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Estrogen-Dependent Rapid Activation of Protein Kinase C in Estrogen Receptor-Positive MCF-7 Breast Cancer Cells and Estrogen Receptor-Negative HCC38 Cells Is Membrane-Mediated and Inhibited by Tamoxifen

Wallace H. Coulter Department of Biomedical Engineering (B.D.B., Z.S.), Georgia Institute of Technology, Atlanta, Georgia 30332; Departments of Periodontics (Z.S.) and Orthopaedics (V.L.S., D.D.D.), University of Texas Health Science Center at San Antonio, San Antonio, Texas 78229; Department of Gynecology (T.F., J.D.), University of Würzburg, 97070 Würzburg, Germany; Department of Orthopedics (C.H.L.), University of Eppendorf, 20255 Hamburg, Germany; and Department of Periodontics (Z.S.), Hebrew University Hadassah, Jerusalem 91120, Israel

Address all correspondence and requests for reprints to: Barbara D. Boyan, Ph.D., Wallace H. Coulter Department of Biomedical Engineering at Georgia Tech and Emory University, Georgia Institute of Technology, 315 Ferst Drive NW, Atlanta, Georgia 30332. E-mail: Barbara.Boyan{at}bme.gatech.edu.

	Abstract

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We examined protein kinase C (PKC) in the regulation of breast cancer cells by estrogen. Estrogen receptor (ER)- positive (+) MCF-7 and ER-negative (-) HCC38 cells were treated with 17ß-estradiol (E₂) or E₂-BSA, which cannot enter the cell. E₂ and E₂-BSA rapidly increased PKC- in both cells via phosphatidylinositol-dependent phospholipase C and G protein, but not phospholipase A₂ or arachidonic acid. In MCF-7 cells, E₂ and E₂-BSA had comparable effects, maximal at 90 min. In HCC38 cells, PKC was maximal at 9 min, with E₂-BSA more than E₂. Tamoxifen blocked estrogen-dependent PKC in MCF-7 cells and reduced it in HCC38 cells. ER-antagonist ICI 182780, ER-agonist diethylstilbestrol, and antibodies to ER and ERß had no effect. E₂ stimulated [³H]thymidine incorporation in MCF-7 only; E₂-BSA had no effect. Tamoxifen did not alter E₂-dependent increases in MCF-7 cells, whereas ICI 182780 reduced DNA synthesis in control and E₂-treated cultures. PKC activity was positively correlated with tumor severity in 133 breast cancer specimens and was greater in ER(-) tumors. Tamoxifen treatment reduced recurrence, and recurrent tumors had higher PKC activity. This indicates that E₂ rapidly increases PKC activity via membrane pathways not involving ER or ERß and suggests that tamoxifen works by reducing PKC activity through non-ER/ERß-dependent mechanisms.

	Introduction

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PROTEIN KINASE C (PKC) activity is elevated in breast cancer tissues (1, 2), suggesting an association with tumorigenicity. Most studies examining the relationship between PKC and breast cancer measured activity of the isoform of the enzyme (PKC; Refs.3 and4). MCF-7 breast cancer cells transfected with PKC are more neoplastic (5), supporting the hypothesis that this isoform is related to tumorigenicity. Other PKC isoforms may play a role as well. NIH 3T3 fibroblasts transfected with PKC-I cDNA display enhanced tumorigenicity (6), and rat embryos overproducing PKCß1 have growth abnormalities (7). Recent studies have shown that PKC is also regulated by estrogen in human breast cancer cells (8).

PKC is involved in intracellular signaling. It has been associated with epidermal growth factor signaling in both estrogen receptor (ER)-positive (+) and ER-negative (-) breast cancer cell lines (9). In chondrocytes (10) and human colon cancer cells (11), 17ß-estradiol (E₂) rapidly increases PKC specific activity without new gene expression or protein synthesis. In rat costochondral cartilage cells, E₂-dependent increases in PKC activity involve G protein and phosphatidylinositol-specific phospholipase C (PI-PLC; Ref. 12); activated PKC is then translocated to the plasma membrane. Plasma membrane fluidity is altered by E₂ as well (13). Neither PKC activation nor altered membrane fluidity is caused by the stereoisomer 17-estradiol, indicating that these rapid effects of E₂ are stereospecific and suggesting that they are receptor-mediated.

Although recent reports suggest that ER and ERß may be present in plasma membranes (14), they may not be responsible for the effect of E₂ on PKC. In rat costochondral growth plate cartilage cells, neither the ER agonist diethylstilbestrol nor the ER antagonist ICI 182780 blocks the action of E₂ on enzyme activity (15). Moreover, ERs are present in chondrocytes from female and male rats (16), but rapid changes in membrane fluidity and increased PKC are only observed in cells from female rats (10, 13). Others have reported that rapid responses to E₂ in MCF-7 breast cancer cells may also not be due to traditional ER-mediated events (17, 18, 19).

The membrane action of E₂ is supported by studies using E₂-BSA, because the conjugated form of the hormone cannot enter the cell (20). In rat chondrocytes (21) and human osteoblasts (22), E₂-BSA elicits many of the same effects as E₂, including PKC activation. In addition, inhibition of PKC blocks some of the physiological responses of chondrocytes to E₂ and E₂-BSA (21), indicating the importance of this signaling pathway in the mechanism of estrogen’s action.

The existence of a membrane-associated receptor for E₂ may explain the success of agents like tamoxifen in treatment of both ER(+) and ER(-) breast cancers (23), because tamoxifen is a potent PKC inhibitor (24). Additional support for this hypothesis is found in the vitamin D literature, where tamoxifen was shown to inhibit the rapid effect of 1,25(OH)₂D₃ and 24R,25(OH)₂D₃ on PKC in rat chondrocytes in a gender-neutral manner (25). Thus, the effect of tamoxifen may not be specific to traditional ERs, but to PKC, which is the isoform sensitive to the action of these regulatory agents (10). Whether this is the case for breast cancer cells is not known.

To better understand the relationship between the ability of tamoxifen to inhibit PKC and its success in the treatment of breast cancer, we used a cell culture model. We examined E₂ and E₂-BSA regulation of PKC activity in ER(+) MCF-7 cells (26) and ER(-) HCC38 cells (27) in the presence and absence of tamoxifen. We also measured PKC activity in extracts of breast cancer tissue from 133 female patients. Data were stratified as a function of tumor size and type, degree of malignancy, histological evidence of nuclear ERs, and treatment regimen and outcome. Tamoxifen may also exert its effects through calmodulin (28, 29), although the importance of this pathway is not yet clear (30). The role of calmodulin in PKC regulation in breast cancer cells, in response to either tamoxifen or estrogen, was not examined in the present study.

	Materials and Methods

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Cell culture model
Two breast cancer cell lines were used as models. MCF-7 cells express traditional nuclear ERs (26). HCC38 cells lack these ERs (27). Both cells lines were purchased from the American Type Culture Collection (Manassas, VA). The presence or absence of ER and ERß was verified by RT-PCR using total RNA isolated from confluent cultures with TRIzol reagent (Life Technologies, Inc., Carlsbad, CA). Primer sets were based on published sequences (31): ER sense, 5'-AAGGAGACTCGCTACTGT-3' (nt 762–769), and antisense, 5'-TCAAAGATCTCCACCATGCC-3' (nt 1482–1501); ERß sense, 5'-GTTGTGCCAGCCCTGTTACT-3' (nt 683–702), and antisense, 5'-CGTTTCTCTTGGCTTTGCTC-3' (nt 1014–1033). Primers were synthesized by the Center for Advanced DNA Technologies (The University of Texas Health Science Center, San Antonio, TX). RNA was reverse-transcribed using the First Strand CDNA synthesis kit (Pharmacia Biotech, Piscataway, NJ) and sequenced by the Center for Advanced DNA Technologies. Rat ovary total RNA (1 µg; Ambion, Inc., Austin, TX) was used as a positive control template for both receptors. The expected product sizes were 740 bp (ER) and 351 bp (ERß). Sequences of the RT-PCR products were confirmed by direct comparison with published rat ER and ERß sequences. Northern blot analysis was performed to confirm the RT-PCR findings and to provide a quantitative assessment of the amounts of mRNA for each receptor in MCF-7 and HCC38 cells.

Western blot analysis of cell culture lysates determined whether the cells synthesized ER and/or ERß. For these experiments, cells were lysed in sample buffer, and the proteins present in the lysates were separated on 4–20% gradient acrylamide gels. Blots of the gels were probed with either rabbit polyclonal antibodies to ER (H-184, Santa Cruz Biotechnology, Inc., Santa Cruz, CA; 1:200 dilution) or with goat polyclonal antibodies to ERß1 (N-19, Santa Cruz Biotechnology, Inc.; 1:100 dilution). Control blots were probed with nonspecific rabbit IgG or goat IgG at the same dilution used for the antibodies. Immunoreactive bands were visualized using alkaline phosphatase-conjugated polyclonal antirabbit or antigoat secondary antibodies. Recombinant human ER was used as a control.

MCF-7 breast cancer cells were confirmed by RT-PCR to express the nuclear ERs, ER and ERß (Fig. 1). Northern blot analysis confirmed that ER mRNA was more abundant than that for ERß (data not shown). Western blot analysis demonstrated the presence of both receptors in cell layer lysates (Fig. 2). In contrast, HCC38 breast cancer cells were negative for ER and ERß by Northern blot analysis, and ER or ERß protein was absent on Western blots (data not shown). However, RT-PCR (35 cycles) detected mRNA for ERß in these cells (Fig. 1).

View larger version (58K): [in this window] [in a new window]   Figure 1. RT-PCR analysis of ER and ERß expression in MCF-7 and HCC38 breast cancer cells. Total RNA was isolated from confluent cultures and subjected to RT-PCR as described in Materials and Methods. The amplified fragments were separated by 1% agarose gel electrophoresis. The primer for ER amplified a cDNA of 740 bp. Primers for ERß amplified a cDNA of 351 bp. In all cases, the amplified cDNAs were sequenced and confirmed to be the expected amplicon. Reactions were carried out in the presence of active and inactive RT to ensure the specificity of the reaction; only data for active RT are shown. Rat ovary total RNA was used as a positive control.

View larger version (83K): [in this window] [in a new window]   Figure 2. Western blot of ER in lysates of MCF-7 and HCC38 breast cancer cells. Cell lysates were electrophoresed on sodium dodecyl sulfate polyacrylamide gels and then transferred for Western blot analysis. Blots were incubated with polyclonal rabbit antibodies to ER, and immunoreactive bands were visualized using an alkaline phosphatase-linked second antibody. Recombinant human ER was used as a control. MW, Molecular weight.

PKC activity
Initial experiments determined the time course of E₂ and E₂-BSA regulation of PKC activity. Confluent cultures were treated for 9, 90, or 270 min with vehicle alone or with 10^-8 and 10^-7 M E₂ or E₂-BSA. Dose response was determined by treating MCF-7 cells and HCC38 cells for 90 min with 10^-11 to 10^-7 M E₂ or E₂-BSA. To determine whether tamoxifen altered the PKC response to estrogen, one half of the cultures were treated with 10^-9 M tamoxifen (Sigma). Alternatively, the cultures were treated for 90 min with 10^{-8 M} E₂ or E₂-BSA plus 10^-11, 10^-10, or 10^-9 M tamoxifen.

The contribution of nuclear ERs to any change in PKC activity was determined by treating confluent cultures with 10^-8 M E₂ or E₂-BSA as above, together with the ER antagonist ICI 182780 (Tocris Cookson, Ballwin, MO; Refs.32 and33) or the ER agonist diethylstilbestrol (Sigma; Ref. 34). MCF-7 cells and HCC38 cells were treated for 90 min with 10^-8 M E₂ or E₂-BSA and either ICI 182870 (10^-8, 10^-7, or 10^-6 M) or diethylstilbestrol (10^-9, 10^-8, or 10^-7 M). In addition, MCF-7 cells and HCC38 cells were incubated for 90 min with 10^-8 M E₂ or E₂-BSA in the presence of specific antibodies to ER and ERß (GeneTex, Inc., San Antonio, TX). Antibodies were added to the cultures at dilutions of 1:500, 1:1000, and 1:5000. Although these antibodies are specific for intracellular ERs, the anti-ER antibody has been used successfully to label proteins in the plasma membrane (35).

Isoform-specific antibodies were used to determine which PKC isoform is sensitive to E₂ or E₂-BSA as described previously (21). After treatment with 10^-8 M E₂ or E₂-BSA for 90 min, HCC38 cells were lysed as described below, and the lysates were incubated with nonspecific IgG or with antibodies to one of the following isoforms: PKC, PKCß, PKC, PKC, and PKC (Santa Cruz Biotechnology, Inc.). After precipitating the antigen-antibody complexes, PKC specific activity was determined in the supernatant.

To assess the mechanisms involved in the increase in PKC specific activity by E₂ or E₂-BSA, HCC38 cells were treated for 90 min with 10^-8 M E₂ or E₂-BSA in the presence of specific inhibitors of signaling pathways associated with membrane-mediated PKC activation (all inhibitors were purchased from Calbiochem (La Jolla, CA). The PI-PLC inhibitor U73122 (36) was used to determine the role of PLC in the mechanism. Cells were treated with 0, 0.1, 1, or 10 µM U73122. The role of G proteins was examined using the general G protein inhibitor GDPßS and the G protein activator GTPS (37) at concentrations of 0, 1, 10, and 100 µM. To assess whether PKC was increased via a phospholipase A₂ (PLA₂)-dependent mechanism, HCC38 cells were treated with the PLA₂ inhibitor quinacrine (38) at concentrations of 10^-9 M to 10^-7 M. In addition, HCC38 cells were treated with 10^-9 to 10^-7 M indomethacin to prevent the metabolism of arachidonic acid, thereby testing the potential role of prostaglandin in the pathway.

All experiments included vehicle-only control cultures. After treatment, PKC activity was measured in cell culture lysates as described previously for rat chondrocytes (25). At the termination of the incubation with E₂ or E₂-BSA, cell layers were rinsed with PBS, removed from the wells with a cell scraper, and lysed in solubilization buffer [50 mM Tris-HCl (pH 7.5), 150 mM NaCl, 5 mM EDTA, 1 mM phenylmethylsulfonylfluoride, and 1% Nonidet P-40] for 30 min on ice. Lysates containing equivalent amounts of protein, determined using the bicinchoninic protein assay reagent kit from Pierce Chemical Co. (Rockford, IL), were mixed for 20 min with a lipid preparation containing phorbol-12- myristate-1-acetate, phosphatidylserine and Triton X-100 mixed micelles, thereby providing the necessary cofactors and conditions for optimal activity. To this mixture, a high-affinity myelin basic protein peptide and [³²P]ATP (25 µCi/ml) were added to a final assay volume of 50 µl. After a 10-min incubation in a 30 C waterbath, samples were spotted onto phosphocellulose disks, which were then washed twice with 1% phosphoric acid and once with distilled water to remove unincorporated label before placement in a scintillation counter.

DNA synthesis
Effects of E₂ and E₂-BSA on proliferation were determined as a function of [³H]thymidine incorporation, as described previously for chondrocytes (15). Nearly confluent cultures of MCF-7 cells and HCC38 cells were treated for 24 h with 10^-11 to 10^-7 M E₂ or E₂-BSA. Tamoxifen (10^-9 M) was added to one half of the cultures. Four hours before harvest, [³H]thymidine was added to the cultures. To determine whether DNA synthesis was regulated via nuclear ERs, cells were treated with E₂ and E₂-BSA in the presence of ICI 182780 or diethylstilbestrol. For these experiments, cells were cultured for 24 h with 10^-8 M E₂ or E₂-BSA plus ICI 182780 (10^-8, 10^-7, or 10^-6 M) or diethylstilbestrol (10^-9, 10^-8, or 10^-7 M). Vehicle-only controls were included in all experiments.

Local production of estrogen
To determine whether MCF-7 cells or HCC38 cells are able to synthesize and secrete estrogen, we examined the ability of the cultures to convert testosterone to 17ß-estradiol, as described previously for chondrocytes (39).

Statistical analysis
For each experiment, each variable was tested in six independent cultures. Data presented in Results are from one set of experiments and are means ± SE of the mean for n = 6. To assess statistical significance, data were first analyzed using ANOVA. Individual groups were compared using Bonferroni’s modification of Student’s t test. All experiments were repeated a minimum of two times to ensure validity of the observations. Because the number of patients in each experiment was sufficiently great in terms of power, we opted to show actual values from one representative experiment, rather than data from multiple experiments that had been normalized as a percentage of control values.

PKC in human breast cancer tissue
Breast tumor tissue was obtained from 133 patients who presented for treatment at the Department of Obstetrics and Gynecology, University of Würzburg, under a protocol approved by the University’s Institutional Review Board. A pathologist classified the tissues as fibroadenoma, invasive lobular carcinoma, or invasive ductal carcinoma. Carcinomas were scored as ER(+) or ER(-) on the basis of immunohistochemistry using an antibody to ER. ER(+) tumors exhibited nuclear antibody staining. Cells in ER(-) tumors exhibited no nuclear, cytosolic, or plasma membrane immunoreactivity. Carcinomas (116 of 118) were also assigned a differential receptor score from 0–12 based on the classification system of Remmele and Stegner (40). Scores from 0–1 are considered ER(-); scores from 2–12 are considered to be ER(+). Tumors were sized according to the TNM classification system (41).

Tissues were also separated into groups on the basis of the treatment protocol selected for each patient: excision of the tumor or ablation of the breast tissue. We noted whether the patient received tamoxifen after surgery and whether there was any tumor recurrence or metastasis. Six patients were lost to follow-up, reducing the number of patients to 112 for these analyses. Because this was a retrospective study using banked tissues, it was not possible to assess prospectively whether patients receiving tamoxifen developed recurrent tumors with lower levels of PKC than their primary tumor exhibited.

Tissue was also frozen immediately after surgical removal and stored at -70 C in the Breast Cancer Tissue Bank at the University of Würzburg. Before determining PKC activity, frozen samples were thawed, their wet weights were determined, and they were then homogenized in RIPA buffer (100 mg tissue wet weight/ml) using a Polytron device (Brinkmann Instruments, Inc., Westbury, NY). PKC in the supernatant obtained after centrifugation at 15,000 x g for 2 min was measured as previously described using assay conditions optimized for phospholipid- and calcium-dependent PKC (10). Protein content was determined as described previously (10).

Data were analyzed by ANOVA, and post hoc comparisons were made using Bonferroni’s modification of Student’s t test.

	Results

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In vitro studies using MCF-7 and HCC38 cells
E₂ and E₂-BSA caused a time- and dose-dependent increase in PKC specific activity in MCF-7 and HCC38 cells, indicating that PKC specific activity was regulated by a membrane-mediated mechanism in both ER(+) and ER(-) breast cancer cells. However, the effects were cell-specific. In MCF-7 cells, a 3.2-fold increase was evident at 9 min, and there was a 5.4-fold increase at 90 min in response to E₂ (Fig. 3A). E₂-BSA caused a 3.1-fold increase at 9 min and a 5.7-fold increase at 90 min (Fig. 3B). In HCC38 cells, the greatest increases in PKC specific activity were seen at 9 min. E₂ caused a 3.4-fold increase at 9 min and a 2.5-fold increase at 90 min (Fig. 3C). E₂-BSA caused an 8.1-fold increase at 9 min, and the effect was reduced to 4.9-fold at 90 min (Fig. 3D). Although effects of E₂ and E₂-BSA were comparable in MCF-7 cells, the stimulatory effect of E₂-BSA in HCC38 cells was more than twice that of E₂. Concentrations of E₂ or E₂-BSA as low as 10^-11 M were stimulatory in the MCF-7 cells (Fig. 4, A and B). HCC38 cells were less sensitive to E₂, exhibiting increases in PKC specific activity only at concentrations of 10^-9 M and greater, whereas E₂-BSA stimulated PKC at 10^-11 M (Fig. 4, C and D).

View larger version (42K): [in this window] [in a new window]   Figure 3. Time course of estrogen-dependent regulation of PKC specific activity in ER(+) MCF-7 and ER(-) HCC38 breast cancer cells. Cells were treated with E2 (A and C) or E2-BSA (B and D) for 9, 90, or 270 min. PKC specific activity was measured in cell layer lysates. Values are the mean ± SEM for six independent cultures for each variable. #, P < 0.05, treatment vs. control at each time point; , P < 0.05, 10-7 M vs. 10-8 M; *, P < 0.05, vs. 9 min for each treatment.

View larger version (37K): [in this window] [in a new window]   Figure 4. Dose-dependent effects of estrogen on PKC specific activity in cultures of MCF-7 and HCC38 breast cancer cells and regulation by trans-tamoxifen. Cells were treated with E2 (A and C) or E2-BSA (B and D) for 90 min in the presence or absence of 10-9 M trans-tamoxifen. PKC specific activity was measured in cell layer lysates. Values are the mean ± SEM for six independent cultures for each variable. #, P < 0.05, tamoxifen vs. control; *, P < 0.05, E2 or E2-BSA vs. control.

View larger version (36K): [in this window] [in a new window]   Figure 5. Dose-dependent effect of tamoxifen on estrogen-dependent PKC specific activity in cultures of MCF-7 and HCC38 breast cancer cells. Cells were treated with 10-8 M E2 (A and C) or E2-BSA (B and D) for 90 min in the presence of 10-11 to 10-9 M trans-tamoxifen. PKC specific activity was measured in cell layer lysates. Values are the mean ± SEM for six independent cultures for each variable. #, P < 0.05, E2 or E2-BSA vs. control at each dose of tamoxifen; , P < 0.05, 10-9 M tamoxifen vs. 10-10 or 10-11 M tamoxifen; *, P < 0.05, tamoxifen vs. control.

View larger version (34K): [in this window] [in a new window]   Figure 6. Effect of ER antagonist ICI 182780 (A) and ER agonist diethylstilbestrol (B) on PKC specific activity in HCC38 breast cancer cells. HCC38 cells were incubated with 10-8 M E2 or E2-BSA for 90 min in the presence of 10-8 to 10-6 M ICI 182780 or 10-9 to 10-7 M diethylstilbestrol. PKC specific activity was measured in cell layer lysates. Values are the mean ± SEM for six independent cultures for each variable. #, P < 0.05, E2 or E2-BSA vs. control at each dose of ICI 182780 or diethylstilbestrol; , P < 0.05, E2 vs. E2-BSA.

View larger version (26K): [in this window] [in a new window]   Figure 7. Effect of inhibition of PI-PLC on PKC specific activity in HCC38 breast cancer cells. HCC38 cells were incubated with 10-8 M E2 or E2-BSA for 90 min in the presence of 0, 0.1, 1, or 10 µM U73122. PKC specific activity was measured in cell layer lysates. Values are the mean ± SEM for six independent cultures for each variable. #, P < 0.05, E2 or E2-BSA vs. control at each dose of U73122; *, P < 0.05, with U73122 vs. without U73122.

View larger version (31K): [in this window] [in a new window]   Figure 8. Role of G protein in the increase in PKC specific activity by E2 and E2-BSA. HCC38 cells were incubated with 10-8 M E2 or E2-BSA for 90 min in the presence of 0, 1, 20, or 100 µM GDPßS to inhibit G proteins (A) or in the presence of 0, 1, 10, or 100 µM GTPS to stimulate G proteins (B). PKC specific activity was measured in cell layer lysates. Values are the mean ± SEM for six independent cultures for each variable. #, P < 0.05, E2 or E2-BSA vs. control at each dose of GDPßS or GTPS; *, P < 0.05, with G protein regulator vs. without G protein regulator.

Proliferation of the breast cancer cells was regulated by estrogen via the nuclear ERs. E₂ affected DNA synthesis in MCF-7 cells in a dose-dependent manner, but E₂-BSA had no effect on [³H]thymidine incorporation (Fig. 9, A and B). ICI 182780 reduced DNA synthesis in control cultures and blocked [³H]thymidine incorporation in response to E₂ (Fig. 9A). The effects of the ER antagonist were dose-dependent (Fig. 10A). At the highest concentration, ICI 182780 completely abolished any increase due to E₂. In addition, the inhibitory effect of ICI 182780 on DNA synthesis in control cultures of MCF-7 cells was maintained in the E₂-BSA-treated cultures, regardless of the E₂-BSA concentration used (Fig. 10A). Neither form of estrogen affected [³H]thymidine incorporation by HCC38 cells (Fig. 10B). ICI 182780 caused a small decrease in [³H]thymidine incorporation in control cultures of HCC38 cells and in all cultures treated with E₂ or E₂-BSA (Fig. 10B). Tamoxifen (10^-9 M) had no effect on the E₂-stimulated increase in DNA synthesis in the MCF-7 cells (data not shown) and it had no effect on proliferation, whether or not the HCC38 cells were treated with E₂ or E₂-BSA (data not shown).

View larger version (24K): [in this window] [in a new window]   Figure 9. Effect of 182780 on E2- and E2-BSA-dependent [3H]thymidine incorporation by MCF-7 breast cancer cells. Confluent cultures of MCF-7 cells were treated for 24 h with 10-11 to 10-7 M E2 (A) or E2-BSA (B) in the presence of 10-6M ICI 182780. Values are the mean ± SEM for six independent cultures for each variable. *, P < 0.05, E2 vs. control; #, P < 0.05, ICI 182780 vs. control.

View larger version (29K): [in this window] [in a new window]   Figure 10. Effect of ICI 182780 on [3H]thymidine incorporation by MCF-7 (A) and HCC38 (B) breast cancer cells. Confluent cultures were treated for 24 h with E2 or E2-BSA in the presence of 10-8 to 10-6 M ICI 182780. Values are the mean ± SEM for six independent cultures for each variable. *, P < 0.05, ICI 182780 vs. control; #, P < 0.05, E2 vs. E2-BSA.

PKC in human breast carcinomas
Classification of the 133 tumors used in this study showed that 15 of the tumors were fibroadenomas, 33 were invasive lobular carcinomas, and 85 were invasive ductal carcinomas. As noted previously (27), tumor severity correlated with patient age (fibroadenoma, 43.9 ± 3.4 yr; invasive lobular carcinoma, 62.2 ± 1.4 yr; and invasive ductal carcinoma, 64.7 ± 2.5 yr). There was a direct correlation between tumor type and PKC specific activity. PKC in fibroadenomas was less than half that measured in invasive lobular carcinomas, and this was approximately half the specific activity measured in invasive ductal carcinomas (Fig. 11A). PKC in carcinomas was more than twice that found in normal breast tissue from the same patient (Fig. 11B). PKC also varied with tumor severity and was higher in larger carcinomas. Values ranged from 26.1 ± 3.7 pmol PO₄/µg protein·min for T1 tumors to 50.4 ± 1.2 pmol PO₄/µg protein·min for T4 tumors (Table 2). PKC varied with ER status as well. ER(-) breast carcinomas had twice the specific activity of ER(+) tissues (Fig. 11C). Enzyme activity varied in a biphasic manner with receptor score (Table 3). As receptor score increased from 0 to 5–7, PKC decreased, with the lowest levels being observed in specimens with scores of 5–7. As receptor score increased from 8–12, PKC specific activity increased, with greatest PKC activity found in tissue specimens with receptor scores of 11–12.

View larger version (18K): [in this window] [in a new window]   Figure 11. PKC specific activity in human breast tumor tissue. A, PKC activity in fibroadenoma, invasive lobular carcinoma, and invasive ductal carcinoma. B, PKC activity in breast cancer tissue (n = 4) and adjacent normal tissue in the same patient (n = 4). C, PKC activity in ER(-) (n = 39) or ER(+) (n = 79) tissue. *, P < 0.05, carcinoma vs. fibroadenoma (A); breast cancer vs. normal tissues (B); or ER(-) vs. ER(+) carcinomas (C); #, P < 0.05, lobular carcinoma vs. ductal carcinoma.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The effect of E₂-BSA was not due to free E₂. Previous studies had shown that part of the response of chondrocytes to E₂-BSA was due to free E₂, although less than 5% of the E₂ in E₂-BSA was unconjugated and therefore able to enter the cell and bind to nuclear ERs (21). By prefiltering the E₂-BSA to remove unconjugated estrogen (22), the effect of free E₂ was eliminated (21). For this reason, only prefiltered E₂-BSA was used in the present study.

Neither ER nor ERß was present in Western blots of HCC38 cells, making it unlikely that the receptor responsible for PKC activation by E₂ or E₂-BSA was a membrane form of these receptors (15, 21). Moreover, antibodies specific for ER and ERß did not block the effects of E₂ or E₂-BSA in MCF-7 cells, which do possess both receptors. Although it could be argued that the antibodies could not detect nuclear receptors, if these receptors were present in the plasma membrane they would have been seen, as has been reported by others (35). This suggests that an alternate receptor may be involved. Whether the receptor is a splice variant of ER or ERß that is not recognized by the antibodies or primers used cannot be ruled out.

Another possibility is that E₂ and E₂-BSA exert their effects via separate membrane receptor-mediated mechanisms in MCF-7 cells and HCC38 cells. Studies using vascular endothelial cells as the model have provided evidence that E₂ binds ER in the plasma membranes but E₂-BSA binds three non-ER proteins (42). This latter hypothesis is supported by the enhanced sensitivity of PKC to E₂-BSA noted in the ER(-) HCC38 cells.

Our results indicate that if separate receptors are used by E₂ and E₂-BSA, they signal by the same pathways in HCC38 cells. E₂ and E₂-BSA cause an increase in PKC specific activity via a PI-PLC-dependent mechanism that involves G proteins, based on the specific inhibition of activation by U73122 and GDPßS, as well as the increase in activation by GTPS. Neither form of estrogen signals via a PLA₂-dependent mechanism, nor are arachidonic acid metabolites involved. Moreover, both forms of estrogen affect the isoform of PKC in HCC38 cells as well as in MCF-7 cells, as demonstrated by the reduction in PKC activity in the presence of antibodies to PKC, but not to PKCß, PKC, PKC, or PKC. E₂ and E₂-BSA also function in the same manner in rat growth plate chondrocytes, specifically activating PKC via PI-PLC and G protein (10), suggesting that this pathway is common across cell types and species. Species and/or cell-type differences may exist, however. Others have reported that in MCF-7 cells, PKC (8) is translocated to the membrane. In rat chondrocytes, PKC translocation to the plasma membrane also occurs in response to E₂ and E₂-BSA (10). However, PKC was not affected by either form of estrogen in the chondrocytes, nor was it affected in the HCC38 cells in the present study.

Although our results demonstrate definitively that non-ER mechanisms are involved in the rapid activation of PKC by estrogen, traditional ER-mediated mechanisms may also play a role. In MCF-7 cells, in which ER and ERß are both present, E₂ and E₂-BSA elicit rapid increases in PKC, as well as a more robust increase at 90 min. In rat chondrocytes, E₂/E₂-BSA sensitive PKC translocation to the plasma membrane accounts for the rapid response, but new PKC expression and synthesis are required for the delayed increase (10). Whether the newly expressed PKC is a consequence of classical ER-dependent gene activation is not known. PKC- dependent pathways can also lead to gene expression, and several studies have now shown that E₂ and E₂-BSA can lead to MAPK activation (43, 44, 45).

Our results indicate that estrogen-dependent regulation of DNA synthesis in breast cancer cells is not via membrane receptors. Only E₂ increased [³H]thymidine incorporation by MCF-7 cells, and neither form of estrogen modulated DNA synthesis in HCC38 cells. However, ER-dependent and ER-independent pathways may both play a role. Several studies have suggested that E₂ exerts its effects on growth through non-ER mediated mechanisms (17, 18, 19). At least part of the response is via the ER, however, because the ER antagonist ICI 182780 decreased [³H]thymidine incorporation in ER(+) MCF-7 cultures treated by E₂ and E₂-BSA. ICI 182780 reduced DNA synthesis in HCC38 cells, which lack ER and ERß protein, suggesting that it may exert antiestrogenic effects by mechanisms unrelated to traditional nuclear ERs. ICI 182780-dependent reduction of DNA synthesis in control cultures reflects the fact that the cells were conditioned by low levels of estrogen in the culture media (<10^-12 M). The goal of our study was not to study the effects of E₂ and E₂-BSA under conditions in which the cells were starved of such conditioning factors present in serum, but to study the incremental effects of estrogen in healthy cells. The fact that ICI 182780 was able to reduce DNA synthesis under these culture conditions supports the hypothesis that E₂ in the control medium and ICI 182780 mediated their effects via a mechanism other than ER or ERß. The possibility cannot be ruled out that small levels of ERß, undetectable on Western blots, were sufficient to mediate the antiestrogenic effect of ICI 182780 in HCC38 cells because RT-PCR was able to detect low levels of ERß mRNA.

Our cell culture studies suggest that mechanisms other than growth arrest may contribute to the success of tamoxifen clinically. In the present study, tamoxifen did not inhibit the stimulatory effect of E₂ on DNA synthesis in MCF-7 cells, nor did it alter DNA synthesis in control cultures. Similarly, tamoxifen did not alter DNA synthesis in HCC38 cells, whether or not they were treated with E₂ or E₂-BSA. This was an unexpected finding for which we do not yet have a comprehensive explanation. Tamoxifen is a PKC inhibitor, and DNA synthesis is mediated by a PKC-dependent mechanism in MCF-7 cells because phorbol esters, which activate PKC (46), also regulate growth in these cells (47). Tamoxifen has cytotoxic effects in breast cancer cells (48) and blocks the stimulatory effects of E₂ on DNA synthesis in some MCF-7 cell lines (49). However, other studies using MCF-7 cells show that tamoxifen can also stimulate DNA synthesis (50), whereas others report that the effect of tamoxifen can vary (49, 51). Tamoxifen concentrations comparable to those we used have not been shown to be cytotoxic, although they are inhibitory to PKC. This suggests that tamoxifen-sensitive PKC, which is membrane-mediated on the basis of its stimulation by E₂-BSA, is not involved in growth regulation of breast cancer cells, at least with respect to DNA synthesis. This hypothesis is supported by the observation that PCK but not PKC, PKC, or PKC is specifically involved in protection of MCF-7 cells against TNF cytotoxicity (52).

The failure of tamoxifen to reduce DNA synthesis in breast cancer cells, although it inhibits PKC activity, differs from colon tumor cells in which inhibition of PKC with chelerythrine or treatment with ICI 182870 blocked E₂-dependent DNA synthesis (11). PKC inhibition by chelerythrine and tamoxifen are not necessarily the same, however. In rat costochondral cartilage cells, chelerythrine causes a complete reduction in PKC in control cultures and reduces [³H]thymidine incorporation to a greater extent than is seen with E₂ (10). Chelerythrine primarily targets PKC (53), but it also has inhibitory effects on other PKC isoforms (54) as well as PKA (55), which may also regulate proliferation. Tamoxifen inhibits PKC in rat chondrocytes (25) as well as in other cells (24, 56), and it has been reported to inhibit calmodulin-dependent cAMP phosphodiesterase activity in rat brain (57). In addition, tamoxifen has been shown to specifically affect PKC (8), whereas E₂ affects PCK (12). The effects of tamoxifen on PKC activity as well as on proliferation of MCF-7 cells also depend on the configuration of the molecule. Cis-tamoxifen is a more potent inhibitor of Ca²⁺ and phosphatidylserine-dependent rat brain PKC than trans- tamoxifen (58). Although others have reported that cis-tamoxifen promotes MCF-7 cell growth and trans-tamoxifen inhibits growth (59), we failed to demonstrate an effect of trans-tamoxifen on DNA synthesis. This may be due to differences in experimental design. Our studies were done using confluent cultures to correlate the effects of estrogen on PKC activity with the regulation of cell physiology by E₂ and E₂-BSA. It may be that culture conditions, such as confluence, modulate the effects of estrogen on the cells.

Recent studies examining local production of steroid hormones suggest that many cells use these agents as autocrine modulators. E₂ is secreted by rat chondrocytes (39), human osteoblasts (60), and colon and breast cancer cells (61, 62) at concentrations up to 1000-fold greater than circulating hormone levels. By acting via membrane receptors coupled to rapid action signaling pathways, locally produced steroids can fine-tune the response of the cell to conditioning levels of the systemically circulating hormone. We failed to find evidence of aromatase activity based on estradiol production via aromatization in either cell line in the present study. Because the fetal bovine serum used in the culture media was not charcoal-stripped, there were low levels of E₂ present even in the control cultures (<10^-12 M), which may have suppressed local E₂ production by the MCF-7 and HCC38 cells.

Our results confirm and extend the relationship between PKC activity and tumorigenicity suggested by previous studies (1, 2, 3, 5). Although earlier reports examined relatively small numbers of samples, we examined 133 specimens, enabling us to establish with a reasonable degree of certainty that tumor severity and PKC specific activity are correlated in a positive manner. Moreover, PKC activity is greater in carcinoma vs. fibroadenoma, particularly in ER(-) carcinomas, suggesting that the PKC signaling pathway may be up-regulated in these cells. We did not specifically assess whether a particular PKC isoform(s) was responsible for the increased enzyme activity in the breast cancer samples. Our assay system is optimized for PKC, which is both Ca²⁺- and phospholipid-dependent (63). Recent studies examining expression of PKC failed to show a correlation between PKC and total PKC activity in cultures of breast cancer cells from 12 patients, nor were they able to show that PKC expression was influenced by a number of commonly used antineoplastic agents (64). PKC is an atypical form of the enzyme and is insensitive to both Ca²⁺ and phospholipid (65). Using antiisoform antibodies, we showed that PKC is not regulated by estrogen in human breast cancer cells, as was shown previously in rat chondrocytes (10). Changes in PKC may contribute to increased PKC in the breast carcinoma tissues we examined because others have shown by immunohistochemistry that distribution of PKC is altered in in situ and invasive lesions in comparison with normal breast tissue (66). Taken together, our in vitro and in vivo results suggest that PKC activity in aggressive neoplasia is related to aspects of the tumors in addition to DNA synthesis, and it is these features that are tamoxifen sensitive.

	Acknowledgments

 
We thank Carol Heston and Wanda Whitfield for their help in the preparation of this manuscript.

	Footnotes

 
This research was funded by the Susan G. Komen Foundation and United States Public Health Service Grants DE-05937 and DE-08603.

Abbreviations: E₂, 17ß-estradiol; ER, estrogen receptor; PI-PLC, phosphatidylinositol-specific phospholipase C; PKC, protein kinase C; PLA₂, phospholipase A₂.

Received October 1, 2002.

Accepted for publication January 21, 2003.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. O’Brian CA, Vogel VG, Singletary SE, Ward NE 1989 Elevated protein kinase C expression in human breast tumor biopsies relative to normal breast tissue. Cancer Res 49:3215–3217[Abstract/Free Full Text]
2. Gordge PC, Hulme MJ, Clegg RA, Miller WR 1996 Elevation of protein kinase A and protein kinase C activities in malignant as compared with normal human breast tissue. Eur J Cancer 32A:2120–2126
3. Gupta KP, Ward NE, Gravitt KR, Bergman PJ, O’Brian CA 1996 Partial reversal of multidrug resistance in human breast cancer cells by an N-myristoylated protein kinase C- pseudosubstrate peptide. J Biol Chem 271:2102–2111[Abstract/Free Full Text]
4. Bergman PJ, Gravitt KR, O’Brian CA 1997 An N-myristoylated protein kinase C- pseudosubstrate peptide that functions as a multidrug resistance reversal agent in human breast cancer cells is not a P-glycoprotein substrate. Cancer Chemother Pharmacol 40:453–456[CrossRef][Medline]
5. Ways DK, Kukoly CA, deVente J, Hooker JL, Bryant, WO, Posekany KJ, Fletcher DJ, Cook PP, Parker PJ 1995 MCF-7 breast cancer cells transfected with protein kinase C- exhibit altered expression of other protein kinase C isoforms and display a more aggressive neoplastic phenotype. J Clin Invest 95:1906–1915
6. Persons DA, Wilkison WO, Bell RM, Finn OJ 1988 Altered growth regulation and enhanced tumorigenicity of NIH 3T3 fibroblasts transfected with protein kinase C-I cDNA. Cell 52:447–458[CrossRef][Medline]
7. Su ZZ, Shen R, O’Brian CA, Fisher PB 1994 Induction of transformation progression in type 5 adenovirus-transformed rat embryo cells by a cloned protein kinase C ß 1 gene and reversal of progression by 5-azacytidine. Oncogene 9:1123–1132[Medline]
8. Lavie Y, Zhang ZC, Cao HT, Han TY, Jones RC, Liu YY, Jarman M, Hardcastle IR, Giuliano AE, Cabot MC 1998 Tamoxifen induces selective membrane association of protein kinase C in MCF-7 human breast cancer cells. Int J Cancer 77:928–932[CrossRef][Medline]
9. Fabbro D, Kung W, Roos W, Regazzi R, Eppenberger U 1986 Epidermal growth factor binding and protein kinase C activities in human breast cancer cell lines: possible quantitative relationship. Cancer Res 46:2720–2725[Abstract/Free Full Text]
10. Sylvia VL, Hughes T, Dean DD, Boyan BD, Schwartz Z 1998 17ß-Estradiol regulation of protein kinase C activity in chondrocytes is sex-dependent and involves nongenomic mechanisms. J Cell Physiol 176:435–444[CrossRef][Medline]
11. Winter DC, Taylor C, O’Sullivan GC, Harvey BJ 2000 Mitogenic effects of oestrogen mediated by a non-genomic receptor in human colon. Br J Surg 87:1684–1689[CrossRef][Medline]
12. Sylvia VL, Schwartz Z, Schuman L, Morgan RT, Mackey S, Gomez R, Boyan BD 1993 Maturation-dependent regulation of protein kinase C activity by vitamin D3 metabolites in chondrocytes cultures. J Cell Physiol 157:271–278[CrossRef][Medline]
13. Schwartz Z, Gates PA, Nasatzky E, Sylvia VL, Mendez J, Dean DD, Boyan BD 1996 Effect of 17ß-estradiol on chondrocyte membrane fluidity and phospholipid metabolism is membrane-specific, sex-specific, and cell maturation-dependent. Biochim Biophys Acta 1282:1–10[Medline]
14. Levin ER 2001 Cell localization, physiology, and nongenomic actions of estrogen receptors. J Applied Physiol 91:1860–1867[Abstract/Free Full Text]
15. Sylvia VL, Boyan BD, Dean DD, Schwartz Z 2000 The membrane effects of 17ß-estradiol on chondrocyte phenotypic expression are mediated by activation of protein kinase C through phospholipase C and G-proteins. J Steroid Biochem Mol Biol 73:211–224[CrossRef][Medline]
16. Nasatzky E, Schwartz Z, Soskolne WA, Brooks BP, Dean DD, Boyan BD, Ornoy A 1994 Sex steroid enhancement of matrix production by chondrocytes is sex and cell maturation specific. Endocr J 2:207–215
17. Sapino A, Pietribiasi F, Bussolati G, Marchisio PC 1986 Estrogen- and tamoxifen-induced rearrangement of cytoskeletal and adhesion structures in breast cancer MCF-7 cells. Cancer Res 46:2526–2531[Abstract/Free Full Text]
18. Stefaneanu L 1997 Pituitary sex steroid receptors: localization and function. Endocr Pathol 8:91–108[Medline]
19. Goldenberg GJ, Froese EK 1982 Drug and hormone sensitivity of estrogen receptor-positive and-negative human breast cancer cells in vitro. Cancer Res 42:5147–5151[Abstract/Free Full Text]
20. Stevis PE, Deecher DC, Suhadolnik L, Mallis LM, Frail DE 1999 Differential effects of estradiol and estradiol-BSA conjugates. Endocrinology 140:5455–5458[Abstract/Free Full Text]
21. Sylvia VL, Walton J, Lopez D, Dean DD, Boyan BD, Schwartz Z 2001 17ß-estradiol-BSA conjugates and 17ß-estradiol regulate growth plate chondrocytes by common membrane associated mechanisms involving PKC dependent and independent signal transduction. J Cell Biochem 81:413–429[CrossRef][Medline]
22. Kousteni S, Bellido T, Plotkin LI, O’Brien CA, Bodenner DL, Han L, Han K, DiGregorio GB, Katzenellenbogen JA, Katzenellenbogen BS, Roberson PK, Weinstein RS, Jilka RL, Manolagas SC 2001 Nongenotropic, sex-nonspecific signaling through the estrogen or androgen receptors: dissociation from transcriptional activity. Cell 104:719–730[Medline]
23. Swain SM 2001 Tamoxifen for patients with estrogen receptor-negative breast cancer. J Clin Oncol 19:93S–97S
24. O’Brian CA, Liskamp RM, Solomon DH, Weinstein IB 1985 Inhibition of protein kinase C by tamoxifen. Cancer Res 45:2462–2465[Abstract/Free Full Text]
25. Schwartz Z, Sylvia VL, Guinee T, Dean DD, Boyan BD 2002 Tamoxifen elicits its anti-estrogen effects in growth plate chondrocytes by inhibiting PKC. J Steroid Biochem Mol Biol 80:401–410[CrossRef][Medline]
26. Horwitz KB, Zava DT, Thilagar AK, Jensen EM, McGuire WL 1978 Steroid receptor analyses of nine human breast cancer cell lines. Cancer Res 38:2434–2437[Abstract/Free Full Text]
27. Gazdar AF, Kurvari V, Virmani A, Gollahon L, Sakaguchi M, Westerfield M, Kodagoda D, Stasny V, Cunningham HT, Wistuba I, Tomlinson G, Tonk V, Ashfaq R, Leitch AM, Minna JD, Shay JW 1998 Characterization of paired tumor and non-tumor cell lines established from patients with breast cancer. Int J Cancer 78:766–774[CrossRef][Medline]
28. Jain PT, Trump BF1997 Tamoxifen induces deregulation of [Ca2+] in human breast cancer cells. Anticancer Res 17:1167–1174
29. Mandlekar S, Kong AN 2001 Mechanisms of tamoxifen-induced apoptosis. Apoptosis 6:469–477[CrossRef][Medline]
30. Johnston SR, Boeddinghaus IM, Riddler S, Haynes BP, Hardcastle IR, Rowlands M, Grimshaw R, Jarman M, Dowsett M 1999 Idoxifene antagonizes estradiol-dependent MCF-7 breast cancer xenograft growth through sustained induction of apoptosis. Cancer Res 59:3646–3651[Abstract/Free Full Text]
31. Inoue S, Hoshino S, Miyoshi H, Akishita M, Hosoi T, Orimo H, Ouchi Y 1996 Identification of a novel isoform of estrogen receptor, a potential inhibitor of estrogen action, in vascular smooth muscle cells. Biochem Biophys Res Comm 219:766–772[CrossRef][Medline]
32. Robertson JF 2001 ICI 182, 780 (Fulvestrant)–the first oestrogen receptor down-regulator: current clinical data. Br J Cancer 85(Suppl 2):11–14
33. Wakeling AE 1995 Use of pure anti-estrogens to elucidate the mode of action of estrogens. Biochem Pharmacol 49:1545–1549[CrossRef][Medline]
34. Fuqua SA 1999 Expression of wild-type estrogen receptor and variant isoforms in human breast cancer. Cancer Res 59:4525–4528[Abstract/Free Full Text]
35. Norfleet AM, Clarke CH, Gametchu B, Watson CS 2000 Antibodies to the estrogen receptor- modulate rapid prolactin release from rat pituitary tumor cells through plasma membrane estrogen receptors. FASEB J 14:157–165[Abstract/Free Full Text]
36. Bleasdale J, Bundy GL, Bunting S, Fitzpatrick FA, Huff RM, Sun FF, Pike JE 1989 Inhibition of phospholipase C-dependent processes by U73, 122. Adv Prostaglandin Thromboxane Leukot Res 19:590–593[Medline]
37. Perez DM, DeYoung MB, Graham RM 1993 Coupling of expressed 1B- and 1D-adrenergic receptor to multiple signaling pathways is both G protein and cell type specific. Mol Pharmacol 44:784–795[Abstract]
38. Church DJ, Braconi S, van der Brent V, Vallotton MB, Lang U1994 Protein kinase C-dependent prostaglandin production mediates angiotensin II- induced atrial-natriuretic peptide release. Biochem J 298:451–456
39. Sylvia VL, Gay I, Hardin R, Dean DD, Boyan BD, Schwartz Z 2002 Rat costochondral chondrocytes produce 17ß-estradiol and regulate its production by 1,25(OH)2D3. Bone 30:57–63[Medline]
40. Remmele W, Stegner HE 1987 Recommendation for uniform definition of an immunoreactive score (IRS) for immunohistochemical estrogen receptor detection (ER-ICA) in breast cancer tissue. Pathologe 8:138–140[Medline]
41. World Health Organization, Histological typing of breast tumors. 2nd ed. Geneva, 1981. Ann Pathol 2:91–105
42. Zheng J, Ali A, Ramirez VD 1996 Steroids conjugated to bovine serum albumin as tools to demonstrate specific steroid neuronal membrane binding sites. J Psychiatry Neurosci 21:187–197[Medline]
43. Fitzpatrick JL, Mize AL, Wade CB, Harris JA, Shapiro RA, Dorsa DM 2002 Estrogen-mediated neuroprotection against ß-amyloid toxicity requires expression of estrogen receptor or ß and activation of the MAPK pathway. J Neurochem 82:674–682[CrossRef][Medline]
44. Alvaro D, Onori P, Metalli VD, Svegliati-Baroni G, Folli F, Franchitto A, Alphini G, Mancino MG, Attili AF, Gaudio E 2002 Intracellular pathways mediating estrogen-induced cholangiocyte proliferation in the rat. Hepatology 36:297–304[CrossRef][Medline]
45. Atanaskova N, Keshamouni VG, Krueger JS, Schwartz JA, Miller F, Reddy KB 2002 MAP kinase/estrogen receptor cross-talk enhances estrogen-medicated signaling and tumor growth but does not confer tamoxifen resistance. Oncogene 21:4000–4008[CrossRef][Medline]
46. Castagna M, Takai Y, Kaibuchi K, Sano K, Kikkawa U, Nishizuka Y 1982 Direct activation of calcium-activated, phospholipid-dependent protein kinase by tumor-promoting phorbol esters. J Biol Chem 257:7847–7851[Abstract/Free Full Text]
47. Darbon, J-M, Valette A, Bayard F 1986 Phorbol esters inhibit the proliferation of MCF-7 cells. Biochem Pharmacol 35:2683–2686[CrossRef][Medline]
48. Zhang L, Zhai X, He Z 2000 Modulating effect of vitamin D3 in vitro on EGFR mRNA expression of human breast cancer cell lines. Zhonghua Zhong Liu Za Zhi 22:205–207[Medline]
49. Swiatecka J, Dzieciol J, Anchim T, Dabrowska M, Pietruczuk M, Wolczynski S 2000 Influence of estrogen, antiestrogen and UV-light on the balance between proliferation and apoptosis in MCF-7 breast adenocarcinoma cells culture. Neoplasma 47:15–24[Medline]
50. Burow ME, Weldon CB, Chiang TC, Tang Y, Collins-Burow BM, Rolfe K, Li S, McLachlan JA, Beckman BS 2000 Differences in protein kinase C and estrogen receptor , ß expression and signaling correlate with apoptotic sensitivity of MCF-7 breast cancer cell variants. Int J Oncol 16:1179–1187[Medline]
51. Basu A 1998 The involvement of novel protein kinase C isozymes in influencing sensitivity of breast cancer MCF-7 cells tumor necrosis factor-. Mol Pharmacol 53:105–111[Abstract/Free Full Text]
52. Sutherland RL, Hall RE, Taylor IW 1983 Cell proliferation kinetics of MCF-7 human mammary carcinoma cells in culture and effects of tamoxifen on exponentially growing and plateau-phase cells. Cancer Res 43:3998–4006[Abstract/Free Full Text]
53. Herbert JM, Augereau JM, Gleye J, Maffrand JP 1990 Chelerythrine is a potent and specific inhibitor of protein kinase C. Biochem Biophys Res Commun 172:993–999[CrossRef][Medline]
54. Barg J, Belcheva MM, Coscia CJ 1992 Evidence for the implication of phosphoinositol signal transduction in µ-opioid inhibition of DNA synthesis. J Neurochem 59:1145–1152[CrossRef][Medline]
55. Azarani A, Goltzman D, Orlowski J 1995 Parathyroid hormone and parathyroid hormone-related peptide inhibit the apical Na+/H+ exchanger NHE-3 isoform in renal cells (OK) via a dual signaling cascade involving protein kinase A and C. J Biol Chem 270:20004–20010[Abstract/Free Full Text]
56. O’Brian CA, Housey GM, Weinstein IB 1988 Specific and direct binding of protein kinase C to an immobilized tamoxifen analogue. Cancer Res 48:3626–3629[Abstract/Free Full Text]
57. Lam HY 1984 Tamoxifen is a calmodulin antagonist in the activation of cAMP phosphodiesterase. Biochem Biophys Res Commun 118:27–32[CrossRef][Medline]
58. O’Brian CA, Liskamp RM, Solomon DH, Weinstein IB 1986 Triphenylethylenes: a new class of protein kinase C inhibitors. J Natl Cancer Inst 76:1243–1246
59. Katzenellenbogen BS 1996 Estrogen receptors: bioactivities and interactions with cell signaling pathways. Biol Reprod 54:287–293[Abstract]
60. Purohit A, Flanagan AM, Reed MJ 1992 Estrogen synthesis by osteoblast cell lines. Endocrinology 131:2027–2029[Abstract/Free Full Text]
61. James VH, McNeill JM, Lai LC, Newton CJ, Ghilchik MW, Reed MJ 1987 Aromatase activity in normal breast and breast tumor tissues: in vivo and in vitro studies. Steroids 50:269–279[CrossRef][Medline]
62. Duncan LJ, Reed MJ 1995 The role and proposed mechanism by which oestradiol 17ß-hydroxysteroid dehydrogenase regulates breast tumour oestrogen concentrations. J Steroid Biochem Mol Biol 55:565–572[CrossRef][Medline]
63. Bell RM, Hannun Y, Loomis C 1986 Mixed micelle assay of protein kinase C. Methods Enzymol 124:353–359[Medline]
64. Schondorf T, Kurbacher C, Becker M, Warm M, Kolhagen H, Gohring U 2001 Heterogeneity of protein kinase C activity and PKC- expression in clinical breast carcinomas. Clin Exp Med 1:1–8[CrossRef][Medline]
65. Liyanage M, Frith D, Livneh E, Stabel S 1992 Protein kinase C group B members PKC-, -, - of recombinant proteins in vitro and in vivo. Biochem J 283:781–787
66. Masso-Welch P, Winston J, Edge S, Darcy K, Asch H, Vaughan M, Ip M 2001 Altered expression and localization of PKC in human breast tumors. Breast Cancer Res Treat 68:211–223[CrossRef][Medline]

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