Expression of protein kinase C isoenzymes in thymocyte subpopulations and their differential regulation

The expression of the different protein kinase C (PKC) isozymes in mouse thymocytes was studied to determine if there is a correlation between isozyme expression and thymocyte phenotype. Expression of PKC isozymes in thymocyte subsets (distinguished by the CD4 or CD8 Ag) was determined by message amplification phenotyping. The expression of mRNA for PKC-alpha, -beta, -epsilon, and -zeta, but not -gamma or -delta isozymes, was detected in all of the unstimulated thymocyte subpopulations analyzed. Thus no differences in the pattern of PKC isozyme expression were found that could be correlated with thymocyte phenotype. However, it was noted that the levels of PKC mRNA expression were affected by different stimuli in unfractionated thymocytes. Whereas mRNA levels of PKC-alpha and -beta were down-regulated by PMA and ionomycin treatment, no significant changes were seen in the levels of PKC-epsilon mRNA with these agents. PKC-epsilon mRNA decreased in thymocytes exposed to Con A similar to what has been reported for PKC-epsilon protein. PKC-zeta mRNA was also down-regulated by PMA or ionomycin, and the combination of both compounds caused a more rapid and drastic effect. Finally, PKC-delta mRNA expression was induced transiently in thymocytes only after exposure to PMA or Con A, and this induction was inhibited by ionomycin treatment. These results indicate that message levels of specific isoforms of PKC are uniquely regulated and suggest an additional level of control of PKC activity in activated lymphocytes.     

Increased expression of protein kinase C isoforms in heart failure due to myocardial infarction

The activities of cardiac protein kinase C (PKC) were examined in hemodynamically assessed rats subsequent to myocardial infarction (MI). Both Ca(2+)-dependent and Ca(2+)-independent PKC activities increased significantly in left ventricular (LV) and right ventricular (RV) homogenates at 1, 2, 4, and 8 wk after MI was induced. PKC activities were also increased in both LV and RV cytosolic and particulate fractions from 8-wk infarcted rats. The relative protein contents of PKC-alpha, -beta, -epsilon, and -zeta isozymes were significantly increased in LV homogenate, cytosolic (except PKC-alpha), and particulate fractions from the failing rats. On the other hand, the protein contents of PKC-alpha, -beta, and -epsilon isozymes, unlike the PKC-zeta isozyme, were increased in RV homogenate and cytosolic fractions, whereas the RV particulate fraction showed an increase in the PKC-alpha isozyme only. These changes in the LV and RV PKC activities and protein contents in the 8-wk infarcted animals were partially corrected by treatment with the angiotensin-converting enzyme inhibitor imidapril. No changes in protein kinase A activity and its protein content were seen in the 8-wk infarcted hearts. The results suggest that the increased PKC activity in cardiac dysfunction due to MI may be associated with an increase in the expression of PKC-alpha, -beta, and -epsilon isozymes, and the improvement of heart function in the infarcted animals by imidapril may be due to partial prevention of changes in PKC activity and isozyme contents.     

A new member of the protein kinase C family, nPKC theta, predominantly expressed in skeletal muscle.

A new protein kinase C (PKC)-related cDNA with unique tissue distribution has been isolated and characterized. This cDNA encodes a protein, nPKC theta, which consists of 707 amino acid residues and showed the highest sequence similarity to nPKC delta (67.0% in total). nPKC theta has a zinc-finger-like cysteine-rich sequence (C1 region) and a protein kinase domain sequence (C3 region), both of which are common in all PKC family members. However, nPKC theta lacks a putative Ca2+ binding region (C2 region) that is seen only in the conventional PKC subfamily (cPKC alpha, -beta I, -beta II, and -gamma) but not in the novel PKC subfamily (nPKC delta, -epsilon, -zeta, and -eta). Northern (RNA) blot analyses revealed that the mRNA for nPKC theta is expressed predominantly in skeletal muscle. Furthermore, nPKC theta mRNA is the most abundantly expressed PKC isoform in skeletal muscle among the nine PKC family members. nPKC theta expressed in COS1 cells serves as a phorbol ester receptor. By the use of an antipeptide antibody specific to the D2-D3 region of the nPKC theta sequence, nPKC theta was recognized as a 79-kDa protein upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis in mouse skeletal muscle extract and also in an extract from COS1 cells transfected with an nPKC theta cDNA expression plasmid. Autophosphorylation of immunoprecipitated nPKC theta was observed; it was enhanced by phosphatidylserine and 12-O-tetradecanoylphorbol-13-acetate but attenuated by the addition of Ca2+. These results clearly demonstrate that nPKC theta should be considered a member of the PKC family of proteins that play crucial roles in the signal transduction pathway.     

Multiple roles of phosphoinositide-specific phospholipase C isozymes

Phosphoinositide-specific phospholipase C is an effector molecule in the signal transduction process. It generates two second messengers, inositol-1,4,5-trisphosphate and diacylglycerol from phosphatidylinositol 4,5-bisphosphate. Currently, thirteen mammal PLC isozymes have been identified, and they are divided into six groups: PLC-beta, -gamma, -delta, -epsilon, -zeta and -eta. Sequence analysis studies demonstrated that each isozyme has more than one alternative splicing variant. PLC isozymes contain the X and Y domains that are responsible for catalytic activity. Several other domains including the PH domain, the C2 domain and EF hand motifs are involved in various biological functions of PLC isozymes as signaling proteins. The distribution of PLC isozymes is tissue and organ specific. Recent studies on isolated cells and knockout mice depleted of PLC isozymes have revealed their distinct phenotypes. Given the specificity in distribution and cellular localization, it is clear that each PLC isozyme bears a unique function in the modulation of physiological responses. In this review, we discuss the structural organization, enzymatic properties and molecular diversity of PLC splicing variants and study functional and physiological roles of each isozyme.     

Increased membrane affinity of the C1 domain of protein kinase Cdelta compensates for the lack of involvement of its C2 domain in membrane recruitment

Protein kinase C (PKC) family members are allosterically activated following membrane recruitment by specific membrane-targeting modules. Conventional PKC isozymes are recruited to membranes by two such modules: a C1 domain, which binds diacylglycerol (DAG), and a C2 domain, which is a Ca2+-triggered phospholipid-binding module. In contrast, novel PKC isozymes respond only to DAG, despite the presence of a C2 domain. Here, we address the molecular mechanism of membrane recruitment of the novel isozyme PKCdelta. We show that PKCdelta and a conventional isozyme, PKCbetaII, bind membranes with comparable affinities. However, dissection of the contribution of individual domains to this binding revealed that, although the C2 domain is a major determinant in driving the interaction of PKCbetaII with membranes, the C2 domain of PKCdelta does not bind membranes. Instead, the C1B domain is the determinant that drives the interaction of PKCdelta with membranes. The C2 domain also does not play any detectable role in the activity or subcellular location of PKCdelta in cells; in vivo imaging studies revealed that deletion of the C2 domain does not affect the stimulus-dependent translocation or activity of PKCdelta. Thus, the increased affinity of the C1 domain of PKCdelta allows this isozyme to respond to DAG alone, whereas conventional PKC isozymes require the coordinated action of Ca2+ binding to the C2 domain and DAG binding to the C1 domain for activation.     

The use of fluorescent phorbol esters in studies of protein kinase C-membrane interactions

The family of protein kinase C (PKC) isozymes belongs to a growing class of proteins that become active by associating with membranes containing anionic phospholipids, such as phosphatidylserine. Depending on the particular PKC isoform, this process is mediated by Ca(2+)-binding to a C2 domain and interaction of activators such as 1,2-diacyl-sn-glycerol or phorbol esters with tandem C1 domains. This cooperation between the C1 and C2 domains in inducing the association of PKC with lipid membranes provides the energy for a conformational change that consists of the release of a pseudosubstrate sequence from the active site, culminating in activation. Thus, the properties of the interactions of the C1 and C2 domains with membranes, both as isolated domains, and as modules in the full length PKC isoforms, have been the subject of intense scrutiny. Here, we review the findings of studies in which fluorescent phorbol esters have been utilized to probe the properties of the C1 domains of PKC with respect to the interaction with activators, the subsequent interaction with membranes, and the role of the activating conformational change that leads to activation.     

Diacylglycerol kinase in the central nervous system--molecular heterogeneity and gene expression.

Diacylglycerol (DAG) is one of the important second messengers, which serves as an activator of protein kinase C (PKC). DAG kinase (DGK) phosphorylates DAG to generate phosphatidic acid, thus DGK is considered to be a regulator of PKC activity through attenuation of DAG. Recent studies have revealed molecular structures of several DGK isozymes from mammalian species, and showed that most of the isozymes are expressed in the brain in various amounts. We have cloned four DGK isozyme cDNAs from rat brain library (DGK alpha, -beta, -gamma, and -zeta) (previously also designated DGK-I, -II, -III, and -IV, respectively) and examined their mRNA expressions in rat brain by in situ hybridization histochemistry. Interestingly, it is revealed that the mRNA for each isozyme is expressed in a distinct pattern in the brain; DGK alpha is expressed in oligodendrocytes, glial cells that form myelin; DGK beta in neurons of the caudate-putamen; DGK gamma predominantly in the cerebellar Purkinje cells; and DGK zeta in the cerebellar and cerebral cortices. Molecular diversity and distinct expression patterns of DGK isozymes suggest a physiological importance for the enzyme in brain function. Furthermore, functional implications of these DGK isozymes are briefly discussed.     

Protein kinase C isozyme expression in phorbol ester-sensitive and -resistant EL4 thymoma cells

To investigate whether differential protein kinase C isozyme expression in phorbol ester-sensitive and -resistant EL4 thymoma cells could account for the difference in phorbol ester responsiveness, we purified and characterized isozymes from the two cell lines. In both cell types, two peaks of protein kinase C activity were resolved on hydroxylapatite following DEAE-cellulose and phenyl-Superose chromatography. Western blot analysis showed that the first peak corresponded to protein kinase C-beta and the second to protein kinase C-alpha. Two-dimensional phosphotryptic mapping of the purified alpha and beta isozymes did not reveal any reproducible differences between sensitive and resistant EL4 cells. Nor were any differences between the cell types observed in the cytosolic versus membrane localization of alpha and beta protein kinase C. Northern blot analysis showed the expression of mRNA for protein kinase C-alpha, -beta, -delta and -epsilon in both cell lines, and the absence of mRNA for gamma or zeta. Although no major differences in expression of alpha, beta, or delta mRNA between sensitive and resistant EL4 cells were detectable, expression of protein kinase C-epsilon mRNA in resistant cells was only 20-25% of that in sensitive. Western blot analysis with anti-protein kinase C-epsilon antibodies showed the presence of the epsilon-isozyme in sensitive cells and the absence of detectable amounts in resistant cells. Although protein kinase C-epsilon constitutes only a small portion of the total protein kinase C in sensitive cells, the possibility is raised that decreased protein kinase C-epsilon expression may contribute to the failure of resistant EL4 cells to respond to phorbol esters.     

C1 domains exposed: from diacylglycerol binding to protein-protein interactions

C1 domains, cysteine-rich modules originally identified in protein kinase C (PKC) isozymes, are present in multiple signaling families, including PKDs, chimaerins, RasGRPs, diacylglycerol kinases (DGKs) and others. Typical C1 domains bind the lipid second messenger diacylglycerol (DAG) and DAG-mimetics such as phorbol esters, and are critical for governing association to membranes. On the contrary, atypical C1 domains possess structural determinants that impede phorbol ester/DAG binding. C1 domains are generally expressed as twin modules (C1A and C1B) or single domains. Biochemical and cellular studies in PKC and PKD isozymes revealed that C1A and C1B domains are non-equivalent as lipid-binding motifs or translocation modules. It has been recently determined that individual C1 domains have unique patterns of ligand recognition, driven in some cases by subtle structural differences. Insights from recent 3-D studies on beta2-chimaerin and Munc13-1 revealed that their single C1 domains are sterically blocked by intramolecular interactions, suggesting that major conformational changes would be required for exposing the site of DAG interaction. Thus, it is clear that the protein context plays a major role in determining whether binding of DAG to the C1 domain would lead to enzyme activation or merely serves as an anchoring mechanism.     

Differential recovery of protein kinase C-alpha and -epsilon isozymes after long-term phorbol ester treatment in rat renal mesangial cells

Glomerular mesangial cells have been shown to express two protein kinase C (PKC) isozymes, PKC-alpha and PKC-epsilon. Upon long-term treatment with phorbol ester PKC-alpha is depleted faster than PKC-epsilon. Here we demonstrate that removal of phorbol ester results in a differential recovery of PKC-alpha and -epsilon isozymes. Whereas PKC-epsilon starts to recover within 1h, PKC-alpha does not begin to recover before 4 h after removal of phorbol ester. These data suggest a differential rate of protein synthesis of PKC-alpha and -epsilon. In parallel to the recovery of PKC isozymes mesangial cells also regained their functional responsiveness, i.e., stimulation of prostaglandin synthesis and feedback inhibition of angiotensin II-stimulated InsP3 formation.     

Protein kinase C {delta}-specific activity reporter reveals agonist-evoked nuclear activity controlled by Src family of kinases

Conventional and novel protein kinase C (PKC) isozymes transduce the abundance of signals mediated by phospholipid hydrolysis; however redundancy in regulatory mechanisms confounds dissecting the unique signaling properties of each of the eight isozymes constituting these two subgroups. Previously, we created a genetically encoded reporter (C kinase activity reporter (CKAR)) to visualize the rate, amplitude, and duration of agonist-evoked PKC signaling at specific locations within the cell. Here we designed a reporter, δCKAR, that specifically measures the activation signature of one PKC isozyme, PKC δ, in cells, revealing unique spatial and regulatory properties of this isozyme. Specifically, we show two mechanisms of activation: 1) agonist-stimulated activation at the plasma membrane (the site of most robust PKC δ signaling), Golgi, and mitochondria that is independent of Src and can be triggered by phorbol esters and 2) agonist-stimulated activation in the nucleus that requires Src kinase activation and cannot be triggered by phorbol esters. Translocation studies reveal that the G-protein-coupled receptor agonist UTP induces the translocation of PKC δ into the nucleus by a mechanism that depends on the C2 domain and requires Src kinase activity. However, translocation from the cytosol into the nucleus is not required for the Src-dependent regulation of nuclear activity; a construct of PKC δ prelocalized to the nucleus continues to be activated by UTP by a mechanism dependent on Src kinase activity. These data identify the nucleus as a signaling hub for PKC δ that is driven by receptor-mediated signaling pathways (but not phorbol esters) and differs from signaling at plasma membrane and Golgi in that it is controlled by Src family kinases.     

Characterization of the interaction of phorbol esters with the C1 domain of MRCK (myotonic dystrophy kinase-related Cdc42 binding kinase) alpha/beta

C1 domains mediate the recognition and subsequent signaling response to diacylglycerol and phorbol esters by protein kinase C (PKC) and by several other families of signal-transducing proteins such as the chimerins or RasGRP. MRCK (myotonic dystrophy kinase-related Cdc42 binding kinase), a member of the dystrophia myotonica protein kinase family that functions downstream of Cdc42, contains a C1 domain with substantial homology to that of the diacylglycerol/phorbol ester-responsive C1 domains and has been reported to bind phorbol ester. We have characterized here the interaction of the C1 domains of the two MRCK isoforms alpha and beta with phorbol ester. The MRCK C1 domains bind [20-(3)H]phorbol 12,13-dibutyrate with K(d) values of 10 and 17 nm, respectively, reflecting 60-90-fold weaker affinity compared with the protein kinase C delta C1b domain. In contrast to binding by the C1b domain of PKCdelta, the binding by the C1 domains of MRCK alpha and beta was fully dependent on the presence of phosphatidylserine. Comparison of ligand binding selectivity showed resemblance to that by the C1b domain of PKCalpha and marked contrast to that of the C1b domain of PKCdelta. In intact cells, as in the binding assays, the MRCK C1 domains required 50-100-fold higher concentrations of phorbol ester for induction of membrane translocation. We conclude that additional structural elements within the MRCK structure are necessary if the C1 domains of MRCK are to respond to phorbol ester at concentrations comparable with those that modulate PKC.     

Uncoupling of ATP-induced inositol phosphate formation and Ca(2+) mobilization by phorbol ester in canine cultured tracheal epithelial cells

The regulation of the increase in inositol phosphates (IPs) production and intracellular Ca(2+) concentration ([Ca(2+)](i)) by protein kinase C (PKC) was investigated in canine cultured tracheal epithelial cells (TECs). Pretreatment of TECs with phorbol 12-myristate 13-acetate (PMA, 1 microM) for 30 min attenuated the ATP- and UTP-induced IPs formation and Ca(2+) mobilization. The concentrations of PMA that gave half-maximal (EC(50)) inhibition of ATP- and UTP-induced IPs accumulation and an increase in [Ca(2+)](i) were 5-10 and 4-12 nM, respectively. Prior treatment of TECs with staurosporine (1 microM), a PKC inhibitor, partially inhibited the ability of PMA to attenuate ATP- and UTP-induced responses, suggesting that the inhibitory effect of PMA is mediated through the activation of PKC. Furthermore, analysis of cell extracts by Western blotting with antibodies against different PKC isozymes revealed that TECs expressed PKC-alpha, -betaI, -betaII, -gamma, -delta, -epsilon, -theta, and -zeta. With PMA treatment of the cells for various times, translocation of PKC-alpha, -betaI, -betaII, -gamma, -delta, -epsilon, and -theta from the cytosol to the membrane was seen after 5- and 30-min and 2- and 4-h treatment. However, 6-h treatment caused a partial down-regulation of these PKC isozymes. PKC-zeta was not significantly translocated and down-regulated at any of the times tested. In conclusion, these results suggest that activation of PKC may inhibit the phosphoinositide (PI) hydrolysis and consequently attenuate the [Ca(2+)](i) increase or inhibit independently both responses to ATP and UTP. The translocation of PKC-alpha, -betaI, -betaII, -delta, -epsilon, -gamma, and -theta induced by PMA caused an attenuation of ATP- and UTP-induced IPs accumulation and Ca(2+) mobilization in TECs.     

Translocation and Down-Regulation of Protein Kinase C-α, -β, and -γ Isoforms During Ischemia-Reperfusion in Rat Brain

We investigated the distribution of protein kinase C (PKC) isoforms in the subcellular fractions (P1, 1,000-g pellet; P2, 10,000-g pellet; P3, 100,000-g pellet; S, 100,000-g supernatant) of rat forebrain after ischemia or reperfusion by immunoblotting. PKC-delta and -epsilon isoforms were predominant in the P2 (synaptosome-rich) fraction, whereas PKC-alpha, -beta, -gamma, -epsilon, and -zeta isoforms were rich in the S (cytosolic) fraction. With time of ischemia (5-30 min), PKC-alpha, -beta, and -gamma translocated to the P2 and P3 fractions, whereas reperfusion for 60 min after 30 min of ischemia reduced PKC-beta activity greatly and PKC-alpha and -gamma activities to a lesser extent. There was no redistribution of PKC-delta, -epsilon, and -zeta after ischemia or reperfusion. A calpain inhibitor, acetylleucylleucylnorleucinal, inhibited the down-regulation of PKC-beta, through intravenous injection. The PKC translocation to the P2 fraction was accompanied by their dephosphorylation, transition of PKC-alpha from dimer to trimer, and the decrease in activity. These data show that PKC-alpha, -beta, and -gamma isoforms translocate chiefly to the synaptosome in ischemic brain in association with the dephosphorylation, multimeric change, and inactivation, followed by the proteolysis of PKC-beta by calpain after postischemic reperfusion.     

A protein kinase C cDNA without the regulatory domain is active after transfection in vivo in the absence of phorbol ester.

We constructed mutant protein kinase C (PKC) cDNAs which expressed PKC activity in vivo in the absence of phorbol ester activation. A hybrid PKC gene, PKAC, was constructed by substituting the coding region for the N-terminal 253 amino acids of PKC alpha with the N-terminal 17 amino acids of the cyclic AMP-dependent protein kinase catalytic subunit (PKA). A truncated PKC gene, delta PKC beta, lacking the coding region for amino acid positions 6 to 159 of PKC beta was also constructed. These mutant kinase genes expressed under the control of the SR alpha promoter activated the c-fos gene enhancer in Jurkat cells and initiated maturation of Xenopus laevis oocytes. Phorbol ester binding activity was absent in both constructs but was preserved in another hybrid gene, PKCA, which was composed of the coding region for 1 to 253 amino acids of PKC alpha at the N-terminal side and the coding region for 18 to 350 amino acids of PKA at the C-terminal side. These results indicate that elimination of the regulatory domain of PKC produces constitutively active PKC that can bypass activation by the phorbol ester. delta PKC beta, in synergy with a calcium ionophore, was capable of activating the interleukin 2 promoter, indicating that cooperation of PKC-dependent and calcium-dependent pathways is necessary for activation of the interleukin 2 gene.     

Identification and functional characterization of protein kinase C isozymes in platelets and HEL cells.

To determine if selective activation of individual isozymes of protein kinase C (PKC) might explain the apparently divergent effects of PKC stimulation on platelets, we purified and characterized the isozymes from both platelets and human erythroleukemia (HEL) cells, a cell line that has many features of megakaryocytes. Two peaks of platelet PKC activity were resolved by hydroxylapatite chromatography; immunoblot analysis revealed that these two peaks represented the alpha and beta isozymes of PKC. In contrast, HEL cells produced only a single peak that contained the beta isozyme. None of the other PKC isozymes were detected in these fractions. The cytosol of platelets and HEL cells, however, were both found to contain the PKC-delta isozyme. Northern hybridization analyses and mRNA amplification by the polymerase chain reaction demonstrated the presence of mRNA encoding the alpha, beta, and delta PKC isozymes in platelets, but only the beta and delta isozymes in HEL cells. Phorbol myristate acetate (PMA), thrombin, or an endoperoxide analog induced the phosphorylation of the 47-kDa substrate of PKC (pleckstrin) found in platelets and HEL cells; preincubation of either HEL cells or platelets with PMA reduced the intracellular Ca2+ rise induced by thrombin. Thus, although both HEL cells and platelets contain PKC-beta and the recently described PKC-delta isozymes, the widely distributed alpha isozyme of PKC is absent in HEL cells; however, isozymes other than PKC-alpha are sufficient for some PMA-mediated functions that are similar to those seen in stimulated platelets.     

Interaction of protein kinase C isozymes with Rho GTPases

Evidence is provided for direct protein-protein interactions between protein kinase C (PKC) alpha, betaI, betaII, gamma, delta, epsilon, and zeta and members of the Rho family of small GTPases. Previous investigations, based on the immunoprecipitation approach, have provided evidence consistent with a direct interaction, but this remained to be proven. In the study presented here, an in vitro assay, consisting only of purified proteins and the requisite PKC activators and cofactors, was used to determine the effects of Rho GTPases on the activities of the different PKC isoforms. It was found that the activity of PKCalpha was potently enhanced by RhoA and Cdc42 and to a lesser extent by Rac1, whereas the effects on the activities of PKCbetaI, -betaII, -gamma, -delta, -epsilon, and -zeta were much reduced. These results indicate a direct interaction between PKCalpha and each of the Rho GTPases. However, the Rho GTPase concentration dependencies for the potentiating effects on PKCalpha activity differed for each Rho GTPase and were in the following order: RhoA > Cdc42 > Rac1. PKCalpha was activated in a phorbol ester- and Ca(2+)-dependent manner. This was reflected by a substantial decrease in the phorbol ester concentration requirements for activity in the presence of Ca(2+), which for each Rho GTPase was induced within a low nanomolar phorbol ester concentration range. The activity of PKCalpha also was found to be dependent on the nature of the GTP- or GDP-bound state of the Rho GTPases, suggesting that the interaction may be regulated by conformational changes in both PKCalpha and Rho GTPases. Such an interaction could result in significant cross-talk between the distinct pathways regulated by these two signaling elements.     

Poster Sessions CP09: Kinases and Phosphatases. Protein kinase C inhibitors counteract ethanol effects on myelin basic protein expression in CG‐4 oligodendrocytes

Abnormal myelin formation appears to be one defect contributing to the neuropathology associated with the fetal alcohol syndrome, the major cause of noncongenital mental retardation. Using the CG‐4 cell line we previously showed that 25–75 mm ethanol (EtOH) down‐regulates myelin basic protein (MBP) expression in differentiating oligodendrocytes (OLGs) without affecting the 2′,3′‐cyclic nucleotide 3′‐phosphodiesterase (CNP) expression or morphological development (Bichenkov and Ellingson 2001). Here we observed that a relatively low concentration of 12‐phorbol‐13‐myristate acetate (PMA) mimicked the EtOH‐caused inhibition of MBP expression without affecting CNP expression or morphology. The inhibition of MBP expression by 100 mm EtOH or 1 nm PMA was completely counteracted by three inhibitors of protein kinase C (PKC); bisinodoylmaleimide I, chelerythrine chloride, and calphostin C, indicating that EtOH down‐regulated MBP expression by activating PKC. We investigated whether the EtOH‐caused activation resulted in part from up‐regulation of the expression of PKC isozymes. Of 11 PKC isozymes examined, CG‐4 OLGs expressed nine; PKC α, β1, β2, δ, ε, λ, μ, nu and zeta; while PKC isozymes γ and theta were not detected. Only five PKC isozymes, α, β1, β2, μ, and nu, displayed developmental changes in expression. However, EtOH did not up‐regulate the early expression of any PKC isozyme during the first two days of differentiation, the developmental stage when it down‐regulates the MBP expression in CG‐4 cells. The results indicate that EtOH delays MBP expression by activating at least one phorbol ester‐sensitive PKC isozyme in differentiating oligodendrocytes without up‐regulating its expression. Acknowledgements: Support: NIAAA Grant AA072185.     

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.     

Role of protein kinase C alpha in calcium induced keratinocyte differentiation: defective regulation in squamous cell carcinoma

Calcium induces both involucrin and transglutaminase-K in normal keratinocytes (NHK) but not in squamous carcinoma cell lines (SCC). The protein kinase C (PKC) agonist phorbol myristoyl acetate potentiates and the PKC antagonist Ro31-8220 blocks the ability of calcium to stimulate the involucrin promoter in normal human keratinocytes but not in SCC4. We thus examined the ability of calcium to regulate the levels of five PKC isozymes in NHK and two SCC. In the normal keratinocytes, the levels of PKC [alpha], PKC [delta], PKC [eta], and PKC [zeta] increased over the first one to two weeks in a calcium-and time-dependent manner. PKC [epsilon] decreased in a time-and calcium-dependent fashion over the three-week period. All five isozymes showed little change during culture in SCC4 at any calcium concentration. Calcium and time of culture had partial effects on SCC12B2, a carcinoma that shows partial differentiation characteristics. Since PKC [alpha] is the only calcium responsive PKC isozyme in keratinocytes and most likely to be directly involved in calcium induced differentiation, we evaluated the effect of inhibiting its production with antisense oligonucleotides on calcium-regulated markers of differentiation. We found that the PKC [alpha] specific antisense oligonucleotide blocked calcium stimulated involucrin promoter activity as well as PKC [alpha], involucrin, and transglutaminase protein production, whereas the sense oligonucleotide control did not. We conclude that although a number of PKC isozymes are regulated during calcium-induced differentiation, PKC [alpha] plays a necessary role in mediating calcium-induced differentiation. Failure to regulate PKC [alpha] in SCC4 may underlie at least part of the failure of calcium to promote differentiation in these cells.