) and the subcellular distribution of different PKC isozymes in rat left ventricle. Post-ischemic recovery of left ventricular developed pressure and +/-dP/dtmax in IH hearts were higher than those of normoxic hearts. Chelerythrine (CHE, 5 microM), a PKC antagonist, significantly inhibited the protective effects of IH, but had no influence on normoxic hearts. CHE significantly reduced the effect of IH on the time to maximal contracture (Tmc), but had no significant effect on the amplitude of maximal contracture (Amc) in IH group. In isolated normoxic cardiomyocytes, [Ca(2+)](i), measured as arbitrary units of fluorescence ratio (340 nm/380 nm) of fura-2, gradually increased during 20 min simulated ischemia and kept at high level during 30 min reperfusion. However, [Ca(2+)](i) kept at normal level during simulated ischemia and reperfusion in isolated IH cardiomyocytes. In normoxic myocytes, [Na(+)](i), indicated as actual concentration undergone calibration, gradually increased during 20 min simulated ischemia and quickly declined to almost the same level as that of pre-ischemia during 30 min simulated reperfusion. However, in IH myocytes, [Na(+)](i) increased to a level lower than the corresponding of normoxic myocytes during simulated ischemia and gradually reduced to the similar level as that of normoxic myocytes after simulated reperfusion. 5 microM CHE greatly increased the levels of [Ca(2+)](i) and [Na(+)](i) during ischemia and reperfusion in normoxic and IH myocytes. In addition, we demonstrated that IH up-regulated the baseline protein expression of particulate fraction of PKC-alpha, epsilon, delta isozymes. There is no significant difference of protein expression of PKC-alpha, epsilon, delta isozymes in cytosolic fraction between IH and normoxic group. The above results suggested that PKC contributed to the cardioprotection afforded by IH against ischemia/reperfusion (I/R) injury; the basal up-regulation of the particulate fraction of PKC-alpha, epsilon, delta isozymes in IH rat hearts and the contribution of PKC to the elimination of calcium and sodium overload might underlie the mechanisms of cardioprotection by IH.     

Decreased Protein Kinase C Activity During Cerebral Ischemia and After Reperfusion in the Adult Rat

The possible activation of protein kinase C (PKC) during total cerebral ischemia was investigated in the rat. Translocation of PKC activity from the soluble to the particulate fraction was used as an index of PKC activation. There was a drop in the proportion of particulate PKC activity from 30% for controls to 20% by 30 min of ischemia (p less than 0.01). By 20 min of cardiac arrest, there was a 40% decline of the total cellular PKC activity (p less than 0.01). This was not accompanied by an increase in activator-independent activity, a finding indicating PKC was not being converted to protein kinase M. These data suggest that PKC was not activated during ischemia, but rather that ischemia causes a reduction in cellular PKC activity. Translocation of PKC activity to the particulate fraction was not observed in the cerebral cortex or hippocampus of reperfused brain for up to 6 h of recovery following 11-13 min of total cerebral ischemia. The level of total, soluble, and particulate PKC activity in the cerebral cortex was reduced (p less than 0.05), corresponding to the decrease observed by 15 min of ischemia without reflow. A similar decline in activity was also observed in the hippocampus. No increase in activator-independent activity was observed. These data suggest that PKC was inhibited during cerebral ischemia and that this reduced level of PKC activity was maintained throughout 6 h of recovery. We conclude that pathological activation of PKC was not responsible for the evolution of ischemic brain damage.     

Isoflurane Inhibits Protein Kinase Cγ and Calcium/Calmodulin Dependent Protein Kinase II-α Translocation to Synaptic Membranes in Ischemic Mice Brains

Volatile anesthetics isoflurane possibly improves the ischemic brain injury. However, its molecular actions are still unclear. In ischemia, protein kinase C (PKC)γ and calcium/calmodulin dependent protein kinase II (CaMKII)-α are persistently translocated from cytosol to cell membranes, and diminish these translocation suggested to be neuroprotective. We thus tested a hypothesis that isoflurane inhibits PKCγ and CaMKII-α translocation after ischemic brain insults. C57Bl/6J male mice were made to inhale 1 or 2 MAC isoflurane, after which 3 or 5 min cerebral ischemia was induced by decapitation. The sampled cerebrum cortex was then homogenized and centrifuged into crude synaptosomal fractions (P2), cytosolic fractions (S3), and particulate fractions (P3). CaMKII-α and PKCγ levels of these fractions were analyzed by immunoblotting. PKCγ and CaMKII-α are translocated to synaptic membrane from cytosol by cerebral ischemia, although isoflurane significantly inhibited such translocation. These results may explain in part the cellular and molecular mechanisms of neuroprotective effects of isoflurane.     

Translocation of PKC isoforms in bovine aortic smooth muscle cells exposed to strain

Our laboratory has previously reported that the exposure of smooth muscle cells (SMC) to the cyclic strain results in significant stimulation of protein kinase C (PKC) activity by translocating the enzyme from the cytosol to the particulate fraction. We now sought to examine the strain-induced translocation of individual PKC isoforms in SMC. Confluent bovine aortic SMC grown on collagen type I-coated plates were exposed to cyclic strain for up to 100 s at average 10% strain with 60 cycles/min. Immunoblotting analysis demonstrates that SMC express PKC-alpha, -beta and -zeta in both cytosolic and particulate fractions. Especially, PKC-alpha and -zeta were predominantly expressed in the cytosolic fraction. However, cyclic strain significantly (P < 0.05) increased PKC-alpha and -zeta in the particulate fraction and decreased in the cytosolic fraction. Thus, the cyclic strain-mediated stimulation of PKC activity in SMC may be due to the translocation of PKC-alpha and -zeta from the cytosolic to the particulate fraction. These results demonstrate that mechanical deformation causes rapid translocation of PKC isoforms, which may initiate a cascade of proliferation responses of SMC since NF-kappaB, which is involved in the cellular proliferation has been known to be activated by these PKC isoforms.     

Activity and subcellular distribution of protein kinase C (PKC) in muscle and brain of force-fed zinc-deficient rats

The purpose of the present study was to investigate, in force-fed rats, whether alimentary zinc (Zn) deficiency affects the activity of the Zn-metalloenzyme protein kinase C (PKC). The in vivo activity of PKC was determined by measuring the subcellular distribution of the enzyme between the cytosolic and the particulate fraction in brain and muscle. For this purpose, 24 male Sprague-Dawley rats with an average live mass of 126 g were divided into 2 groups of 12 animals each. The Zn-deficient and the control rats received a semisynthetic casein diet with a Zn content of 1.2 and 24.1 ppm, respectively. All animals were fed four times daily by gastric tube in order to ensure that the depleted animals also received adequate nutrients and to synchronize the feed intake exactly. After 12 d, the depleted rats were in a state of severe Zn deficiency, as demonstrated by a 70% lower serum Zn concentration and a 66% reduction in the serum activity of alkaline phosphatase. Neither the cytosolic nor the particulate fraction of the thigh muscle showed any difference between the depleted and the control animals as regards PKC activity/g of muscle. The specific activity of PKC/mg of protein in the cytosolic fraction of the muscle was not affected by alimentary zinc deficiency, whereas the specific activity of PKC in the particulate fraction of the muscle was reduced by a significant 10% in Zn deficiency (150±12 vs 135±14 pmol P/min/mg protein). In the brain, neither the cytosolic nor the particulate fraction revealed any difference in PKC activity/g of fresh weight or in the specific activity/mg of protein between the control and the Zn-deficient rats.     

Differential activation of protein kinase C isoforms following chemical ischemia in rat cerebral cortex slices

The aim of the current study was to characterize the effects of chemical ischemia and reperfusion at the transductional level in the brain. Protein kinase C isoforms (, β₁, β₂, γ, δ and ) total levels and their distribution in the particulate and cytosolic compartments were investigated in superfused rat cerebral cortex slices: (i) under control conditions; (ii) immediately after a 5-min treatment with 10 mM NaN₃, combined with 2 mM 2-deoxyglucose (chemical ischemia); (iii) 1 h after chemical ischemia (reperfusion). In control samples, all the PKC isoforms were detected; immediately after chemical ischemia, PKC β₁, δ and isoforms total levels (cytosol + particulate) were increased by 2.9, 2.7 and 9.9 times, respectively, while isoform was slightly reduced and γ isoform was no longer detectable. After reperfusion, the changes displayed by , β₁, γ, δ and were maintained and even potentiated, moreover, an increase in β₂ (by 41 ± 12%) total levels became significant. Chemical ischemia-induced a significant translocation to the particulate compartment of PKC isoform, which following reperfusion was found only in the cytosol. PKC β₁ and δ isoforms particulate levels were significantly higher both in ischemic and in reperfused samples than in the controls. Conversely, following reperfusion, PKC β₂ and isoforms displayed a reduction in their particulate to total level ratios. The intracellular calcium chelator, 1,2-bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid, 1 mM, but not the N-methyl-d-asparate receptor antagonist, MK-801, 1 μM, prevented the translocation of β₁ isoform observed during ischemia. Both drugs were effective in counteracting reperfusion-induced changes in β₂ and isoforms, suggesting the involvement of glutamate-induced calcium overload. These findings demonstrate that: (i) PKC isoforms participate differently in neurotoxicity/neuroprotection events; (ii) the changes observed following chemical ischemia are pharmacologically modulable; (iii) the protocol of in vitro chemical ischemia is suitable for drug screening.     

Protein and Molecular Characterization of Hippocampal Protein Kinase C in C57BL/6 and DBA/2 Mice

Abstract: Measures of protein kinase C (PKC) in C57BL/6 and DBA/2 mice using [³H]phorbol 12,13-dibutyrate binding to tissue homogenates and brain slices demonstrated that levels of activated, membrane-bound PKC were greater in C57BL hippocampus than in DBA hippocampus. Western analysis of α-, β_I-, β_II-, γ-, δ-, and ɛ-PKC using isozyme-specific antibodies indicated that the increase observed in C57BL hippocampus was due primarily to the γ-PKC protein, whose immunoreactivity was greater in the membrane-bound fraction in C57BL mice. Characterization of α-, β_I,II-, and γ-PKC hippocampal mRNA using northern analysis and isozyme-specific nucleic acid probes did not reveal differences between the strains in levels of gene expression. Restriction fragment length polymorphisms (RFLP) were found in the α- and γ-, but not β-PKC genomic DNA. The RFLPs appeared to be located in noncoding, nonregulatory regions of the gene. These findings suggest that the γ-PKC isozyme is largely responsible for the PKC activity difference in C57BL and DBA hippocampus that has been reported previously and may be closely associated with differences in learning ability observed in these strains.     

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.     

Activation of protein kinase C isozymes by contractile stimuli in arterial smooth muscle.

Protein kinase C (PKC) has been proposed to be involved in the regulation of vascular smooth muscle (VSM) contractile activity. However, little is known in detail about the activation of this kinase or specific isozymes of this kinase by contractile stimuli in VSM. As an index of PKC activation, Ca(2+)- and phospholipid-dependent histone IIIS kinase activity was measured in the particulate fraction from individual strips of isometrically contracting carotid arterial smooth muscle. Phorbol 12,13-dibutyrate (PDB) increased PKC activity in the particulate fraction (155% over resting value by 15 min) with a time course which paralleled or preceded force development. Stimulation with the agonist histamine (10(-5) M) resulted in rapid increases in both force and particulate fraction PKC activity which was maximal by 2 min (increase of 139%) and partially sustained over 45 min (increase of 41%). KCl (109 mM), which evokes a sustained contractile response, caused a slow increase (124% by 45 min) in particulate fraction PKC activity. No significant increases in activator-independent histone kinase activity were observed in response to any stimulus tested. PKC alpha and PKC beta were identified as the principal Ca2+/phospholipid-dependent PKC isozymes expressed in this tissue. In unstimulated arterial tissue, the ratio of immunodetectable isozyme content (alpha:beta) was estimated to be 1:1 in the particulate and 1.5:1 in the cytosolic fractions. Upon stimulation with each of the three contractile stimuli, particulate fraction PKC content assessed by immunoblotting increased with a time course and to an extent comparable to the observed changes in PKC activity. There was no evidence of differential regulation of the PKC alpha or -beta isozymes by PDB compared to the other contractile stimuli. These results indicate that diverse contractile stimuli are capable of tonically activating PKC in preparations of functional smooth muscle, and are consistent with a functional role for PKC alpha and/or -beta in the regulation of normal smooth muscle contractile activity.     

Differential activation of protein kinase C isoforms following chemical ischemia in rat cerebral cortex slices

The aim of the current study was to characterize the effects of chemical ischemia and reperfusion at the transductional level in the brain. Protein kinase C isoforms (α, β₁, β₂, γ, δ and ɛ) total levels and their distribution in the particulate and cytosolic compartments were investigated in superfused rat cerebral cortex slices: (i) under control conditions; (ii) immediately after a 5-min treatment with 10 mM NaN₃, combined with 2 mM 2-deoxyglucose (chemical ischemia); (iii) 1 h after chemical ischemia (reperfusion). In control samples, all the PKC isoforms were detected; immediately after chemical ischemia, PKC β₁, δ and ɛ isoforms total levels (cytosol + particulate) were increased by 2.9, 2.7 and 9.9 times, respectively, while α isoform was slightly reduced and γ isoform was no longer detectable. After reperfusion, the changes displayed by α, β₁, γ, δ and ɛ were maintained and even potentiated, moreover, an increase in β₂ (by 41 ± 12%) total levels became significant. Chemical ischemia-induced a significant translocation to the particulate compartment of PKC α isoform, which following reperfusion was found only in the cytosol. PKC β₁ and δ isoforms particulate levels were significantly higher both in ischemic and in reperfused samples than in the controls. Conversely, following reperfusion, PKC β₂ and ɛ isoforms displayed a reduction in their particulate to total level ratios. The intracellular calcium chelator, 1,2-bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid, 1 mM, but not the N-methyl-d-asparate receptor antagonist, MK-801, 1 μM, prevented the translocation of β₁ isoform observed during ischemia. Both drugs were effective in counteracting reperfusion-induced changes in β₂ and ɛ isoforms, suggesting the involvement of glutamate-induced calcium overload. These findings demonstrate that: (i) PKC isoforms participate differently in neurotoxicity/neuroprotection events; (ii) the changes observed following chemical ischemia are pharmacologically modulable; (iii) the protocol of in vitro chemical ischemia is suitable for drug screening.     

Preconditioning blocks cardiocyte apoptosis: role of K(ATP) channels and PKC-epsilon

The aims of this study were to determine whether preconditioning blocks cardiocyte apoptosis and to determine the role of mitochondrial ATP-sensitive K(+) (K(ATP)) channels and the protein kinase C epsilon-isoform (PKC-epsilon) in this effect. Ventricular myocytes from 10-day-old chick embryos were used. In the control series, 10 h of simulated ischemia followed by 12 h of reoxygenation resulted in 42 +/- 3% apoptosis (n = 8). These results were consistent with DNA laddering and TdT-mediated dUTP nick-end labeling (TUNEL) assay. Preconditioning, elicited with three cycles of 1 min of ischemia separated by 5 min of reoxygenation before subjection to prolonged simulated ischemia, markedly attenuated the apoptotic process (28 +/- 4%, n = 8). The selective mitochondrial K(ATP) channel opener diazoxide (400 micromol/l), given before ischemia, mimicked preconditioning effects to prevent apoptosis (22 +/- 4%, n = 6). Pretreatment with 5-hydroxydecanoate (100 micromol/l), a selective mitochondrial K(ATP) channel blocker, abolished preconditioning (42 +/- 2%, n = 6). In addition, the effects of preconditioning and diazoxide were blocked with the specific PKC inhibitors G?-6976 (0.1 micromol/l) or chelerythrine (4 micromol/l), given at simulated ischemia and reoxygenation. Furthermore, preconditioning and diazoxide selectively activated PKC-epsilon in the particulate fraction before simulated ischemia without effect on the total fraction, cytosolic fraction, and PKC delta-isoform. The specific PKC activator phorbol 12-myristate 13-acetate (0.2 micromol/l), added during simulated ischemia and reoxygenation, mimicked preconditioning to block apoptosis. Opening mitochondrial K(ATP) channels blocks cardiocyte apoptosis via activating PKC-epsilon in cultured ventricular myocytes. Through this signal transduction, preconditioning blocks apoptosis and preserves cardiac function in ischemia-reperfusion.     

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)