Protein kinase C initially inhibits the induction of meiotic cell division in Xenopus oocytes.

We have used one activator and two inhibitors of protein kinase C (PKC) to examine the role of this enzyme in the induction of meiotic cell division. At 1 U/ml, phosphatidylcholine-specific phospholipase C increases DAG, alters intracellular pH and inhibits the induction of meiosis by insulin or progesterone. However, when added about 1.6 h after progesterone, the enzyme speeds the induction of cell division. Microinjection of inhibitor peptide (19-36) of PKC has little effect on progesterone action but stimulates the induction of meiosis by insulin. When the inhibitor peptide is injected about 2h after insulin addition, the peptide inhibits. A second PKC inhibitor, staurosporine, decreases PKC-dependent intracellular pH and in vitro oocyte PKC activity. At similar concentrations, staurosporine stimulates insulin or progesterone action, but, when added after about 2 h, the drug inhibits induction by insulin. We conclude that PKC is initially inhibitory to the induction of meiotic cell division but then may become synergistic.     

Protein kinase C: properties and possible role in cellular division and differentiation

Protein kinase C was first described some eight years ago. Recent results indicate that this kinase may have a crucial role in signal transduction for substances involved in cellular differentiation and division. Protein kinase C is activated by attachment to plasma membranes, in the presence of calcium and diacylglycerol. The activator is produced in the membrane following the signal-induced breakdown of phosphoinositides. Tumor promoters, such as phorbol ester, can substitute for diacylglycerol. The recent findings that: tyrosine kinases might be involved in the phosphoinositide turnover and, phosphorylation of growth factor receptors by protein kinase C regulates some of their functions, indicate more and more clearly that this kinase is involved in the control of cell growth division and differentiation. Purification procedures, properties and mechanisms of regulation will be summarized and discussed.     

Protein kinase C epsilon suppresses Abeta production and promotes activation of alpha-secretase

Deposition of plaques containing Abeta is considered important in the pathogenesis of Alzheimer's disease. Phorbol esters that activate protein kinase C (PKC) promote alpha-secretase-mediated processing of the beta amyloid precursor protein (APP), which generally reduces formation of Abeta. To determine which PKC isozymes mediate this process, we studied CHO cells that express human APP751. Phorbol 12-myristate, 13-acetate (PMA)-stimulated APP secretion, which was reduced by a general PKC inhibitor bisindoylmaleimide I, but not by G? 6976, which inhibits PKCalpha, beta, gamma, and mu. Since PKCdelta and epsilon were the only other PMA-sensitive isozymes present, we studied cells that express selective peptide inhibitors of these isozymes. Expression of the PKCepsilon inhibitor inhibited PMA-induced APPs secretion and suppression of Abeta production. In contrast, the PKCdelta inhibitor had no effect. These results provide evidence that PKCepsilon decreases Abeta production by promoting alpha-secretase mediated cleavage of APP.     

Protein kinase C epsilon: a new target to control inflammation and immune-mediated disorders

Recent advances in understanding the molecular basis for mammalian host immune responses to microbial invasion suggest that the first line of defense against microbes is the recognition of pathogen-associated molecular patterns by a set of germline-encoded receptors: the Toll-like receptors (TLRs). TLRs have been identified as being part of a large family of pathogen-recognition receptors that play a decisive role in the induction of both innate and adaptive immunity. Indeed, activation of T lymphocytes depends on their interaction with dendritic cells previously stimulated by TLR agonists such as bacterial lipopolysaccharide (LPS), a TLR-4 ligand. A novel PKC epsilon (epsilon) was recently found to be a critical component of TLR-4 signaling pathway and thereby to play a key role in macrophage and dendritic cell (DC) activation in response to LPS. Thus, controlling the kinase activity of PKC epsilon might represent an efficient strategy to prevent or treat certain inflammatory disorders of microbial origin.     

蛋白激酶C与细胞周期

近年的研究表明,PKC涉及到细胞的周期调节。在酵母细胞和哺乳动物细胞均发现PKC参与细胞周期调控,从而提示PKC可能在进化上是一种保守的细胞周期调节子。一般认为PKC在两个点上对细胞周期起作用,即G1期和G2期到M期的过渡期（G2／M）。在G1期,PKC分别在早G1期和晚G1期作用有所不同,主要作用表现在使细胞停留在G1期的中末阶段,这一过程,主要涉及到抑制肿瘤抑制因子－成视网膜细胞瘤（Rb)蛋白的磷酸化。PKC的主要作用是降低周期素依赖激酶CDK2的活性、降低周期素E和A的表达和增加周期素依赖的周期抑制蛋白p21^WAF1和p27^KIP1的表达;在G2／M期,PKC对细胞周期的调节主要与Cdc2(CDK1)的活性抑制有关。     

Protein kinase C epsilon is required for the induction of mitogen-activated protein kinase phosphatase-1 in lipopolysaccharide-stimulated macrophages

LPS induces in bone marrow macrophages the transient expression of mitogen-activated protein kinase (MAPK) phosphatase-1 (MKP-1). Because MKP-1 plays a crucial role in the attenuation of different MAPK cascades, we were interested in the characterization of the signaling mechanisms involved in the control of MKP-1 expression in LPS-stimulated macrophages. The induction of MKP-1 was blocked by genistein, a tyrosine kinase inhibitor, and by two different protein kinase C (PKC) inhibitors (GF109203X and calphostin C). We had previously shown that bone marrow macrophages express the isoforms PKC beta I, epsilon, and zeta. Of all these, only PKC beta I and epsilon are inhibited by GF109203X. The following arguments suggest that PKC epsilon is required selectively for the induction of MKP-1 by LPS. First, in macrophages exposed to prolonged treatment with PMA, MKP-1 induction by LPS correlates with the levels of expression of PKC epsilon but not with that of PKC beta I. Second, G?6976, an inhibitor selective for conventional PKCs, including PKC beta I, does not alter MKP-1 induction by LPS. Last, antisense oligonucleotides that block the expression of PKC epsilon, but not those selective for PKC beta I or PKC zeta, inhibit MKP-1 induction and lead to an increase of extracellular-signal regulated kinase activity during the macrophage response to LPS. Finally, in macrophages stimulated with LPS we observed significant activation of PKC epsilon. In conclusion, our results demonstrate an important role for PKC epsilon in the induction of MKP-1 and the subsequent negative control of MAPK activity in macrophages.     

Protein kinase C epsilon is involved in ionizing radiation induced bystander response in human cells

Our earlier study demonstrated the induction of PKC isoforms (βII, PKC-α/β, PKC-θ) by ionizing radiation induced bystander response in human cells. In this study, we extended our investigation to yet another important member of PKC family, PKC epsilon (PKC?). PKC? functions both as an anti-apoptotic and pro-apoptotic protein and it is the only PKC isozyme implicated in oncogenesis. Given the importance of PKC? in oncogenesis, we wished to determine whether or not PKC? is involved in bystander response. Gene expression array analysis demonstrated a 2–3-fold increase in PKC? expression in the bystander human primary fibroblast cells that were co-cultured in double-sided Mylar dishes for 3 h with human primary fibroblast cells irradiated with 5 Gy of α-particles. The elevated PKC? expression in bystander cells was verified by quantitative real time PCR. Suppression of PKC? expression by small molecule inhibitor Bisindolylmaleimide IX (Ro 31-8220) considerably reduced the frequency of micronuclei (MN) induced both by 5 Gy of γ-rays (low LET) and α-particles (high LET) in bystander cells. Similar cytoprotective effects were observed in bystander cells after siRNA mediated silencing of PKC? suggestive of its critical role in mediating some of the bystander effects (BE). Our novel study suggests the possibility that PKC signaling pathway may be a critical molecular target for suppression of ionizing radiation induced biological effects in bystander cells.     

Protein kinase C epsilon mediates the induction of P-glycoprotein in LNCaP prostate carcinoma cells.

P-glycoprotein (P-gp) mediates drug resistance. Protein kinase C (PKC) expression correlates with drug resistance in several types of cancer. We determined whether PKC signals the induction of P-gp in LNCaP human prostate cancer cells, and identified a specific isozyme involved, in a model of aspirin-induced P-glycoprotein expression. An inhibitor of PKC activity, and a specific peptide inhibitor of PKC epsilon translocation, suppressed the induction of P-gp. The PKC activator ingenol, but not OAG, induced P-gp expression in a dose-dependent manner. Based on our results, we conclude that PKC epsilon mediates the induction of P-gp. Accordingly, PKC epsilon is activated and translocates from the membrane fraction to the cytoskeleton fraction in aspirin-treated cells. The findings of this study point to PKC epsilon as a signalling molecule for the induction of P-gp in LNCaP prostate cancer cells.     

Protein kinase C(mu) regulation of the JNK pathway is triggered via phosphoinositide-dependent kinase 1 and protein kinase C(epsilon)

The protein kinase C (PKC)-related enzyme PKC(mu)/PKD (protein kinase D) is activated by activation loop phosphorylation through PKC(eta). Here we demonstrate that PKC(mu) is activated by the direct phosphorylation of PKC(epsilon). PKC(mu) colocalizes with PKC(epsilon) in HEK293 and MCF7 cells as shown by confocal immunofluorescence analyses. PDK1, known as the upstream kinase for several PKC isozymes, associates intracellularly with PKC(epsilon) and PKC(eta). PKC(eta) is phosphorylated by PDK1 in vitro, leading to kinase activation as similarly reported for PKC(epsilon) activation by PDK1. Coexpression of PDK1, PKC(epsilon) and PKC(mu) in HEK293 cells results in PKC(mu) activation. In contrast, the coexpression of PDK1 and PKC(eta) with PKC(mu) does not activate PKC(eta) or consequently PKC(mu). PDK1/PKC(epsilon)-triggered activation of PKC(mu) inhibits JNK, a downstream effector of PKC(mu), whereas upon transient expression of PDK1, PKC(eta), and PKC(mu), JNK is not affected. These data implicate PKC(epsilon) as the biologically important upstream kinase for PKC(mu) in HEK293 cells, regulating downstream effectors. Our results further indicate a PDK1/PKC(eta)/PKC(mu) controlled negative regulation of PKC(eta) kinase activity. In this study, we show that differentially activated kinase cascades involving PDK1 and novel PKC isotypes are responsible for the regulation of PKC(mu) activity and consequently inhibit the JNK pathway.     

Histone kinase and cell division

1. The activity of the soluble phosphokinase for histone F1 increases in regenerating rat liver during the first period of DNA synthesis after partial hepatectomy. The increase probably represents new enzyme synthesis. 2. A dose of 500rd of gamma-irradiation given early in G1 decreases the amount of histone F1 phosphokinase found 22h after partial hepatectomy by 60-70%. 3. The enzyme preparations also contained a histone F1 phosphatase; the presence together of the kinase and phosphatase caused a disproportion between net (31)P uptake and (32)P incorporation into histone F1. 4. All four subclasses of histone F1 could accept phosphate from ATP. 5. Crude enzyme preparations transferred more (31)P into histone F1 with an initially low phosphate content than into one with a high phosphate content; conversely, more (32)P was transferred into the latter.     

Protein kinase C in tumoricidal activation of mouse macrophage cell lines

A potential role of protein kinase C (PKC) in lipopolysaccharide- (LPS-) induced tumoricidal activation of macrophages was investigated by using two mouse macrophage cell lines (P388D1 and J774). J774 cells are stimulated by LPS to kill target P815 mastocytoma cells, whereas P388D1 cells fail to develop such an ability. Pretreatment of J774 cells with H-7 or phorbol myristate acetate resulted in a significant inhibition of LPS-induced cytotoxicity, whereas pretreatment with H-8, ML-7, HA1004, or W-7 did not. Since these results suggested a critical role of PKC in the activation process, the properties of PKC in the two cell lines were compared. Western blotting with rabbit antiserum specific for the PKC beta regulatory domain allowed detection of a protein of 79 kilodaltons (kDa) in the detergent lysates of both cell lines that were not stimulated by LPS. However, LPS treatment resulted in the appearance of a second protein of 40 kDa only in J774 cells and not in P388D1 cells. Furthermore, two forms of protein kinase (one basic and the other acidic) were identified in the cytosol of J774 cells by HPLC on DEAE-5PW, whereas only the basic form was found in P388D1 cells. On the basis of the response of the basic and acidic form protein kinases to phosphatidylserine (PS), diolein, and Ca2+, the basic form was found to contain both regulatory and catalytic domains of PKC, whereas the acidic form was suggested to represent the PKC catalytic domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protein kinase C epsilon activation delays neuronal depolarization during cardiac arrest in the euthermic arctic ground squirrel

During the pre-hibernation season, arctic ground squirrels (AGS) can tolerate 8 min of asphyxial cardiac arrest (CA) without detectable brain pathology. Better understanding of the mechanisms regulating innate ischemia tolerance in AGS has the potential to facilitate the development of novel prophylactic agents to induce ischemic tolerance in patients at risk of stroke or CA. We hypothesized that neuroprotection in AGS involves robust maintenance of ion homeostasis similar to anoxia-tolerant turtles. Ion homeostasis was assessed by monitoring ischemic depolarization (ID) in cerebral cortex during CA in vivo and during oxygen glucose deprivation in vitro in acutely prepared hippocampal slices. In both models, the onset of ID was significantly delayed in AGS compared with rats. The epsilon protein kinase C (εPKC) is a key mediator of neuroprotection and inhibits both Na⁺/K⁺-ATPase and voltage-gated sodium channels, primary mediators of the collapse of ion homeostasis during ischemia. The selective peptide inhibitor of εPKC (εV1-2) shortened the time to ID in brain slices from AGS but not in rats despite evidence that εV1-2 decreased activation of εPKC in brain slices from both rats and AGS. These results support the hypothesis that εPKC activation delays the collapse of ion homeostasis during ischemia in AGS.     

Signal transduction of constitutively active protein kinase C epsilon

The protein kinase C (PKC) family is the most prominent target of tumor-promoting phorbol esters. For the PKCε isozyme, different intracellular localizations and oncogenic potential in several but not all experimental systems have been reported. To obtain information about PKCε-signaling, we investigated the effects of constitutively active rat PKCε (PKCεA/E, alanine 159 is replaced by glutamic acid) in HeLa cells in a doxycycline-inducible vector. Upon induction of PKCεA/E expression by doxycycline, the major part of PKCεA/E was localized to the Golgi. This led (i) to phosphorylations of PKCε^S729, Elk-1^S383, PDK1^S241 and Rb^S807/S811, (ii) to elevated expression of receptor of activated C kinase 2 (RACK2) after 12 h, and (iii) increased colony formation in soft agar, increased cell migration and invasion, but not to decreased doubling time. Following induction of PKCεA/E-expression by doxycycline for 24 h and additional short-term treatment with 12-O-tetradecanoylphorbol-13-acetate (TPA), PKCεA/E translocated to the plasma membrane and increased phosphorylation of MARCKS^S152/156. Treatment with doxycycline/TPA or TPA alone increased phosphorylations of Elk-1^S383, PDK1^S241, Rb^S807/S811, PKCδ^T505, p38MAPK^T180/Y182, MEK1/2^S217/S221 and ERK2^T185/T187. MARCKS was not phosphorylated after treatment with TPA alone, demonstrating that in this system it is phosphorylated only by PKCε localized to the plasma membrane but not by PKCα or δ, the other TPA-responsive PKC isozymes in HeLa cells. These results demonstrate that PKCε can induce distinctly different signaling from the Golgi and from the plasma membrane.     

Protein kinase C theta and epsilon promote T-cell survival by a rsk-dependent phosphorylation and inactivation of BAD

Both MAPK and protein kinase C (PKC) signaling pathways promote cell survival and protect against cell death. Here, we show that 12-O-tetradecanoylphorbol-13-acetate (TPA) prevents Fas-induced apoptosis in T lymphocytes. The effect of TPA was specifically abolished by the PKC inhibitor GF109203X and by dominant negative PKCtheta, PKCepsilon, and PKCalpha, suggesting that novel and conventional PKC isoforms mediate phorbol ester action. Moreover, TPA stimulated phosphorylation of BAD at serine 112, an effect abrogated by GF109203X but not by the MEK inhibitor PD98059. Expression of constitutively active PKC increased the phosphorylation of BAD at serine 112 but not at serine 136. Additionally, Fas-mediated cell death was enhanced by overexpression of a catalytically inactive form of p90Rsk (Rsk2-KN). Finally, Rsk2-KN abolished the protective effect of constitutively active PKC and totally blocked phosphorylation of BAD on serine 112. Thus, novel PKCtheta and PKCepsilon rescue T lymphocytes from Fas-mediated apoptosis via a p90Rsk-dependent phosphorylation and inactivation of BAD.     

Aurora A in cell division: kinase activity not required

Aurora A kinase is a key regulator of cell division, whose functions were attributed to its ability to phosphorylate diverse substrates. Aurora A is now shown to have a kinase-independent role in the regulation of chromatin-mediated microtubule assembly.     

Protein kinase C regulation: C1 meets C-tail

In a recent issue of Cell, Leonard et?al. (2011) describe the structure of PKCβII, an AGC kinase, revealing an unanticipated intramolecular autoinhibitory interaction between its C-terminal tail and the diacylglycerol and phorbol ester binding site of its C1b domain.