Antagonistic Effects of Protein Kinase C alpha  and delta  on Both Transformation and Phospholipase D Activity Mediated by the Epidermal Growth Factor Receptor

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Molecular and Cellular Biology, November 1999, p. 7672-7680, Vol. 19, No. 11
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Antagonistic Effects of Protein Kinase C $alpha$ and $delta$ on Both Transformation and Phospholipase D Activity Mediated by the Epidermal Growth Factor Receptor

Armand Hornia, Zhimin Lu, Taiko Sukezane, Minghao Zhong, Troy Joseph, Paul Frankel, and David A. Foster^*

Department of Biological Sciences, Hunter College of The City University of New York, New York, New York 10021

Received 13 August 1998/Returned for modification 4 November 1998/Accepted 23 June 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Downregulation of protein kinase C $delta$ (PKC $delta$ ) by treatment with the tumor-promoting phorbol ester 12-O-tetradecanoylphorbol-13-acetate(TPA) transforms cells that overexpress the non-receptor classtyrosine kinase c-Src (Z. Lu et al., Mol. Cell. Biol. 17:3418-3428,1997). We extended these studies to cells overexpressing a receptorclass tyrosine kinase, the epidermal growth factor (EGF) receptor(EGFR cells); like c-Src, the EGF receptor is overexpressed inseveral human tumors. In contrast with expectations, downregulationof PKC isoforms with TPA did not transform the EGFR cells; however,treatment with EGF did transform these cells. Since TPA downregulatesall phorbol ester-responsive PKC isoforms, we examined the effectsof PKC $delta$ - and PKC $alpha$ -specific inhibitors and the expression ofdominant negative mutants for both PKC $delta$ and $alpha$ . Consistent witha tumor-suppressing function for PKC $delta$ , the PKC $delta$ -specific inhibitorrottlerin and a dominant negative PKC $delta$ mutant transformed theEGFR cells in the absence of EGF. In contrast, the PKC $alpha$ -specificinhibitor Go6976 and expression of a dominant negative PKC $alpha$ mutantblocked the transformed phenotype induced by both EGF and PKC $delta$ inhibition. Interestingly, both rottlerin and EGF induced substantialincreases in phospholipase D (PLD) activity, which is commonlyelevated in response to mitogenic stimuli. The elevation of PLDactivity in response to inhibiting PKC $delta$ , like transformation,was dependent upon PKC $alpha$ and restricted to the EGFR cells. Thesedata demonstrate that PKC isoforms $alpha$ and $delta$ have antagonistic effectson both transformation and PLD activity and further support atumor suppressor role for PKC $delta$ that may be mediated by suppressionof tyrosine kinase-dependent increases in PLDactivity.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The conversion of a normal cell to a transformed cell is a progressive process whereby successive rounds of mutation (initiation)and selected amplification (promotion) of the initiated cellsresult in an amplified population of partially transformed cells.Within the amplified population of partially transformed cellsadditional mutations may occur that provide a further selectiveadvantage to a single member of clonally amplified cells. Thisprocess selects for cells with more aggressive growth properties,resulting in the generation of cells with a more aggressive malignantphenotype. Substances that stimulate the amplification of incompletelytransformed cells are known as tumor promoters, and while notinducing directly the genetic changes that ultimately result ina malignant tumor, they dramatically speed up the process by generatinglarge populations of initiated cells that are subject to furthermutation (6, 46-48). Epigenetic factors, such as diet, hormones,and cigarette smoke, have all been reported to have tumor-promotingproperties and contribute in poorly understood ways to tumorprogression.

Members of our group recently reported that rat fibroblasts overexpressing the non-receptor tyrosine kinase c-Src become transformedupon treatment with the tumor-promoting phorbol ester 12-O-tetradecanoylphorbol-13-acetate(TPA) (23). In this cell culture model, TPA was able to inducethe amplification of cells containing an initiating mutation (c-Srcoverexpression) and therefore functioned very much like a tumorpromoter in vitro. The tumor-promoting effect of TPA was determinedto be due to the depletion of the $delta$ isoform of protein kinaseC (PKC) (23). Other studies also suggest that PKC $delta$ negativelyregulates cell division (4, 15-17, 19, 31, 44). PKC $delta$ has been shown to negatively affect the Jak-Stat signaling pathway,which is frequently activated in response to cell division signals(34). Phospholipase D (PLD) activity, which is elevated in responseto mitogenic signals, was stimulated by the downregulation ofPKC in cells overexpressing c-Src (23), suggesting that PKC $delta$ may also negatively regulate PLD activity. However, the activationof PLD by the mitogenic signals induced by both platelet-derivedgrowth factor and epidermal growth factor (EGF) has been reportedto be dependent on PKC (32, 45). PKC $alpha$ has been implicatedas an activator of PLD; however, it may be independent of itsown kinase activity (36). Thus, a role for PLD in mitogenicsignals may be complex and involve differential effects of differentisoforms. Collectively, these data suggest that PKC $delta$ negativelyregulates cell division by suppressing mitogenic signals and areconsistent with PKC $delta$ having a tumor-suppressing effect that islost when PKC $delta$ is downregulated. In this report, we describethe antagonistic effects of PKC $alpha$ and $delta$ on both transformationand PLD activity in cells that overexpress the EGF receptor (EGFRcells); like c-Src, the EGF receptor is implicated in many humancancers (2, 27, 28).

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cells and cell culture conditions. Rat 3Y1 cells or rat 3Y1 EGFR cells were maintained in Dulbecco's modified Eagle medium (DMEM) supplemented with 10% bovinecalf serum (HyClone) as described previously (23, 49). Cellcultures were made quiescent by growing them to confluence andthen replacing the medium with fresh medium containing 0.5% bovinecalf serum for 1 day. For growth of cells in soft agar, 10³ cells were suspended in top agar (DMEM, 20% calf serum, and 0.38%agar) and overlaid onto hardened bottom agar (DMEM, 20% calf serum,and 0.7% agar) as described previously (33).

Transfection. Cells were plated at a density of 10⁵/100-mm-diameter dish 18 h prior to transfection. Transfections were performed by usingLipofectamine reagent (GIBCO) according to the vendor's instructions.Transfected cultures were selected with either puromycin (5 µg/ml)or hygromycin (200 µg/ml) for 10 to 14 days at 37°C. At that timeantibiotic-resistant colonies were picked and expanded for furtheranalysis under selectiveconditions.

Materials. The PKC inhibitors rottlerin and Go6976 were obtained from Calbiochem. Monoclonal antibodies to the EGF receptor and PKC $alpha$ were obtained from Transduction Laboratories, and a polyclonalantibody for PKC $delta$ was obtained from Santa Cruz Biotechnology.pCEP4, which contains the hygromycin resistance gene, was obtainedfromInvitrogen.

Western analysis. Extraction of proteins from cultured cells was performed as previously described (23, 24). Equal amounts of protein weresubjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresiswith an 8% acrylamide separating gel, transferred to nitrocellulose,and blocked overnight at 4°C with 5% nonfat dry milk mixed withisotonic phosphate-buffered saline (PBS; 136 mM NaCl, 2.6 mM KCl,1.4 mM KH₂PO₄, 4.2 mM Na₂HPO₄). The nitrocellulose filters werewashed three times for 5 min in PBS and then incubated with antibodiesas described below. Depending upon the origin of the primary antibodies,either anti-mouse or anti-rabbit immunoglobulin G was used fordetection with the ECL system(Amersham).

PLD assays. Confluent 35-mm-diameter culture dishes were prelabeled for 4 h with 3 µCi of [³H]myristate (40 Ci/mmol) in 3 ml of medium containing 0.5% newborncalf serum. PLD-catalyzed transphosphatidylation in the presenceof 1% butanol was performed as described previously (37, 38).Extraction and characterization of lipids by thin-layer chromatographywere performed as previously described (38).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

3Y1 EGFR cells display a transformed phenotype upon treatment with EGF, but not TPA. 3Y1 rat fibroblasts were stably transfected with a plasmid (pPEGFr) containing a puromycin resistance marker gene and theEGF receptor gene under the control of the simian virus 40 promoter(5). EGF receptor overexpression was verified by Western analysisof several puromycin-resistant clones as shown in Fig. 1. Clone2 expressed the highest levels of the EGF receptor and was usedfor most subsequent experiments. Upon establishment of EGFR cells,we examined the effects of both long-term TPA treatment and EGFon the morphology of these cells. In Fig. 2a, it is shown thatthe EGFR cells (clone 2) had a flat nontransformed morphologylike that of the parental 3Y1 cells. In response to EGF, the EGFRcells took on a refractile morphology characteristic of transformation(Fig. 2a). This morphological change was observed in the otherEGFR clones as well, indicating that the ability of EGF to inducethis phenotype was not restricted to the clonal EGFR cell lineshown (data not shown). However, in contrast with expectations,TPA treatment did not cause a transformed morphology as observedpreviously with c-Src-overexpressing cells (23). We next investigatedthe ability of EGFR cells to form colonies in soft agar, and asshown in Fig. 2b, EGF, but not TPA, induced anchorage-independentgrowth. The ability of the EGFR cells to form colonies in softagar in the presence of EGF correlated well with the level ofexpression of the EGF receptor. Clone 3, which expressed low levelsof the receptor, and clone 4, which expressed intermediate levelsthe receptor (Fig. 1), formed low and intermediate numbers ofcolonies in response to EGF relative to the numbers expressedby clone 2 (Fig. 2c). The inability of TPA to induce the transformedphenotype was not due to a lack of PKC isoform downregulation,since this treatment resulted in the same rapid degradation ofPKC isoforms as reported previously (23, 24) (data not shown).These data indicate that downregulation of PKC isoforms in responseto TPA does not have the same effect in EGFR cells as observedpreviously for cells overexpressing the non-receptor tyrosinekinase c-Src (23).

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FIG. 1. Establishment of 3Y1 EGFR cells. 3Y1 cells were transfected with pPEGFr, which expresses the EGF receptor from the simian virus 40 promoter and contains a puromycin resistance marker (5). Several puromycin-resistent colonies were picked and analyzed for levels of expression of the EGF receptor. Western blot analysis was performed on lysates from the parental 3Y1 cells (3Y1) and the puromycin-resistant colonies with an antibody raised against the EGF receptor.

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FIG. 2. EGFR cells display a transformed phenotype upon treatment with EGF but not TPA. (a) Parental 3Y1 or EGFR cells were either left untreated or treated with TPA (400 nM) or EGF (100 ng/ml) for 24 h, at which time the morphology of the cells was examined. (b) Anchorage-independent growth of the EGFR cells (clone 2) was examined in the presence or absence of either TPA (400 nM) or EGF (100 ng/ml) as shown. TPA and EGF were replenished every 4 days. A total of 10³ cells were suspended in soft agar, and the percentage of cells that formed colonies was determined 3 weeks later. (c) Anchorage-independent growth of 3Y1 cells and 3Y1 EGFR cells (clones 2, 3, and 4) was examined in the presence of EGF (100 ng/ml) as described for panel b.

Differential effects of PKC $alpha$ and $delta$ on EGF receptor-mediated transformation. The inability of prolonged TPA treatment to induce a transformed phenotype in the EGFR cells could be due to a requirementfor one of the PKC isoforms depleted by the TPA treatment forthe EGF receptor to induce a mitogenic signal. To investigatethis possibility, we employed inhibitors of PKC that were specificfor PKC $alpha$ and PKC $delta$ . It was demonstrated previously that activationof PKC isoforms was required for ubiquitination and downregulationin 3Y1 cells and that Go6976 (29) specifically inhibited PKC $alpha$ downregulation and rottlerin (18) specifically inhibited PKC $delta$ downregulation (24). Thus, these two inhibitors were ableto distinguish PKC $alpha$ and $delta$ requirements in these cells. We examinedthe effects of these two compounds on anchorage-independent growthin the EGFR and parental 3Y1 cells. Go6976 strongly inhibitedboth EGF-induced and background colony formation in the EGFR cells(Fig. 3a), indicating a PKC $alpha$ requirement for EGF-induced mitogenicsignals. Rottlerin, on the other hand, stimulated colony formationof the EGFR cells in the absence of EGF and increased the numberof colonies formed in soft agar in the presence of EGF (Fig. 3b).Rottlerin did not induce colony formation in the parental 3Y1cells (data not shown). Consistent with its inducing a transformedphenotype in the EGFR cells, rottlerin also caused a transformedmorphology in the EGFR cells in the absence of EGF (Fig. 3c).The effect of rottlerin on colony formation was also seen in EGFRclones 3 and 4, which expressed low and intermediate levels ofthe EGF receptor, and the number of colonies correlated with thelevel of EGF receptor expression (Fig. 3d). Consistent with theinability of prolonged TPA treatment to induce a transformed phenotypein the EGFR cells, Go6976 inhibited the rottlerin-induced transformedmorphology (Fig. 3c). These data indicate that inhibition of PKC $delta$ specifically has a tumor-promoting effect similar to that reportedpreviously for cells overexpressing c-Src (23). However, incontrast to c-Src, the EGF receptor has a PKC $alpha$ requirement formitogenesis that explains why TPA treatment, which downregulatesboth PKC $alpha$ and $delta$ , does not cause transformation of EGFR cells.

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FIG. 3. Effects of PKC $alpha$ - and $delta$ -specific inhibitors on EGFR cells. EGFR cells were treated with EGF (100 ng/ml) and either Go6976 (0.5 µM) or rottlerin (15 µM) and then examined for the ability to form colonies in soft agar as described for Fig. 2b. (c) The EGFR cells were treated with EGF (100 ng/ml), rottlerin (15 µM), Go6976 (0.5 µM), or TPA (400 nM) as shown, and the morphology of the cells was examined 24 h later as for Fig. 2a. (d) The ability of rottlerin to stimulate colony formation in EGFR clones 2, 3, and 4 was determined as described for panel a.

To further establish that the effects of the PKC-specific inhibitors Go6976 and rottlerin were due to effects on PKC $alpha$ andPKC $delta$ , respectively, we introduced dominant negative mutants ofPKC $alpha$ and $delta$ into the EGFR cells. These mutants both have a conservedLys in the ATP binding site converted to Ala and have been shownpreviously to act as dominant negative mutants for PKC $alpha$ and $delta$ (20, 22, 23, 42). Expression of the dominant negativePKC $alpha$ and $delta$ mutants was verified by taking advantage of the previousdemonstration that PKC downregulation in response to TPA is dependentupon an active kinase (24). Two cell lines transfected witheither the kinase-dead PKC $alpha$ or $delta$ were treated with TPA for 24h, and the levels of PKC $alpha$ and $delta$ were then determined by Westernblot analysis. As shown in Fig. 4a, both PKC $alpha$ and $delta$ were degradedby TPA treatment to below the level of detection in the parentalEGFR cells. In contrast, PKC $alpha$ and $delta$ levels in the two cell linesexpressing the dominant negative PKC $delta$ were reduced only by abouthalf, indicating that the kinase-dead dominant negative PKC mutantswere expressed. Having established that the dominant negativePKC $delta$ was expressed, we next examined the ability of cells toform colonies in soft agar in the presence and absence of EGF.As expected, the dominant negative PKC $alpha$ inhibited EGF-inducedcolony formation and the cells expressing the dominant negativePKC $delta$ now formed colonies in soft agar in the absence of EGF (Fig.4b). There was also a correlation between colony number and thelevel of expression of the dominant negative PKC $delta$ , with cloneB expressing higher levels of the PKC $delta$ mutant (Fig. 4a) and alsoforming more colonies. Expression of the dominant negative PKC $delta$ mutant did not increase the number of colonies induced by EGFtreatment (Fig. 4b), indicating that activation of the EGF receptoris able to overcome the inhibitory effects of PKC $delta$ (see Discussion).

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FIG. 4. Effects of dominant negative (DN) mutants of PKC $alpha$ and $delta$ on the ability of EGFR cells to form colonies in soft agar. (a) EGFR cells were cotransfected with plasmids expressing either a dominant negative PKC $alpha$ or $delta$ mutant and pCEF4 (Invitrogen), which expresses a hygromycin resistance marker gene. One clone expressing the PKC $alpha$ mutant and two clones expressing different levels of the PKC $delta$ mutant were analyzed for expression of the mutants by Western blot analysis before and after treatment with TPA (400 nM, 24 h). TPA treatment downregulates the endogenous wild-type PKC $alpha$ and $delta$ , but not the kinase-dead mutants (24). (b) The ability of the EGFR cells and the EGFR cell lines expressing the dominant negative PKC $alpha$ and $delta$ mutants to form colonies in soft agar was determined as for Fig. 3 in the presence and absence of EGF (100 ng/ml) as shown.

Differential effects of PKC $alpha$ and $delta$ on PLD activity in EGFR cells. Members of our group reported previously that in cells overexpressing c-Src, downregulation of PKC isoforms with prolongedtreatment with TPA resulted in an increase in PLD activity (23).We therefore examined the effect of PKC downregulation by TPAon PLD activity in EGFR and parental 3Y1 cells in the presenceand absence of EGF. Activation of PLD by EGF has been reportedpreviously (39, 45), and consistent with these reports, EGFstrongly elevated PLD activity in the EGFR cells, between six-and eightfold (Fig. 5a). Downregulation of PKC isoforms with prolongedTPA treatment had no dramatic effect on the PLD activity in eitherEGF-treated or untreated 3Y1 or EGFR cells (Fig. 5a), suggestingthat the EGF-induced PLD activity in these cells was independentof PKC. The role of PKC in the activation of PLD in response toEGF has been controversial. A dependence upon PKC was found infibroblasts (45) but not in A431 human epidermoid carcinomacells (39). The transformed phenotype induced by EGF was inhibitedby the PKC $alpha$ inhibitor Go6976 and enhanced by the PKC $delta$ inhibitorrottlerin. Thus, it is possible that downregulation of all PKCisoforms by TPA treatment could have inhibitory and stimulatoryeffects on PLD activity that would neutralize each other. We thereforeexamined the effects of the PKC isoform-specific inhibitors Go6976and rottlerin on the PLD activity in the EGFR cells. The PKC $alpha$ -specificinhibitor Go6976 reduced the EGF-induced increase in PLD activityto approximately the level seen with the inhibitor alone (Fig.5b). The PKC $delta$ inhibitor rottlerin stimulated PLD activity inthe EGFR cells to an even higher level than that observed in responseto EGF (Fig. 5b). Rottlerin did not substantially elevate PLDactivity in the parental 3Y1 cells (data not shown), indicatingthat the effect may be restricted to the partially transformedEGFR cells. Nor did EGF substantially further elevate PLD activityin the rottlerin-treated cells (Fig. 5b), indicating that theeffect may be on the same population of PLD molecules activatedin response to EGF. These data suggest that PKC $alpha$ is a positiveregulator of EGF-induced PLD activity and that PKC $delta$ is a negativeregulator of PLD activity.

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FIG. 5. Downregulation of PKC $delta$ elevates PLD activity in EGFR cells. (a) Parental 3Y1 and EGFR cells were treated with EGF (100 ng/ml, 5 min) and/or TPA (400 nM, 24 h) in the presence of 1% butanol, and PLD activity was determined by examining the levels of the PLD-generated transphosphatidylation product phosphatidylbutanol as described in Materials and Methods. The relative PLD activity was normalized to the PLD activity in the untreated 3Y1 cells. Error bars represent the standard deviations for two independent experiments performed in duplicate. (b) The effects of the PKC $alpha$ - and $delta$ -specific inhibitors Go6976 (0.5 µM) and rottlerin (15 µM) on EGF-induced PLD activity were determined as for panel a. The relative PLD activity was normalized to the PLD activity in the untreated EGFR cells. (c) EGFR cells expressing dominant negative (DN) mutants of PKC $alpha$ and $delta$ were examined for the effect on PLD activity in the presence and absence of EGF as shown. The relative PLD activity was normalized to the PLD activity in the untreated EGFR cells. Error bars represent the standard deviations for two independent experiments performed in duplicate, where duplicates varied by less than 10%.

We next examined the PLD activity in the EGFR cell lines expressing the dominant negative PKC mutants described for Fig. 4.If PKC $alpha$ is required for EGF-induced PLD activity, as suggestedby the data in Fig. 5b, then EGF-induced PLD activity should bereduced in the EGFR cells expressing the dominant negative PKC $alpha$ , and as shown in Fig. 5c, that is exactly what was observed.EGF-induced PLD activity dropped from sevenfold to twofold. Itwas also anticipated that the EGFR cells expressing the dominantnegative PKC $delta$ would have an elevated basal level of PLD activitythat could not be substantially elevated by EGF. And as shownin Fig. 5c, the basal PLD activity was elevated about eightfoldrelative to that of the parental EGFR cells and EGF did not significantlyelevate the PLD activity further. These data are consistent withthe results obtained with the PKC isoform-specific inhibitorsand further indicate a PKC $alpha$ requirement for EGF-induced PLD activityand an inhibitory effect for PKC $delta$ on PLD activity in the EGFRcells that is lost upon downregulation or inhibition. The effectsof the $alpha$ and $delta$ PKC isoforms on PLD activity in the EGFR cellsmirror exactly the effects of these isoforms on transformationof thesecells.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this report, we have shown that in EGFR cells, inhibition of PKC $delta$ results in a transformed phenotype. This suggests atumor-suppressing effect for PKC $delta$ that is lost upon inhibition.The addition of EGF to EGFR cells led to a transformed phenotypethat was dependent upon PKC $alpha$ . The ability of EGF to induce atransformed phenotype in the absence of PKC $delta$ downregulation suggeststhat upon EGF treatment, the inhibitory effects of PKC $delta$ can beovercome. In this regard, it was shown previously that in responseto EGF, PKC $delta$ becomes phosphorylated on tyrosine, leading to areduction of PKC $delta$ kinase activity (8). Thus, the ability ofEGF to overcome the negative effects of PKC $delta$ may be due to theability to stimulate tyrosine phosphorylation of PKC $delta$ . This isvery similar to the differential abilities of v-Src and c-Srcto transform cells. 3Y1 cells overexpressing c-Src are not transformed;however, downregulation of PKC $delta$ results in the transformationof these cells (23). The same cells overexpressing v-Src arealready transformed, but interestingly, PKC $delta$ associates withv-Src in these cells and becomes phosphorylated on tyrosine andthe tyrosine-phosphorylated PKC $delta$ leads to reduced PKC $delta$ kinaseactivity (50) and reduced PKC $delta$ protein levels (3). A correlationbetween tyrosine phosphorylation of PKC $delta$ and reduced levels ofPKC $delta$ kinase activity was also observed in cells transformed byv-Ras (7). Thus, there is apparently a mechanism whereby PKC $delta$ can be downregulated through tyrosine phosphorylation in responseto cell division signals that allows cells to overcome the negativeregulatory effects of PKC $delta$ .

It is possible that some of the effects of EGF receptor overexpression are mediated by c-Src. c-Src phosphorylates the EGFreceptor at Tyr845, and this phosphorylation is required for EGF-inducedDNA synthesis (41). The EGF receptor also phosphorylates c-Src.Thus, there is an intimate and complex relationship between theEGF receptor and c-Src, in which the EGF receptor functions bothupstream and downstream of c-Src. Our previous studies with c-Srcoverexpression were done with cells that do not express detectablelevels of the EGF receptor, indicating that the effect of overexpressedc-Src were not mediated by the EGF receptor. Thus, while c-Srcmay play some role in the effects mediated by EGF receptor overexpression,the EGF receptor did not play a role in the effects mediated byc-Src overexpression. Thus, inhibition of PKC $delta$ has tumor-promotingeffects in cells with different initiatingmutations.

The data presented here and previously (23, 50) suggest a model where overexpression of c-Src or the EGF receptor primesa cell for division; however, cell division is blocked by PKC $delta$ . This is similar conceptually to a model proposed several yearsago by Stiles et al. where resting cells needed both "competence"and "progression" factors to leave the resting stage of the cellcycle (G₀) and traverse G₁ into S phase (40). Thus, overexpressionof c-Src or the EGF receptor is postulated to act as a competencefactor which either prevents entrance into the resting (G₀) stateor facilitates exit from G₀. Inhibition of PKC $delta$ , which allowsfor the traversing of G₁, is then postulated to be a progressionfactor. In the tumor promotion model, inhibition or depletionof the tumor-suppressing PKC $delta$ allows cell cycle progression and,therefore, the amplification of the initiated (c-Src- or EGF receptor-overexpressing)cells. In these two models for the regulation of cell proliferation,promotion and progression are similar in that they facilitatepassage through G₁ into S phase. Most of the characterized tumorsuppressor genes also affect cell cycle progression through aG₁/S cell cycle checkpoint. The genes encoding p53, p21^cip, p27, members of the p16^ink family, and retinoblastoma protein are the best studied in whatis being called a tumor suppressor pathway (35). It has beensuggested that a defect in this tumor-suppressing pathway, whichblocks cell cycle progression in late G₁, is essential for allhuman tumors (35). Members of our group have found that in serum-starvedcells overexpressing c-Src, inhibition of PKC $delta$ results in anincrease in DNA synthesis that can be detected as soon as 3 hafter treatment (reference 23 and our unpublished observations).This rapid induction of DNA synthesis by PKC $delta$ inhibition suggeststhat, in the absence of serum, at least some of the c-Src-overexpressingcells are blocked in late G₁ and that inhibiting PKC $delta$ facilitatespassage through this checkpoint into S phase. Consistent withthis hypothesis, PKC $delta$ was recently reported to suppress expressionof the G₁ cyclins D1 and E (15), which facilitate passage fromG₁ to S. Thus, PKC $delta$ may be another regulator of this tumor-suppressingpathway that allows progression through the G₁/S cell cycle checkpoint.Overexpression of PKC $delta$ in CHO cells led to an accumulation ofcells in G₂/M upon TPA treatment (44), indicating that PKC $delta$ may negatively regulate cell cycle progression at multiplepoints.

The role of PLD in cell cycle regulation is poorly understood; however, PLD activity is elevated in response to most, if notall, mitogenic stimuli (12, 13). RalA, a small GTPase whichinteracts directly with PLD1 (26), is required for v-Src-inducedPLD activity (21, 26). RalA is also required for the transformationof fibroblasts in culture by Ras and Raf (43) and for the formationof tumors in mice (1). We have also found that RalA is requiredfor the transformed phenotype induced by EGF in EGFR cells (25).The finding here that downregulation or inhibition of PKC $delta$ inthe EGFR cells leads to substantial increases in PLD activityis consistent with a role for PLD in the cell cycle progressionstimulated by inhibition of PKC $delta$ . It is not clear how PKC $delta$ downregulationresults in the elevation of PLD activity. However, since phosphorylationof the EGF receptor by PKC negatively regulates receptor function(10, 11, 14, 30), it is possible that the loss of PKC $delta$ -mediated inhibition of the EGF receptor could lead to the observedincrease in PLD activity that may in some as-yet-undeterminedway contribute to cell cycleprogression.

It was demonstrated previously (23) that cells overexpressing c-Src become transformed upon treatment with TPA, which downregulatesboth PKC $alpha$ and $delta$ . However, as demonstrated here, EGFR cells donot become transformed upon TPA treatment. This is presumablydue to the requirement of PKC $alpha$ for both EGF-induced transformationand PLD activity. Interestingly, the activation of PLD by Src,in contrast with the activation of PLD by EGF, is independentof PKC $alpha$ (23, 38). Thus, the PKC $alpha$ requirement for EGF-inducedPLD activity may explain the differential effect of long-termTPA treatment on the transformed phenotype in cells overexpressingc-Src and in EGFR cells. The role that PKC $alpha$ plays in the transformedphenotype and in PLD activity mediated by the EGF receptor isnot clear. PKC $alpha$ activates PLD directly in vitro and, surprisingly,is kinase independent (36). The dominant negative PKC $alpha$ usedin these studies to inhibit the PLD activity is kinase defective,suggesting that PKC $alpha$ kinase activity is required. Additionally,several reports have described ligand-induced PLD activity thatis sensitive to PKC inhibitors that block kinase activity (13).The role that PKC $alpha$ plays in the activation of PLD observed hereis apparently dependent upon the kinase activity of PKC $alpha$ andis therefore not likely to act on PLDdirectly.

The differential effects of PKC $alpha$ and $delta$ upon PLD activity likely explain previously reported discrepancies in the dependenceof EGF-induced PLD activity upon PKC (39, 45). Downregulationof all phorbol ester-responsive isoforms by TPA would be expectedto have both inhibitory and stimulatory effects upon PLD activityin EGFR cells. And as reported here for EGFR fibroblasts and previouslyfor human epidermoid carcinoma A431 cells, which also overexpressthe EGF receptor (45), downregulation of PKC isoforms with TPAhad little or no effect on PLD activity. However, as shown here,the PKC $alpha$ -specific inhibitor Go6976 blocked EGF-induced PLD activityvery effectively. These data are also consistent with previousreports implicating PKC $alpha$ as an activator of PLD activity in vitro(36) and with a requirement for PKC in the activation of PLDby EGF as reported by Yeo and Exton (45). The apparent lackof a PKC requirement for EGF-induced PLD activity seen in theA431 cells was likely due to both stimulatory and inhibitory effectsof downregulating all phorbol ester-responsive PKC isoforms withTPA.

Overexpression of a tyrosine kinase is a common genetic alteration in human cancers (9). This kind of genetic change doesnot by itself result in a tumor. This initiating event does, however,give the cell a selective growth advantage over other cells inthe presence of promoting substances that suppress the proteinsthat prevent cell cycle progression. In this report, we have presentedfurther evidence that inhibition of PKC $delta$ is sufficient to stimulateanchorage-independent growth of cells overexpressing a receptorclass tyrosine kinase, which is common in human tumors. Li etal. recently reported that PKC $delta$ was required for transformationinduced by the insulin-like growth factor I receptor (22). Thissuggests the possibility that PKC $delta$ may also have positive rolesin regulating cell division in response to other stimuli. However,the data presented here and previously (23) suggest that suppressionof PKC $delta$ by substances that either inhibit or downregulate PKC $delta$ can enhance the promotion phase of tumor progression in cellsin which either c-Src or the EGF receptor is overexpressed. Itwill be important to determine whether epigenetic events, suchas diet, hormones, and cigarette smoke, are able to either inhibitor downregulate PKC $delta$ such that cells containing mutations thatelevate tyrosine kinase activity would be amplified and thereforesubject to progression to a more cancerousphenotype.

	ACKNOWLEDGMENTS

A.H. and Z.L. contributed equally to thiswork.

We thank Sergey Beychenok and Henghe Tian for comments on the manuscript. We thank Renato Baserga and Stuart Decker for providingEGF receptor expression plasmids and Shigeo Ohno for providingthe vectors expressing the PKC $alpha$ and PKC $delta$ kinase-deadmutants.

This investigation was supported by grants from the National Institutes of Health (CA46677) and from the American Cancer Society(BE-243) (to D.A.F.) and by a Research Centers in Minority Institutions(RCMI) award from the Division of Research Resources, NationalInstitutes of Health (RR-03037), to HunterCollege.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biological Sciences, Hunter College of The City University of New York,695 Park Ave., New York, NY 10021. Phone: (212) 772-4075. Fax:(212) 772-5227. E-mail: foster{at}genectr.hunter.cuny.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Aguirre Ghiso, J., P. Frankel, Z. Lu, H. Jiang, E. Farías, A. Olsen, L. A. Feig, E. Bal de Kier Joffé, and D. A. Foster. RalA requirement for v-Src- and v-Ras-induced tumorigenicity and overproduction of urokinase-type plasminogen activator and metalloproteases. Oncogene, in press.

2. Biscardi, J. S., A. P. Belsches, and S. J. Parsons. 1998. Characterization of human epidermal growth factor receptor and c-Src interactions in human breast tumor cells. Mol. Carcinog. 21:261-272[Medline].

3. Blake, R. A., P. Garcia-Paramio, P. J. Parker, and S. A. Courtneidge. 1999. Src promotes PKC $delta$ degradation. Cell Growth Differ. 10:231-241[Abstract/Free Full Text].

4. Borner, C., M. Ueffing, S. Jaken, P. J. Parker, and I. B. Weinstein. 1995. Two closely related isoforms of protein kinase C produce reciprocal effects on the growth of rat fibroblasts. J. Biol. Chem. 270:78-86[Abstract/Free Full Text].

5. Collins, K., T. Jacks, and N. P. Pavletich. 1997. The cell cycle and cancer. Proc. Natl. Acad. Sci. USA 94:2776-2778[Free Full Text].

6. Coppola, D., A. Ferber, M. Miura, C. Sell, C. D'Ambrosio, R. Rubin, and R. Baserga. 1994. A functional insulin-like growth factor I receptor is required for the mitogenic and transforming activities of the epidermal growth factor receptor. Mol. Cell. Biol. 14:4588-4595[Abstract/Free Full Text].

7. Decker, S. J. 1984. Effects of epidermal growth factor and 12-O-tetradecanoylphorbol-13-acetate on metabolism of the epidermal growth factor receptor in normal human fibroblasts. Mol. Cell. Biol. 4:1718-1724[Abstract/Free Full Text].

8. Denning, M. F., A. A. Dlugosz, M. K. Howett, and S. H. Yuspa. 1993. Expression of an oncogenic ras^Ha gene in murine keratinocytes induces tyrosine phosphorylation and reduced activity of protein kinase C $delta$ . J. Biol. Chem. 268:26079-26081[Abstract/Free Full Text].

9. Denning, M. F., A. A. Dlugosz, D. W. Threadgill, T. Magnuson, and S. H. Yuspa. 1996. Activation of the epidermal growth factor receptor signal transduction pathway stimulates tyrosine phosphorylation of protein kinase C $delta$ . J. Biol. Chem. 271:5325-5331[Abstract/Free Full Text].

10. Dickson, R. B., D. S. Salomon, and M. E. Lippman. 1992. Tyrosine kinase receptor-nuclear protooncogene interactions in breast cancer. Cancer Treat. Res. 61:249-273[Medline].

11. Dingiovanni, J. 1992. Multistage carcinogenesis in mouse skin. Pharmacol. Ther. 54:63-128[Medline].

12. Downward, J., M. D. Waterfield, and P. J. Parker. 1985. Autophosphorylation and protein kinase C phosphorylation of the epidermal growth factor receptor. Effect on tyrosine kinase activity and ligand binding affinity. J. Biol. Chem. 260:14538-14546[Abstract/Free Full Text].

13. Exton, J. H. 1998. Phospholipase D. Biochim. Biophys. Acta 1436:105-115[Medline].

14. Foster, D. A. 1993. Intracellular signalling mediated by protein-tyrosine kinases: networking through phospholipid metabolism. Cell. Signal. 5:389-399[Medline].

15. Friedman, B., A. R. Frackelton, A. H. Ross, J. M. Connors, H. Fujiki, T. Sugimora, and M. R. Rosner. 1984. Tumor promoters block tyrosine-specific phosphorylation of the epidermal growth factor receptor. Proc. Natl. Acad. Sci. USA 81:3034-3038[Abstract/Free Full Text].

16. Fukumoto, S., Y. Nishizawa, M. Hosoi, H. Koyama, K. Yamakawa, S. Ohno, and H. Morii. 1997. Protein kinase C $delta$ inhibits the proliferation of vascular smooth muscle cells by suppressing G1 cyclin expression. J. Biol. Chem. 272:13816-13822[Abstract/Free Full Text].

17. Goode, N. T., M. A. Hajibagheri, G. Warren, and P. J. Parker. 1994. Expression of mammalian protein kinase C in Schizosaccharomyces pombe: isotype-specific induction of growth arrest, vesicle formation, and endocytosis. Mol. Biol. Cell 5:907-920[Abstract].

18. Griffiths, G., B. Garrone, E. Deacon, P. Owen, J. Pongracz, G. Mead, A. Bradwell, D. Watters, and J. Lord. 1996. The polyether bistratene A activates protein kinase C- $delta$ and induces growth arrest in HL60 cells. Biochem. Biophys. Res. Commun. 222:802-808[Medline].

19. Gschwendt, M., H.-J. Muller, K. Kielbassa, R. Zang, W. Kittstein, G. Rincke, and F. Marks. 1994. Rottlerin, a novel protein kinase inhibitor. Biochem. Biophys. Res. Commun. 199:63-98[Medline].

20. Hirai, S., Y. Izumi, K. Higa, K. Kaibuchi, K. Mizuno, S. Osada, K. Suzuki, and S. Ohno. 1994. Ras-dependent signal transduction is indispensable but not sufficient for the activation of AP1/Jun by PKC $delta$ . EMBO J. 13:2331-2340[Medline].

21. Jiang, H., J.-Q. Luo, T. Urano, Z. Lu, D. A. Foster, and L. Feig. 1995. Involvement of Ral GTPase in v-Src-induced phospholipase D activation. Nature 378:409-412[Medline].

22. Li, W., Y.-X. Jiang, J. Zhang, L. Soon, L. Flechner, V. Kapoor, J. H. Pierce, and L.-H. Wang. 1998. Protein kinase C- $delta$ is an important signaling molecule in insulin-like growth factor I receptor-mediated cell transformation. Mol. Cell. Biol. 18:5888-5898[Abstract/Free Full Text].

23. Lu, Z., A. Hornia, Y.-W. Jiang, Q. Zang, S. Ohno, and D. A. Foster. 1997. Tumor promotion by depleting cells of protein kinase C $delta$ . Mol. Cell Biol. 17:3418-3428[Abstract].

24. Lu, Z., D. Liu, A. Hornia, W. Devonish, M. Pagano, and D. A. Foster. 1998. Activation of protein kinase C triggers its ubiquitination and degradation. Mol. Cell. Biol. 18:839-845[Abstract/Free Full Text].

25. Lu, Z., A. Hornia, T. Sukezane, M. Zhong, T. Joseph, P. Frankel, L. A. Feig, and D. A. Foster. Ras-mediated activation of RalA/phospholipase D pathway is required for the growth-promoting effects of EGF. Submitted for publication.

26. Luo, J.-Q., X. Liu, S. M. Hammond, W. C. Colley, L. A. Feig, M. A. Frohman, A. J. Morris, and D. A. Foster. 1997. Ral interacts directly with the Arf-responsive PIP2-dependent phospholipase D1. Biochem. Biophys. Res. Commun. 235:854-859[Medline].

27. Luttrell, D. K., A. Lee, T. J. Lansing, R. M. Crosby, K. D. Jung, D. Willard, M. Luther, M. Rodriguez, J. Berman, and T. M. Gilmer. 1994. Involvement of pp60^c-src with two major signaling pathways in human breast cancer. Proc. Natl. Acad. Sci. USA 91:83-87[Abstract/Free Full Text].

28. Mao, W., R. Irby, D. Coppola, L. Fu, M. Wloch, J. Turner, H. Yu, R. Garcia, R. Jove, and T. J. Yeatman. 1997. Activation of c-Src by receptor tyrosine kinases in human colon cancer cells with high metastatic potential. Oncogene 15:3083-3090[Medline].

29. Martiny-Baron, G., M. G. Kazanietz, H. Mischak, P. M. Blumberg, G. Kochs, H. Hug, D. Marme, and C. Schachtele. 1993. Selective inhibition of protein kinase C isozymes by the indolocarbazole Go 6976. J. Biol. Chem. 268:9194-9197[Abstract/Free Full Text].

30. McCaffrey, P. G., B. Friedman, and M. R. Rosner. 1984. Diacylglycerol modulates binding and phosphorylation of the epidermal growth factor receptor. J. Biol. Chem. 259:12502-12507[Abstract/Free Full Text].

31. Mischak, H., J. A. Goodnight, W. Kolch, G. Martiny-Baron, C. Schachtle, M. G. Kazanietz, P. M. Blumberg, J. H. Pierce, and J. F. Mushinski. 1993. Overexpression of protein kinase C- $delta$ and - $varepsilon$ in NIH 3T3 cells induces opposite effects on growth, morphology, anchorage dependence, and tumorigenicity. J. Biol. Chem. 268:6090-6096[Abstract/Free Full Text].

32. Plevin, R., S. G. Cook, S. Palmer, and M. J. O. Wakelam. 1991. Multiple sources of sn-1,2-diacylglycerol in platelet-derived-growth factor-stimulated Swiss 3T3 fibroblasts. Biochem. J. 279:559-565.

33. Qureshi, S. A., C. K. Joseph, R. Gupta, M. Hendrickson, J. Song, J. Bruder, U. R. Rapp, and D. A. Foster. 1993. A dominant-negative Raf-1 mutant prevents v-Src-induced transformation. Biochem. Biophys. Res. Commun. 192:969-975[Medline].

34. Saharinen, P., N. Ekman, K. Sarvas, P. Parker, K. Alitalo, and O. Silvennoinen. 1997. The Bmx tyrosine kinase induces activation of the Stat signaling pathway, which is specifically inhibited by protein kinase C $delta$ . Blood 90:4341-4353[Abstract/Free Full Text].

35. Sherr, C. J. 1996. Cancer cell cycles. Science 274:1672-1677[Abstract/Free Full Text].

36. Singer, W. D., H. A. Brown, X. Jiang, and P. C. Sternweis. 1996. Regulation of phospholipase D by protein kinase C is synergistic with ADP-ribosylation factor and independent of protein kinase activity. J. Biol. Chem. 271:4504-4510[Abstract/Free Full Text].

37. Song, J., L. M. Pfeffer, and D. A. Foster. 1991. v-Src increases diacylglycerol levels via a type D phospholipase-mediated hydrolysis of phosphatidylcholine. Mol. Cell. Biol. 11:4903-4908[Abstract/Free Full Text].

38. Song, J., and D. A. Foster. 1993. v-Src activates a phospholipase D activity that is distinguishable from phospholipase D activity activated by protein kinase C. Biochem. J. 294:711-717.

39. Song, J., Y.-W. Jiang, and D. A. Foster. 1994. EGF induces the production of biologically distinguishable diglyceride species from phosphatidylinositol and phosphatidylcholine: evidence for the independent activation of type C and type D phospholipases. Cell Growth Differ. 5:79-85[Abstract].

40. Stiles, C. D., G. T. Capone, C. D. Scher, H. N. Antoniades, J. J. Van Wyk, and W. J. Pledger. 1979. Dual control of cell growth by somatomedins and platelet-derived growth factor. Proc. Natl. Acad. Sci. USA 76:1279-1283[Abstract/Free Full Text].

41. Tice, D. A., J. S. Biscardi, A. L. Nickles, and S. J. Parsons. 1999. Mechanism of biological synergy between cellular Src and epidermal growth factor receptor. Proc. Natl. Acad. Sci. USA 96:1415-1420[Abstract/Free Full Text].

42. Ueda, Y., S. Hirai, S. Osada, A. Suzuku, K. Mizuno, and S. Ohno. 1996. Protein kinase C $delta$ activates the MEK-ERK pathway in a manner independent of Ras and dependent on Raf. J. Biol. Chem. 271:23512-23519[Abstract/Free Full Text].

43. Urano, T., R. Emkey, and L. A. Feig. 1996. Ral GTPases mediate a distinct downstream signaling pathway from Ras that facilitates cellular transformation. EMBO J. 16:810-816.

44. Watanabe, T., Y. Ono, Y. Taniyama, K. Hazama, K. Igarashi, K. Ogita, U. Kikkawa, and Y. Nishizuka. 1992. Cell division arrest induced by phorbol ester in CHO cells overexpressing protein kinase C- $delta$ subspecies. Proc. Natl. Acad. Sci. USA 89:10159-10163[Abstract/Free Full Text].

45. Yeo, E. J., and J. H. Exton. 1995. Stimulation of phospholipase D by epidermal growth factor requires protein kinase C activation in Swiss 3T3 cells. J. Biol. Chem. 270:3980-3988[Abstract/Free Full Text].

46. Yuspa, S. H., and M. C. Poirier. 1988. Chemical carcinogenesis: from animal models to molecular models in one decade. Adv. Cancer Res. 50:25-70[Medline].

47. Yuspa, S. H., A. A. Dlugosz, C. K. Cheng, M. F. Denning, T. Tennenbaum, A. B. Glick, and W. C. Weinberg. 1994. Role of oncogenes and tumor suppressor genes in multistage carcinogenesis. J. Investig. Dermatol. 103:90S-95S[Medline].

48. Yuspa, S. H. 1998. The pathogenesis of squamous cell cancer: lessons learned from studies of skin carcinogenesis. J. Dermatol. Sci. 17:1-7[Medline].

49. Zang, Q., P. Frankel, and D. A. Foster. 1995. Selective activation of protein kinase C isoforms by v-Src. Cell Growth Differ. 6:1367-1373[Abstract].

50. Zang, Q., Z. Lu, M. Curto, N. Barile, D. Shalloway, and D. A. Foster. 1997. Interaction between v-Src and protein kinase C $delta$ in v-Src-transformed fibroblasts. J. Biol. Chem. 272:13275-13280[Abstract/Free Full Text].

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1.	Aguirre Ghiso, J., P. Frankel, Z. Lu, H. Jiang, E. Farías, A. Olsen, L. A. Feig, E. Bal de Kier Joffé, and D. A. Foster. RalA requirement for v-Src- and v-Ras-induced tumorigenicity and overproduction of urokinase-type plasminogen activator and metalloproteases. Oncogene, in press.
2.	Biscardi, J. S., A. P. Belsches, and S. J. Parsons. 1998. Characterization of human epidermal growth factor receptor and c-Src interactions in human breast tumor cells. Mol. Carcinog. 21:261-272[Medline].
3.	Blake, R. A., P. Garcia-Paramio, P. J. Parker, and S. A. Courtneidge. 1999. Src promotes PKC $delta$ degradation. Cell Growth Differ. 10:231-241[Abstract/Free Full Text].
4.	Borner, C., M. Ueffing, S. Jaken, P. J. Parker, and I. B. Weinstein. 1995. Two closely related isoforms of protein kinase C produce reciprocal effects on the growth of rat fibroblasts. J. Biol. Chem. 270:78-86[Abstract/Free Full Text].
5.	Collins, K., T. Jacks, and N. P. Pavletich. 1997. The cell cycle and cancer. Proc. Natl. Acad. Sci. USA 94:2776-2778[Free Full Text].
6.	Coppola, D., A. Ferber, M. Miura, C. Sell, C. D'Ambrosio, R. Rubin, and R. Baserga. 1994. A functional insulin-like growth factor I receptor is required for the mitogenic and transforming activities of the epidermal growth factor receptor. Mol. Cell. Biol. 14:4588-4595[Abstract/Free Full Text].
7.	Decker, S. J. 1984. Effects of epidermal growth factor and 12-O-tetradecanoylphorbol-13-acetate on metabolism of the epidermal growth factor receptor in normal human fibroblasts. Mol. Cell. Biol. 4:1718-1724[Abstract/Free Full Text].
8.	Denning, M. F., A. A. Dlugosz, M. K. Howett, and S. H. Yuspa. 1993. Expression of an oncogenic ras^Ha gene in murine keratinocytes induces tyrosine phosphorylation and reduced activity of protein kinase C $delta$ . J. Biol. Chem. 268:26079-26081[Abstract/Free Full Text].
9.	Denning, M. F., A. A. Dlugosz, D. W. Threadgill, T. Magnuson, and S. H. Yuspa. 1996. Activation of the epidermal growth factor receptor signal transduction pathway stimulates tyrosine phosphorylation of protein kinase C $delta$ . J. Biol. Chem. 271:5325-5331[Abstract/Free Full Text].
10.	Dickson, R. B., D. S. Salomon, and M. E. Lippman. 1992. Tyrosine kinase receptor-nuclear protooncogene interactions in breast cancer. Cancer Treat. Res. 61:249-273[Medline].
11.	Dingiovanni, J. 1992. Multistage carcinogenesis in mouse skin. Pharmacol. Ther. 54:63-128[Medline].
12.	Downward, J., M. D. Waterfield, and P. J. Parker. 1985. Autophosphorylation and protein kinase C phosphorylation of the epidermal growth factor receptor. Effect on tyrosine kinase activity and ligand binding affinity. J. Biol. Chem. 260:14538-14546[Abstract/Free Full Text].
13.	Exton, J. H. 1998. Phospholipase D. Biochim. Biophys. Acta 1436:105-115[Medline].
14.	Foster, D. A. 1993. Intracellular signalling mediated by protein-tyrosine kinases: networking through phospholipid metabolism. Cell. Signal. 5:389-399[Medline].
15.	Friedman, B., A. R. Frackelton, A. H. Ross, J. M. Connors, H. Fujiki, T. Sugimora, and M. R. Rosner. 1984. Tumor promoters block tyrosine-specific phosphorylation of the epidermal growth factor receptor. Proc. Natl. Acad. Sci. USA 81:3034-3038[Abstract/Free Full Text].
16.	Fukumoto, S., Y. Nishizawa, M. Hosoi, H. Koyama, K. Yamakawa, S. Ohno, and H. Morii. 1997. Protein kinase C $delta$ inhibits the proliferation of vascular smooth muscle cells by suppressing G1 cyclin expression. J. Biol. Chem. 272:13816-13822[Abstract/Free Full Text].
17.	Goode, N. T., M. A. Hajibagheri, G. Warren, and P. J. Parker. 1994. Expression of mammalian protein kinase C in Schizosaccharomyces pombe: isotype-specific induction of growth arrest, vesicle formation, and endocytosis. Mol. Biol. Cell 5:907-920[Abstract].
18.	Griffiths, G., B. Garrone, E. Deacon, P. Owen, J. Pongracz, G. Mead, A. Bradwell, D. Watters, and J. Lord. 1996. The polyether bistratene A activates protein kinase C- $delta$ and induces growth arrest in HL60 cells. Biochem. Biophys. Res. Commun. 222:802-808[Medline].
19.	Gschwendt, M., H.-J. Muller, K. Kielbassa, R. Zang, W. Kittstein, G. Rincke, and F. Marks. 1994. Rottlerin, a novel protein kinase inhibitor. Biochem. Biophys. Res. Commun. 199:63-98[Medline].
20.	Hirai, S., Y. Izumi, K. Higa, K. Kaibuchi, K. Mizuno, S. Osada, K. Suzuki, and S. Ohno. 1994. Ras-dependent signal transduction is indispensable but not sufficient for the activation of AP1/Jun by PKC $delta$ . EMBO J. 13:2331-2340[Medline].
21.	Jiang, H., J.-Q. Luo, T. Urano, Z. Lu, D. A. Foster, and L. Feig. 1995. Involvement of Ral GTPase in v-Src-induced phospholipase D activation. Nature 378:409-412[Medline].
22.	Li, W., Y.-X. Jiang, J. Zhang, L. Soon, L. Flechner, V. Kapoor, J. H. Pierce, and L.-H. Wang. 1998. Protein kinase C- $delta$ is an important signaling molecule in insulin-like growth factor I receptor-mediated cell transformation. Mol. Cell. Biol. 18:5888-5898[Abstract/Free Full Text].
23.	Lu, Z., A. Hornia, Y.-W. Jiang, Q. Zang, S. Ohno, and D. A. Foster. 1997. Tumor promotion by depleting cells of protein kinase C $delta$ . Mol. Cell Biol. 17:3418-3428[Abstract].
24.	Lu, Z., D. Liu, A. Hornia, W. Devonish, M. Pagano, and D. A. Foster. 1998. Activation of protein kinase C triggers its ubiquitination and degradation. Mol. Cell. Biol. 18:839-845[Abstract/Free Full Text].
25.	Lu, Z., A. Hornia, T. Sukezane, M. Zhong, T. Joseph, P. Frankel, L. A. Feig, and D. A. Foster. Ras-mediated activation of RalA/phospholipase D pathway is required for the growth-promoting effects of EGF. Submitted for publication.
26.	Luo, J.-Q., X. Liu, S. M. Hammond, W. C. Colley, L. A. Feig, M. A. Frohman, A. J. Morris, and D. A. Foster. 1997. Ral interacts directly with the Arf-responsive PIP2-dependent phospholipase D1. Biochem. Biophys. Res. Commun. 235:854-859[Medline].
27.	Luttrell, D. K., A. Lee, T. J. Lansing, R. M. Crosby, K. D. Jung, D. Willard, M. Luther, M. Rodriguez, J. Berman, and T. M. Gilmer. 1994. Involvement of pp60^c-src with two major signaling pathways in human breast cancer. Proc. Natl. Acad. Sci. USA 91:83-87[Abstract/Free Full Text].
28.	Mao, W., R. Irby, D. Coppola, L. Fu, M. Wloch, J. Turner, H. Yu, R. Garcia, R. Jove, and T. J. Yeatman. 1997. Activation of c-Src by receptor tyrosine kinases in human colon cancer cells with high metastatic potential. Oncogene 15:3083-3090[Medline].
29.	Martiny-Baron, G., M. G. Kazanietz, H. Mischak, P. M. Blumberg, G. Kochs, H. Hug, D. Marme, and C. Schachtele. 1993. Selective inhibition of protein kinase C isozymes by the indolocarbazole Go 6976. J. Biol. Chem. 268:9194-9197[Abstract/Free Full Text].
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Antagonistic Effects of Protein Kinase C and on Both Transformation and Phospholipase D Activity Mediated by the Epidermal Growth Factor Receptor

Antagonistic Effects of Protein Kinase C $alpha$ and $delta$ on Both Transformation and Phospholipase D Activity Mediated by the Epidermal Growth Factor Receptor