Expression of mammalian protein kinase C in Schizosaccharomyces pombe: isotype-specific induction of growth arrest, vesicle formation, and endocytosis.

Mammalian protein kinase C (PKC) isotypes elicit a number of effects on expression in Schizosaccharomyces pombe. A small decrease in growth rate results from PKC-gamma expression, and treatment of these cells with phorbol esters leads to marked growth inhibition and vesicle formation. PKC-delta and -eta expression causes growth inhibition and vesiculation, and the magnitude of both of these effects is increased by phorbol esters. In contrast, PKC-epsilon expression produces growth inhibition but no vesicle accumulation, and this effect is not responsive to phorbol ester. Finally, PKC-zeta has no observable effect. Thus, isotype-specific biological effects are observed. The accumulation of vesicles correlates with phorbol ester-dependent growth inhibition and occurs only with expression of those isotypes that down-regulate in response to phorbol esters in these cells. Antibodies against mammalian clathrin light chain 1a identified clathrin-coated vesicles and up-regulation of clathrin expression in those cells where vesicles accumulate; the increased vesicular traffic includes an element of endocytosis. Thus expression of specific mammalian PKC isotypes up-regulates endocytosis in S. pombe, providing a likely explanation for PKC-mediated receptor internalization in higher eukaryotes.     

Unique substrate specificity and regulatory properties of PKC-epsilon: a rationale for diversity

PKC-epsilon was isolated from a murine brain cDNA library. The clone, lambda 61PKC-epsilon, encoded a polypeptide of 737 amino acids that is homologous to other PKCs. Northern analysis showed that the 7 kb mRNA for this cDNA is widely expressed. The protein when expressed in COS-1 cells displayed phorbol ester-binding activity. However in order to detect the kinase activity of PKC-epsilon, it was necessary to employ a synthetic peptide substrate based upon the pseudosubstrate site. Subsequent analysis demonstrated that PKC-epsilon, while showing certain properties characteristic of the PKC family, has a quite distinct substrate specificity and is independent of Ca2+.     

Studies on the primary sequence requirements for PKC-alpha, -beta 1 and -gamma peptide substrates.

The substrate specificity of purified PKC-alpha, -beta and -gamma has been investigated. A series of synthetic peptides based upon the sequence surrounding serine-7 in glycogen synthase were generated and used to determine the basic residue requirements of these PKC isotypes. While PKC-alpha and -beta are indistinguishable in their phosphorylation of these peptides, PKC-gamma shows a distinct specificity profile for these synthetic substrates.     

Differential regulation of Cl- transport proteins by PKC in Calu-3 cells

Cl- transport proteins expressed in a Calu-3 airway epithelial cell line were differentiated by function and regulation by protein kinase C (PKC) isotypes. mRNA expression of Cl- transporters was semiquantitated by RT-PCR after transfection with a sense or antisense oligonucleotide to the PKC isotypes that modulate the activity of the cystic fibrosis transmembrane conductance regulator [CFTR (PKC-epsilon)] or of the Na/K/2Cl (NKCC1) cotransporter (PKC-delta). Expression of NKCC1 and CFTR mRNAs and proteins was independent of antisense oligonucleotide treatment. Transport function was measured in cell monolayers grown on a plastic surface or on filter inserts. With both culture methods, the antisense oligonucleotide to PKC-epsilon decreased the amount of PKC-epsilon and reduced cAMP-dependent activation of CFTR but not alpha(1)-adrenergic activation of NKCC1. The antisense oligonucleotide to PKC-delta did not affect CFTR function but did block alpha(1)-adrenergic activation of NKCC1 and reduce PKC-delta mass. These results provide the first evidence for mRNA and protein expression of NKCC1 in Calu-3 cells and establish the differential regulation of CFTR and NKCC1 function by specific PKC isotypes at a site distal to mRNA expression and translation in airway epithelial cells.     

Ether-linked diglycerides inhibit vascular smooth muscle cell growth via decreased MAPK and PI3K/Akt signaling

Diglycerides (DGs) are phospholipid-derived second messengers that regulate PKC-dependent signaling pathways. Distinct species of DGs are generated from inflammatory cytokines and growth factors. Growth factors increase diacyl- but not ether-linked DG species, whereas inflammatory cytokines predominately generate alkyl, acyl- and alkenyl, acyl-linked DG species in rat mesenchymal cells. These DG species have been shown to differentially regulate protein kinase C (PKC) isotypes. Ester-linked diacylglycerols activate PKC-epsilon and cellular proliferation in contrast to ether-linked DGs, which lead to growth arrest through the inactivation of PKC-epsilon. It is now hypothesized that ether-linked DGs inhibit mitogenesis through the inactivation of ERK and/or Akt signaling cascades. We demonstrate that cell-permeable ether-linked DGs reduce vascular smooth muscle cell growth by inhibiting platelet-derived growth factor-stimulated ERK in a PKC-epsilon-dependent manner. This inhibition is specific to the ERK pathway, since ether-linked DGs do not affect growth factor-induced activation of other family members of the MAPKs, including p38 MAPK and c-Jun NH(2)-terminal kinases. We also demonstrate that ether-linked DGs reduce prosurvival phosphatidylinositol 3-kinase (PI3K)/Akt signaling, independent of PKC-epsilon, by diminishing an interaction between the subunits of PI3K and not by affecting protein phosphatase 2A or lipid (phosphatase and tensin homologue deleted in chromosome 10) phosphatases. Taken together, our studies identify ether-linked DGs as potential adjuvant therapies to limit vascular smooth muscle migration and mitogenesis in atherosclerotic and restenotic models.     

PKC-{epsilon}-dependent survival signals in diabetic hearts

Diabetes mellitus is complicated by the development of a primary cardiomyopathy, which contributes to the excess morbidity and mortality of this disorder. The protein kinase C (PKC) family of isozymes plays a key role in the cardiac phenotype expressed during postnatal development and in response to pathological stimuli. Hyperglycemia is an activating signal for cardiac PKC isozymes that modulate a myriad of cell events including cell death and survival. The epsilon-isozyme of the PKC family transmits a powerful survival signal in cardiac muscle cells. Accordingly, to test the hypothesis that endogenous activation of cardiac PKC-epsilon will protect against hyperglycemic cell injury and left ventricular dysfunction, diabetes mellitus was induced using streptozotocin in genetically engineered mice with cardiac-specific expression of the PKC-epsilon translocation activator [psiepsilon-receptors for activated C kinase (psiepsilon-RACK)]. The results demonstrate a striking PKC-epsilon cardioprotective phenotype in diabetic psiepsilon-RACK (epsilon-agonist) mice that is characterized by inhibition of the hyperglycemia apoptosis signal, attenuation of hyperglycemia-mediated oxidative stress, and preservation of parameters of left ventricular pump function. Hearts of diabetic epsilon-agonist mice exhibited selective trafficking of PKC-epsilon to membrane and mitochondrial compartments, phosphorylation/inactivation of the mitochondrial Bad protein, and inhibition of cytochrome c release. We conclude that activation of endogenous PKC-epsilon in hearts of diabetic epsilon-agonist mice promotes the survival phenotype, attenuates markers of oxidative stress, and inhibits the negative inotropic properties of chronic hyperglycemia.     

The linoleic acid derivative DCP-LA selectively activates PKC-epsilon, possibly binding to the phosphatidylserine binding site

This study examined the effect of 8-[2-(2-pentyl-cyclopropylmethyl)-cyclopropyl]-octanoic acid (DCP-LA), a newly synthesized linoleic acid derivative with cyclopropane rings instead of cis-double bonds, on protein kinase C (PKC) activity. In the in situ PKC assay with reverse-phase high-performance liquid chromatography, DCP-LA significantly activated PKC in PC-12 cells in a concentration-dependent (10 nM-100 microM) manner, with the maximal effect at 100 nM, and the DCP-LA effect was blocked by GF109203X, a PKC inhibitor, or a selective inhibitor peptide of the novel PKC isozyme PKC-epsilon. Furthermore, DCP-LA activated PKC in HEK-293 cells that was inhibited by the small, interfering RNA against PKC-epsilon. In the cell-free PKC assay, of the nine isozymes examined here, DCP-LA most strongly activated PKC-epsilon, with >7-fold potency over other PKC isozymes, in the absence of dioleoyl-phosphatidylserine and 1,2-dioleoyl-sn-glycerol; instead, the DCP-LA action was inhibited by dioleoyl-phosphatidylserine. DCP-LA also activated PKC-gamma, a conventional PKC, but to a much lesser extent compared with that for PKC-epsilon, by a mechanism distinct from PKC-epsilon activation. Thus, DCP-LA serves as a selective activator of PKC-epsilon, possibly by binding to the phosphatidylserine binding site on PKC-epsilon. These results may provide fresh insight into lipid signaling in PKC activation.     

Selective degradation of the PKC-epsilon isoform during cell death in AKR-2B fibroblasts

The protein kinase C (PKC) family of serine/threonine protein kinases is involved in intracellular signals that regulate growth, differentiation, and apoptosis. AKR-2B cells express the PKC isoforms alpha, gamma, epsilon, lambda, mu, und zeta (J. Hoppe, R. Sch?fer, V. Hoppe, and A. Sachinidis, Cell Death Differ. 6, 546-556). Here we show that during serum starvation only PKC-epsilon was cleaved. An N-terminal fragment of 42 kDa remained associated with subcellular components, presumably the Golgi apparatus. The C-terminal part (catalytic domain) was further degraded and was no longer detectable in vivo. As published before, the activation of the DEVDase in AKR-2B cells is prevented by numerous agents like PDGF, TPA, and DEVD.cmk (R. Sch?fer, D. Karbach, and J. Hoppe, Exp. Cell Res. 240, 28--39). All these agents completely prevented PKC-epsilon cleavage, indicating a tight correlation between DEVDase activity and PKC-epsilon cleavage. By using recombinant caspase-3 or highly purified DEVDase from cytosolic extracts we localized by Edman degradation the cleavage site in recombinant PKC-epsilon to asp383 in the hinge region between regulatory and catalytic domains. The corresponding tetrapeptide sequences SSPD and SATD for human and mouse PKC-epsilon, respectively, are unusual for caspase-3. Expression of the catalytic domain or of the cleavage-resistant mutant D383A had no effect on cell death in AKR-2B cells.     

Protein kinase C-epsilon protects PC12 cells against methamphetamine-induced death: possible involvement of suppression of glutamate receptor

The involvement of PKC isoform in the methamphetamine (MA)-induced death of neuron-like PC12 cell was studied. The death and the enhanced terminal dUTP nick end labeling (TUNEL) staining were inhibited by a caspase inhibitor, z-Val-Ala-Asp- (OMe)-CH(2)F (z-VAD-fmk). However, the cell death shows neither morphological nor biochemical features of apoptosis or necrosis. The cell death was suppressed by a protein kinase C (PKC) activator, 12,13-phorbol myristate acetate, but was enhanced by PKC specific inhibitor calphostin C or bisindolylmaleimide, not by PKC inhibitor relatively specific for PKC-alpha (safingol) or PKC-delta (rottlerin). Western blotting demonstrated the expression of PKC-alpha, gamma, delta, epsilon and zeta, of which PKC-epsilon translocated from the soluble to the particulate fraction after MA-treatment. Antisense to PKC-epsilon enhanced MA-induced death. A glutamate receptor antagonist MK801 abrogated the cell death, which is reversed by PKC inhibition. These data suggest that PKC-epsilon promotes PC12 cell survival through glutamate receptor suppression.     

Overexpression of protein kinase C-epsilon and its regulatory domains in fibroblasts inhibits phorbol ester-induced phospholipase D activity

In fibroblasts, the protein kinase C (PKC) activator phorbol 12-myristate 13-acetate (PMA) stimulates phospholipase D (PLD)-mediated hydrolysis of both phosphatidylcholine (PtdCho) and phosphatidylethanolamine (PtdEtn) by PKC-alpha-mediated nonphosphorylating and phosphorylating mechanisms. Here we have used NIH 3T3 fibroblasts overexpressing holo PKC-epsilon and its regulatory, catalytic, and zinc finger domain fragments to determine if this isozyme also regulates PLD activity. Overexpression of holo PKC-epsilon inhibited the stimulatory effects of PMA (5-100 nM) on both PtdCho and PtdEtn hydrolysis. Overexpression of PKC-epsilon also was found to inhibit platelet-derived growth factor-induced PLD activity. Expression of the catalytic unit of PKC-epsilon had no effect on PMA-induced PLD activity. In contrast, expression of both the regulatory domain fragment and the zinc finger domain of PKC-epsilon resulted in significant inhibition of PMA-stimulated PtdCho and PtdEtn hydrolysis. Interestingly, although PKC-alpha also mediates the stimulatory effect of PMA on the synthesis of PtdCho by a phosphorylation mechanism, overexpression of holo PKC-epsilon or its regulatory domain fragments did not affect PMA-induced PtdCho synthesis. These results indicate that the PKC-epsilon system can act as a negative regulator of PLD activity and that this inhibition is mediated by its regulatory domain.     

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.     

Localization and kinetics of protein kinase C-epsilon anchoring in cardiac myocytes

Protein kinase C-epsilon (PKC-epsilon) plays a central role in cardiac cell signaling, but mechanisms of translocation and anchoring upon activation are poorly understood. Conventional PKC isoforms rely on a rapid Ca2+-mediated recruitment to cell membranes, but this mechanism cannot be employed by PKC-epsilon or other PKC isoforms lacking a Ca2+-binding domain. In this study, we used recombinant green fluorescent protein (GFP) fusion constructs and confocal microscopy to examine the localization, kinetics, and reversibility of PKC-epsilon anchoring in permeabilized rat cardiac myocytes. PKC-epsilon-GFP bound with a striated pattern that co-localized with alpha-actinin, a marker of the Z-line of the sarcomere. Binding required activation of PKC and occurred slowly but reversibly with apparent rate constants of k(on) = 4.6 +/- 1.2 x 10(3) M(-1) x s(-1) and k(off) = 1.4 +/- 0.5 x 10(-3) s(-1) (t1/2 = 8 min) as determined by fluorescence recovery after photobleaching and by perfusion experiments. A truncated construct composed of the N-terminal 144-amino-acid variable region of PKC-epsilon (epsilonV1-GFP), but not an analogous N-terminal domain of PKC-delta, mimicked the Z-line decoration and slow binding rate of the full-length enzyme. These findings suggest that the epsilonV1 domain is important in determining PKC-epsilon localization and translocation kinetics in cardiac muscle. Moreover, PKC-epsilon translocation is not a diffusion-controlled binding process but instead may be limited by intramolecular conformational changes within the V1 domain. The k(off) for epsilonV1-GFP was two- to threefold faster than for full-length enzyme, indicating that other domains in PKC-epsilon contribute to anchoring by prolonging the bound state.     

Biochemical properties of rat protein kinase C-eta expressed in COS cells.

Using a PKC-epsilon cDNA probe a cDNA for PKC-eta has been cloned from a rat lung cDNA library. When expressed in COS cells, rat PKC-eta appeared as an 84 kDa protein. PKC-eta expressed in COS cells, was solubilized by 1% Triton X-100 and purified away from the endogenous PKC-alpha by ammonium sulphate fractionation. The activity of this PKC-eta preparation was characterized with respect to cofactor dependence and substrate specificity. Various PKC pseudosubstrate peptides are phosphorylated by PKC-eta in a phospholipid and TPA-dependent but calcium-independent manner. The polypeptide histone IIIS is a poor substrate.     

Protein kinase C-epsilon (PKC-epsilon): its unique structure and function

Protein kinase C (PKC)-epsilon was first discovered among novel PKC isotypes by cDNA cloning, and characterized as a calcium-independent but phorbol ester/diacylglycerol-sensitive serine/threonine kinase. PKC-epsilon is targeted to a specific cellular compartment in a manner dependent on second messengers and on specific adapter proteins in response to extracellular signals that activate G-protein-coupled receptors, tyrosine kinase receptors, or tyrosine kinase-coupled receptors. PKC-epsilon then regulates various physiological functions including the activation of nervous, endocrine, exocrine, inflammatory, and immune systems. The controlled activation of PKC-epsilon plays a protective role in the development of cardiac ischemia and Alzheimer's disease, whereas its uncontrolled chronic activation results in severe diseases such as malignant tumors and diabetes. This review summarizes recent progress in our understanding of the unique structure and physiological and pathological roles of PKC-epsilon with a focus mainly on knockout, transgenic, and mutational studies.     

PKC signaling at fertilization in mammalian eggs

Protein kinase C (PKC) has been proposed to regulate major egg activation events during mammalian fertilization. Most of the evidence supporting this assumption has first been obtained using pharmacological activation and inhibition of the kinase, while egg activation was assessed by checking for exocytosis of the cortical granules, extrusion of the second polar body and formation of pronuclei. However, results have been inconclusive and sometimes contradictory regarding the exact role of PKC in regulating egg activation events. The PKC family is composed of various isotypes, which differ in their modular structures and regulatory properties. Hence the need to re-examine the roles of egg PKCs more specifically. Mammalian eggs express many PKC isotypes, the roles of which have been investigated using immunodetection, isotype-specific inhibition and, more recently, live imaging of fluorescent chimaeras. Here, I review the recent development of PKC research in mammalian fertilization and the evidence for a specific role for certain PKC isotypes in fertilization-induced egg activation.     

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.     

PKC epsilon is a unique regulator for hsp90 beta gene in heat shock response

An early event in cellular heat shock response is the transmittance of stress signals from the cell surface into the nuclei, resulting in the induction of heat shock proteins (Hsps). Protein kinase C (PKC) has been implicated as a key player in transducing stress signals. However, mechanism(s) by which PKC regulates heat shock-induced events remains largely unknown. Here we present data that pan-PKC inhibitor GF109203X, but not classic PKC inhibitor G?6976, specifically repressed heat shock-induced accumulation of mRNA as well as promoter activity of hsp90 beta, but not hsp90 alpha, in Jurkat cells. Subcellular fractionation studies revealed that heat shock exclusively induced PKC-epsilon membrane translocation. Consistently, expression of a constitutively active PKC-epsilon(A159E) resulted in an enhanced promoter activity of hsp90 beta upon heat shock, whereas a dominant-negative PKC-epsilon(K437R) abolished this effect. In contrast, constitutively active-PKC-alpha or dominant-negative-PKC-alpha had no effects on heat shock induction of the gene. The effect of PKC-epsilon on hsp90 beta expression seems to be stimuli-specific, as phorbol myristate acetate-mediated hsp90 beta expression was PKC-epsilon-independent. We conclude that PKC-epsilon is specifically required in the signaling pathway leading to the induction of hsp90 beta gene in response to heat shock.     

Expression and characterization of protein kinase C-delta

A cDNA encoding protein kinase C-delta (PKC-delta) was isolated from a rat brain library. The coding region was subcloned into the expression vector pmt2 and transfected into COS-1 cells. Expression of the protein led to an 11-fold increase in activity as determined with a synthetic peptide based on the PKC-delta pseudosubstrate site. The Mr of PKC-delta as determined by SDS/PAGE and immunoblot analysis using anti-(PKC-delta C-terminal) antibodies was 77,000. The enzyme was purified to near homogeneity and showed total dependency on phospholipid and diacylglycerol (or phorbol esters) for activity. Like PKC-epsilon, PKC-delta displays no Ca2+ dependence for activation. The substrate specificity of PCK-delta is similar to that of PKC-epsilon but quite different from other PKCs.