PKCα Inhibition Research Articles

Inhibitory mechanism of pure curcumin on Wilms’ tumor 1 (WT1) gene expression through the PKCα signaling pathway in leukemic K562 cells

The aim of this study was to investigate the inhibitory mechanism of pure curcumin on WT1 expression in leukemic K562 cells. Pure curcumin suppressed WT1 expression, independent of effects on protein degradation or WT1 mRNA stability. Chromatin immunoprecipitation and reporter gene assays indicate that pure curcumin treatment attenuates WT1 auto-regulation. Interestingly, PKCα inhibition mimicks the repressive effects of pure curcumin in K562 cells. Conversely, myristoylated PKCα over-expression increased WT1 expression and reversed the inhibitory effect of pure curcumin. Our study indicates that pure curcumin attenuates WT1 auto-regulatory function through inhibition of PKCα signaling in K562 cells.

The extend of desmoglein 3 depletion in pemphigus vulgaris is dependent on Ca2+‐induced differentiation – a role in suprabasal epidermal skin splitting?

Pemphigus vulgaris (PV) is an autoimmune disease of skin and mucous membranes characterized by formation of intraepidermal blisters. Patients develop autoantibodies against the desmosomal cadherins desmoglein (Dsg) 3 and 1, leading to suprabasal keratinocyte detachment. Depletion of Dsg3 was reported to be a critical mechanism in PV pathogenesis. Because we did not detect reduced Dsg3 levels in keratinocytes cultured for longer time periods in high Ca2+ conditions, we hypothesized that Dsg depletion was dependent on Ca2+-mediated keratinocyte differentiation. Our data indicate that depletion of Dsg3 occurs specifically in deep epidermal layers both in PV patient skin and an organotypic raft model of human epidermis. Also, depletion was prominent in cultured primary keratinocytes as well as in HaCaT cells incubated in high Ca2+ media for 3d but is less pronounced in HaCaT cultures after 8d. These effects were dependent on protein kinase C alpha (PKCα) signaling because inhibition of PKCα blunted both Dsg3 depletion and loss of intercellular adhesion. Moreover, PKCα inhibition blocked suprabasal Dsg3 depletion in cultured human epidermis and blister formation in a neonatal mouse model. Taken together, our data indicate a contribution of Dsg depletion to PV pathogenesis dependent on Ca2+-induced differentiation, which may contribute to the suprabasal cleavage plane observed in PV.

PKC-ALPHA MEDIATES NEPHRIN ENDOCYTOSIS: PP.9.354

Background: Mikroalbuminuria is an early lesion during the development of diabetic nephropathy. The loss of high molecular weight proteins in the urine is usually associated with decreased expression of slit diaphragm proteins. Nephrin, is the major component of the glomerular slit diaphragm and loss of nephrin has been well described in rodent models of experimental diabetes as well as in human diabetic nephropathy. Methodology/Principal Findings: In this manuscript we analyzed the role of PKCalpha (PKCα) on endocytosis of nephrin in podocytes. We found that treatment of diabetic mice with a PKCα-inhibitor (GÖ6976) leads to preserved nephrin expression and reduced proteinuria. In addition, we found that PKCα deficient mice are completely protected from LPS induced transient proteinuria. In vitro, we found that high glucose but also LPS stimulation would induce PKCα protein expression. We can demonstrate that PKCα mediates nephrin endocytosis in podocytes and that overexpression of PKCα leads to an augmented endocytosis response. After PKCactivation, we demonstrate an inducible association of PKCα, PICK1 and nephrin in podocytes. Moreover we can demonstrate a strong induction of PKCα in podocytes of patients with diabetic nephropathy. Conclusions/Significance: We therefore conclude that activation of PKCα is a pathomechanistic key event during the development of diabetic nephropathy. PKCα is involved in reduction of nephrin surface expression and therefore PKCα inhibition might be a novel target olecule for anti-proteinuric therapy.

Abstract LB-372: Activation of focal adhesion kinase in cancer cells is regulated by crosstalk between PKCα and MDA-9/syntenin

Abstract mda-9/Syntenin, a tandem PDZ-domain containing adaptor protein, functions as a positive regulator of cancer cell progression in several human cancers. Protein kinase Cα (PKCα) is a key intermediate between integrins and focal adhesion kinase (FAK) signaling in response to fibronectin (FN), but the molecular mechanism by which PKCα regulates FN-induced FAK activation remains unclear. Here, we report that mda-9/syntenin links FN-induced activation of FAK and PKCα in human breast cancer and melanoma cells. FN induced mda-9/syntenin expression and PKCα activation in a similar manner prior to FAK activation. PKCα inhibition resulted in the suppression of the endogenous and FN-induced mda-9/syntenin expression, as well as mda-9/syntenin-induced cell migration and invasion toward FN. mda-9/Syntenin expression and PKCα activation was interdependently regulated; e.g., inhibition of mda-9/syntenin suppressed both FN-induced and endogenous phosphorylation of PKCα at Thr638/641, and inhibition of PKCα suppressed both FN-induced and endogenous expression of mda-9/syntenin. Moreover, inhibition of either mda-9/syntenin or PKCα suppressed the FN-induced association of integrin- 1/FAK/c-Src signaling complexes. Consistently, suppression of either mda-9/syntenin or PKCα significantly inhibited FN-induced phosphorylation of FAK at Tyr397 and c-Src at Tyr416, activation of downstream signaling molecules such p38 and ERK mitogen-activated protein kinases (MAPKs), Cdc42 GTPase, and nuclear factor-κB (NF-κB). These findings demonstrate that PKC -dependent mda-9/syntenin up regulation could play a critical role in FN-induced activation of FAK, and mda-9/syntenin may act as a molecular adaptor that links PKCα and FAK during adhesion to FN in human breast cancer and melanoma cells. Note: This abstract was not presented at the AACR 101st Annual Meeting 2010 because the presenter was unable to attend. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr LB-372.

PKCα expression is a marker for breast cancer aggressiveness

BackgroundProtein kinase C (PKC) isoforms are potential targets for breast cancer therapy. This study was designed to evaluate which PKC isoforms might be optimal targets for different breast cancer subtypes.ResultsIn two cohorts of primary breast cancers, PKCα levels correlated to estrogen and progesterone receptor negativity, tumor grade, and proliferative activity, whereas PKCδ and PKCε did not correlate to clinicopathological parameters. Patients with PKCα-positive tumors showed poorer survival than patients with PKCα-negative tumors independently of other factors. Cell line studies demonstrated that PKCα levels are high in MDA-MB-231 and absent in T47D cells which proliferated slower than other cell lines. Furthermore, PKCα silencing reduced proliferation of MDA-MB-231 cells. PKCα inhibition or downregulation also reduced cell migration in vitro.ConclusionsPKCα is a marker for poor prognosis of breast cancer and correlates to and is important for cell functions associated with breast cancer progression.

Activation of the Integrin Effector Kinase Focal Adhesion Kinase in Cancer Cells Is Regulated by Crosstalk between Protein Kinase Cα and the PDZ Adapter Protein mda-9/Syntenin

Aberrant adhesion signaling pathways in cancer cells underlie their deadly invasive capabilities. The adhesion-related PDZ adapter protein mda-9/syntenin is a positive regulator of cancer cell progression in breast cancer, melanoma, and other human cancers. In this study, we report that mda-9/syntenin mediates adhesion-mediated activation of protein kinase Calpha (PKCalpha) and focal adhesion kinase (FAK) by fibronectin (FN) in human breast cancer and melanoma cells. FN rapidly stimulated the expression of mda-9/syntenin and the activation of PKCalpha prior to activation of FAK. Inhibiting PKCalpha suppressed basal or FN-induced expression of mda-9/syntenin, as well as cell migration and invasion toward FN stimulated by mda-9/syntenin. Several lines of evidence suggested that activation of PKCalpha and expression of mda-9/syntenin were interdependent. First, mda-9/syntenin inhibition suppressed basal or FN-induced phosphorylation of PKCalpha at Thr(638/641), whereas PKCalpha inhibition suppressed basal or FN-induced expression of mda-9/syntenin. Second, inhibiting either mda-9/syntenin or PKCalpha suppressed FN-induced formation of integrin-beta(1)/FAK/c-Src signaling complexes. Third, inhibiting either mda-9/syntenin or PKCalpha suppressed FN-induced phosphorylation of FAK Tyr(397) and c-Src Tyr(416) and the induction of downstream effector signals to p38 and mitogen-activated protein kinase, Cdc42, and NF-kappaB. In summary, our findings offer evidence that mda-9/syntenin acts as a molecular adaptor linking PKCalpha and FAK activation in a pathway of FN adhesion by human breast cancer and melanoma cells.

Human Uterine Smooth Muscle and Leiomyoma Cells Differ in Their Rapid 17β-Estradiol Signaling: Implications for Proliferation

Uterine leiomyomas, benign uterine smooth muscle tumors that affect 30% of reproductive-aged women, are a significant health concern. The initiation event for these tumors is unclear, but 17beta-estradiol (E2) is an established promoter of leiomyoma growth. E2 not only alters transcription of E2-regulated genes but also can rapidly activate signaling pathways. The aim of our study is to investigate the role of rapid E2-activated cytoplasmic signaling events in the promotion of leiomyomas. Western blot analysis revealed that E2 rapidly increases levels of phosphorylated protein kinase C alpha (PKC alpha) in both immortalized uterine smooth muscle (UtSM) and leiomyoma (UtLM) cell lines, but increases levels of phosphorylated ERK1/2 only in UtLM cells. Our studies demonstrate a paradoxical effect of molecular and pharmacological inhibition of PKC alpha on ERK1/2 activation and cellular proliferation in UtLM and UtSM cells. PKC alpha inhibition decreases levels of phosphorylated ERK1/2 and proliferation in UtLM cells but raises these levels in UtSM cells. cAMP-PKA signaling is rapidly activated only in UtSM cells with E2 and inhibits ERK1/2 activation and proliferation. We therefore propose a model whereby E2's rapid activation of PKC alpha and cAMP-PKA signaling plays a central role in the maintenance of a low proliferative index in normal uterine smooth muscle via its inhibition of the MAPK cascade and these pathways are altered in leiomyomas to promote MAPK activation and proliferation. These studies demonstrate that rapid E2-signaling pathways contribute to the promotion of leiomyomas.

A Feed-Forward Loop Involving Protein Kinase Cα and MicroRNAs Regulates Tumor Cell Cycle

Protein kinase Calpha (PKCalpha) has been implicated in cancer, but the mechanism is largely unknown. Here, we show that PKCalpha promotes head and neck squamous cell carcinoma (SCCHN) by a feed-forward network leading to cell cycle deregulation. PKCalpha inhibitors decrease proliferation in SCCHN cell lines and xenografted tumors. PKCalpha inhibition or depletion in tumor cells decreases DNA synthesis by suppressing extracellular signal-regulated kinase phosphorylation and cyclin E synthesis. Additionally, PKCalpha down-regulates miR-15a, a microRNA that directly inhibits protein synthesis of cyclin E, as well as other cell cycle regulators. Furthermore, both PKCalpha and cyclin E protein expression are increased in primary tumors, and PKCalpha inversely correlates with miR-15a expression in primary tumors. Finally, PKCalpha is associated with poor prognosis in SCCHN. These results identify PKCalpha as a key regulator of SCCHN tumor cell growth by a mechanism involving activation of mitogen-activated protein kinase, an initiator of the cell cycle, and suppression of miR-15a, an inhibitor of DNA synthesis. Although the specific components may be different, this type of feed-forward loop network, consisting of a stimulus that activates a positive signal and removes a negative brake, is likely to be a general one that enables induction of DNA synthesis by a variety of growth or oncogenic stimuli.

Serotonin modifies cytoskeleton and brush-border membrane architecture in human intestinal epithelial cells

Serotonin or 5-hydroxytryptamine (5-HT) influences numerous functions in the gastrointestinal tract. We previously demonstrated that 5-HT treatment of Caco-2 cells inhibited Na(+)/H(+) exchangers (NHE) and Cl(-)/OH(-) exchange activities via distinct signaling mechanisms. Since regulation of several ion transporters such as NHE3 is influenced by intact cytoskeleton, we hypothesized that 5-HT modifies actin cytoskeleton and/or brush-border membrane architecture via involvement of signaling pathways. Ultrastructural analysis showed that 5-HT (0.1 muM, 1 h) treatment of Caco-2 cells caused the apical membrane to assume a convex dome shape that was associated with shortening of microvilli. To examine whether these cellular architecture changes are cytoskeleton driven, we analyzed actin cytoskeleton by fluorescence microscopy. 5-HT induced basal stress fibers with prominent cortical actin filaments via 5-HT3 and 5-HT4 receptor subtypes. This induction was partially attenuated by chelation of intracellular Ca(2+) and PKCalpha inhibition (Go6976). In vitro assays revealed that PKCalpha interacted with actin and this association was increased by 5-HT. Our data provide novel evidence that 5-HT-induced signaling via 5-HT3/4 receptor subtypes to cause Ca(2+) and PKCalpha-dependent regulation of actin cytoskeleton may play an important role in modulation of ion transporters that contribute to pathophysiology of diarrheal conditions associated with elevated levels of 5-HT.

Protein Kinase Cα Determines HER2 Fate in Breast Carcinoma Cells with HER2 Protein Overexpression without Gene Amplification

In some HER2-positive breast tumors, cell surface overexpression of HER2 is not associated with gene amplification but may instead rest in altered gene transcription, half-life, or recycling of the oncoprotein. Here, we show that HER2 overexpression in HER2 2+ carcinomas is associated with neither an increase in gene transcription nor a deregulation in the ubiquitin-dependent pathways, but instead seems to be regulated by protein kinase Calpha (PKCalpha) activity. The stimulation of PKCalpha up-regulated HER2 expression, whereas PKCalpha inhibition by pharmacologic treatments and PKCalpha-specific small interfering RNA led to a dramatic down-regulation of HER2 levels only in breast cancer cells HER2 2+. Consistent with the in vitro data, our biochemical analysis of HER2 2+ human primary breast specimens revealed significantly higher levels of phosphorylated PKCalpha compared with HER2-negative tumors. Inhibition of HER2 activation by the tyrosine kinase inhibitor lapatinib led to decreased levels of PKCalpha phosphorylation, clearly indicating a cross-talk between PKCalpha and HER2 molecules. These data suggest that HER2 overexpression in HER2 2+ carcinomas is due to an accumulation of the recycled oncoprotein to the cell surface induced by activated PKCalpha.

Response to Field

We read with interest the commentary (1) accompanying our article (2) in the October issue of the JCI. We appreciate Michael Field’s opinion that based on our data, the concept of secretory diarrhea must be revised to include the idea that net water secretion, or diarrhea, can occur in the absence of active ion secretion. However, we disagree with his conclusion that TNF must affect capillary permeability or smooth muscle contractility to generate increased interstitial pressure and a hydraulic driving force for water secretion. In contrast to Field’s suggestion, our study of 2 TNF superfamily members, TNF and LIGHT (lymphotoxin-like inducible protein that competes with glycoprotein D for herpesvirus entry mediator on T cells), demonstrates that water secretion occurs as a consequence of epithelial Na+ malabsorption and increased epithelial paracellular permeability. This is supported by the observation that although TNF and LIGHT cause quantitatively similar paracellular permeability increases, only TNF causes diarrhea. The key difference that accounts for this is that only TNF activates PKCα, thereby inhibiting Na+/H+ exchanger isoform 3 (NHE3); TNF did not induce diarrhea when PKCα-mediated NHE3 inhibition was prevented by either pharmacological inhibitors or PKCα knockout. Could these approaches to PKCα inhibition have also prevented PKCα-dependent changes in capillary permeability or smooth muscle contractility? To test this we took advantage of the observation that LIGHT does not activate PKCα. LIGHT did cause diarrhea when PKC was activated pharmacologically, confirming that LIGHT was fully able to recapitulate TNF-like diarrhea when coupled with PKC activation. More importantly, direct NHE3 inhibition, either pharmacological or genetic, showed that this was the critical second component necessary for LIGHT to cause diarrhea. This was not due to inhibition of endothelial or smooth muscle NHE3, since neither tissue expresses NHE3. The unmistakable conclusion is that the necessary role of PKCα in TNF-induced diarrhea is to inhibit epithelial NHE3 and not to effect changes in capillary permeability or smooth muscle contractility. Why, then, is NHE3 so critical? Is it simply that Na+ absorption provides an osmotic driving force for water absorption? This alone is an inadequate explanation, as inhibition of absorption is not necessarily equivalent to induction of secretion. We propose that loss of NHE3-mediated Na+ absorption results in dissipation of the normal hyperosmolarity of the upper villus that drives water absorption (3). It then follows that increased paracellular permeability allows Na+ to leak from tissue to lumen; without NHE3, Na+ cannot be reabsorbed. Increased epithelial paracellular permeability may also allow water and other solutes to flow into the lumen, thereby compounding loss of the villous osmotic gradient that drives water absorption. In terms of absorption, the model gains further support from the observation that LIGHT-induced increases in permeability enhance water absorption (when NHE3 is active). Thus, this model fully explains the data without the need to invoke increased interstitial pressure to force water through paracellular or transcellular water channels. Is it therefore impossible for elevated interstitial pressure, secondary to increased capillary permeability or smooth muscle contraction, to contribute to TNF-induced diarrhea? It is not. However, if elevated venous or interstitial pressure were able to cause diarrhea by the mechanism proposed by Yablonski and Lifson (4) that is cited by Field (1), it is surprising that diarrhea is not a common clinical characteristic of patients with portal hypertension and that jejunal water and electrolyte transport are normal in these patients (5). We therefore conclude that TNF causes acute diarrhea via myosin light chain kinase–dependent increases in epithelial paracellular permeability coupled with PKCα-dependent NHE3 inhibition. Although intriguing as a hypothesis, no data support the role of increased interstitial pressure physically squeezing water into the lumen as proposed by Field. However, existing models of epithelial transport do provide an ample explanation for the observed synergy between increased epithelial paracellular permeability and Na+ malabsorption.

Involvement of PKCα in insulin-induced PKCδ expression: Importance of SP-1 and NFκB transcription factors

Protein kinase C delta (PKCδ) is a key molecule in insulin signaling essential for insulin-induced glucose transport in skeletal muscle. Recent studies in our laboratory have shown that insulin rapidly stimulates PKCδ activity and increases PKCδ protein and RNA levels, and that the SP-1 transcription factor is involved in insulin-induced transcription of the PKCδ gene. Activation of SP-1 involves serine phosphorylation and translocation to the nucleus. In this study we examined the possibility that PKCα might be involved in serine phosphorylation and activation of SP-1. We found that insulin rapidly phosphorylates and translocates SP-1. In the cytoplasm, SP-1 was constitutively associated with PKCα, and insulin stimulation caused these proteins to dissociate. In contrast, in the nucleus insulin induced an increase in association between PKCα and SP-1. PKCα inhibition blocked insulin-induced serine phosphorylation of SP-1 and its association with PKCα in the nucleus. Inhibition of PKCα also reduced the insulin-induced increase in PKCδ RNA and protein in the cytoplasmic and nuclear fractions. We also attempted to determine if another transcription factor might be involved in regulation of PKCδ expression. We earlier showed that insulin did not affect nuclear NFκB levels. Inhibition of NFκB, however, increased insulin-induced increase in PKCδ RNA and protein in the cytoplasmic and nuclear fractions. Surprisingly, this inhibition reduced the insulin-induced increase in cytoplasmic and nuclear PKCα RNA and protein. Inhibition of PKCδ reduced IκBα phosphorylation as well as NFκB activation. Thus, PKCα regulates insulin-induced PKCδ expression levels and this regulation involves activation of SP-1 and NFκB.

612 POSTER Acquired resistance to drugs that yield PKCδ activation and PKCα inhibition modify adhesion and invasion in human cancer cells

612 POSTER Acquired resistance to drugs that yield PKCδ activation and PKCα inhibition modify adhesion and invasion in human cancer cells

Protein kinase C-α mediates epidermal growth factor receptor transactivation in human prostate cancer cells

Progression of human prostate cancer to a malignancy that is refractory to androgen-ablation therapy renders the disease resistant to available treatment options and accounts for the high prostate cancer mortality rate. Epidermal growth factor receptor (EGFR) expression in human prostate cancer specimens increases with disease progression to androgen-refractory prostate cancer, and experimental models implicate EGFR-dependent signaling to Erk1/2 activation in the androgen-refractory prostate cancer phenotype. 12-O-Tetradecanoylphorbol-13-acetate (TPA)-induced Erk1/2 activation in human prostate cancer PC-3 cells is a paradigm of diacylglycerol-induced EGFR transactivation in androgen-independent prostate cancer. In this report, we establish an obligatory role for TPA-induced protein kinase C (PKC)-alpha activation in EGFR transactivation and signaling to Erk1/2 activation in PC-3 cells. TPA-regulated molecules include PKCs, PKDs, and Ras guanyl nucleotide-releasing proteins. The PKC-selective inhibitors GF109203X and Go6983 each blocked TPA-induced EGFR transactivation, indicating a requirement for PKC. PC-3 cells express four PKC isozymes. Prolonged bryostatin 1 treatment abrogated PKCalpha expression without altering expression levels of the other PKC isozymes. Pharmacologic PKCalpha "knockdown" abrogated TPA-induced Erk1/2 activation without affecting the EGF/EGFR-induced response, indicating that PKCalpha was required for EGFR transactivation but dispensable for signaling of ligand-activated EGFR to Erk1/2 activation. We corroborated this by showing that Go6976, which is a PKCalpha-selective inhibitor in PC-3 cells, likewise abolished TPA-induced Erk1/2 activation and did not inhibit EGF/EGFR-induced Erk1/2 activation. Go6976 had similar effects in DU145 cells, providing evidence for a common PKCalpha-dependent Erk1/2 activation mechanism in androgen-independent human prostate cancer cells of distinct genetic origin. These results constitute a rational basis for selective PKCalpha inhibition as a modality of prostate cancer therapy.

Functional Interaction of Protein Kinase Cα with the Tyrosine Kinases Syk and Src in Human Platelets

There is a high degree of cross-talk between tyrosine phosphorylation and the serine/threonine phosphorylation signaling pathways. Here we show a physical and functional interaction between the classical protein kinase C isoform (cPKC), PKCalpha, and two major nonreceptor tyrosine kinases in platelets, Syk and Src. In the presence of the cPKC-selective inhibitor Go6976, platelet 5-hydroxytryptamine release was abolished in response to co-activation of glycoproteins VI and Ib-IX-V by the snake venom alboaggregin A, whereas platelet aggregation was substantially inhibited. Of the two platelet cPKCs, PKCalpha but not PKCbeta was activated, occurring in an Syk- and phospholipase C-dependent manner. Syk and PKCalpha associate in a stimulation-dependent manner, requiring Syk but not PKC activity. PKCalpha and Syk also co-translocate from the cytosol to the plasma membrane upon platelet activation, in a manner dependent upon the activities of both kinases. Although PKCalpha is phosphorylated on tyrosine downstream of Syk, we provide evidence against phosphorylation of Syk by PKCalpha, consistent with a lack of effect of PKCalpha inhibition on Syk activity. PKCalpha also associates with Src; although in contrast to interaction with Syk, PKCalpha activity is required for the association of these kinases but not the stimulation-induced translocation of Src to the cell membrane. Finally, the activity of Src is negatively regulated by PKC, as shown by potentiation of Src activity in the presence of the PKC inhibitors GF109203X or Go6976. Therefore, there is a complex interplay between PKCalpha, Syk, and Src involving physical interaction, phosphorylation, translocation within the cell, and functional activity regulation.

Protein Kinase Cα-Mediated Chemotaxis of Neutrophils Requires NF-κB Activity but Is Independent of TNFα Signaling in Mouse Skin In Vivo

Protein kinase C (PKC) isoforms are major regulators of cutaneous homeostasis and mediate inflammation in response to 12-O-tetradecanoylphorbol-13-acetate (TPA). We have previously reported that transgenic mice overexpressing PKCalpha in the skin exhibit severe intraepidermal neutrophilic inflammation and keratinocyte apoptosis when treated topically with TPA. Activation of PKCalpha increases the production of TNFalpha and the transcription of chemotactic factors (MIP-2, KC, S100A8/A9), vascular endothelial growth factor, and GM-CSF in K5-PKCalpha keratinocytes. In response to PKCalpha activation, NF-kappaB translocates to the nucleus and this is associated with IkappaB phosphorylation and degradation. Preventing IkappaB degradation reduces both the expression of inflammation-associated genes and chemoattractant release. To determine whether TNFalpha mediated NF-kappaB translocation and subsequent expression of proinflammatory factors, K5-PKCalpha mice were treated systemically with a dimeric soluble form of p75 TNFR (etanercept) or crossed with mice deficient for both TNFR isoforms, and keratinocytes were cultured in the presence of TNFalpha-neutralizing Abs. The in vivo treatment and TNFR deficiency did not prevent inflammation, and the in vitro treatment did not prevent NF-kappaB nuclear translocation after TPA. Together these results implicate PKCalpha as a regulator of a subset of cutaneous cytokines and chemokines responsible for intraepidermal inflammation independent of TNFalpha. PKCalpha inhibition may have therapeutic benefit in some human inflammatory skin disorders.

Protein kinase Calpha negatively regulates systolic and diastolic function in pathological hypertrophy.

The protein kinase C (PKC) family is implicated in cardiac hypertrophy, contractile failure, and beta-adrenergic receptor (betaAR) dysfunction. Herein, we describe the effects of gain- and loss-of-PKCalpha function using transgenic expression of conventional PKC isoform translocation modifiers. In contrast to previously studied PKC isoforms, activation of PKCalpha failed to induce cardiac hypertrophy, but instead caused betaAR insensitivity and ventricular dysfunction. PKCalpha inhibition had opposite effects. Because PKCalpha is upregulated in human and experimental cardiac hypertrophy and failure, its effects were also assessed in the context of the Galphaq overexpression model (in which PKCalpha is transcriptionally upregulated). Normalization (inhibition) of PKCalpha activity in Galpha(q) hearts improved systolic and diastolic function, whereas further activation of PKCalpha caused a lethal restrictive cardiomyopathy with marked interstitial fibrosis. These results define pathological roles for PKCalpha as a negative regulator of ventricular systolic and diastolic function.

Alpha-Tocopherol specifically inactivates cellular protein kinase C alpha by changing its phosphorylation state.

The mechanism of protein kinase C (PKC) regulation by alpha-tocopherol has been investigated in smooth-muscle cells. Treatment of rat aortic A7r5 smooth-muscle cells with alpha-tocopherol resulted in a time- and dose-dependent inhibition of PKC. The inhibition was not related to a direct interaction of alpha-tocopherol with the enzyme nor with a diminution of its expression. Western analysis demonstrated the presence of PKCalpha, beta, delta, epsilon, zeta and micro isoforms in these cells. Autophosphorylation and kinase activities of the different isoforms have shown that only PKCalpha was inhibited by alpha-tocopherol. The inhibitory effects were not mimicked by beta-tocopherol, an analogue of alpha-tocopherol with similar antioxidant properties. The inhibition of PKCalpha by alpha-tocopherol has been found to be associated with its dephosphorylation. Moreover the finding of an activation of protein phosphatase type 2A in vitro by alpha-tocopherol suggests that this enzyme might be responsible for the observed dephosphorylation and subsequent deactivation of PKCalpha. It is therefore proposed that PKCalpha inhibition by alpha-tocopherol is linked to the activation of a protein phosphatase, which in turn dephosphorylates PKCalpha and inhibits its activity.

Downregulation of Protein Kinase C Suppresses Induction of Apoptosis in Human Prostatic Carcinoma Cells

Protein kinase C (PKC) has been implicated in propagating signals for apoptosis. We have investigated the effect of pharmacological modulation of PKC activity in DU-145 human androgen-independent prostatic carcinoma cells. The apoptotic death of these cells is characterized by the acquisition of classical apoptotic morphology and generation of ≥1-mbp and 450- to 600-kbp DNA fragments in attached preapoptotic cell populations prior to cellular detachment and accrual of 30- to 50-kbp DNA fragments. We found that induction of apoptosis was arrested by downregulation of PKC activity and not by transient activation or inhibition of the enzyme. Concentrations and durations of exposure to phorbol esters that downregulated PKC activity correlated with inhibition of VP-16 or melphalan-induced morphological apoptosis and generation of the 30- to 50-kbp DNA fragments. Chronic exposure to phorbol-12,13-dibutyrate (PDBu) did not, however, suppress production of the ≥1-mbp and 450- to 600-kbp DNA fragments found in preapoptotic cell populations, suggesting that PKC downregulation may interfere with the transition between a preapoptotic cell and an apoptotic cell. PKC isozyme analysis revealed that chronic PDBu treatment caused downregulation of PKC-α and -ϵ in DU-145 cells. Using concentrations of the PKC inhibitor UCN-01 that were consistent with PKC-α inhibition (but not PKC-ϵ inhibition), however, did not mimic the effects of chronic PDBu treatment, implying that downregulation of PKC-ϵ may be of particular importance. Together, these findings suggest that phorbol esters may act as tumor promoters by suppressing apoptosis.