Mitogen-Activated Protein Kinase Kinase Kinase 1 Activates Androgen Receptor-Dependent Transcription and Apoptosis in Prostate Cancer

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Molecular and Cellular Biology, July 1999, p. 5143-5154, Vol. 19, No. 7
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Mitogen-Activated Protein Kinase Kinase Kinase 1 Activates Androgen Receptor-Dependent Transcription and Apoptosis in Prostate Cancer

Maria T. Abreu-Martin,¹ Ajai Chari,²^,³ Andrew A. Palladino,¹ Noah A. Craft,²^,³ and Charles L. Sawyers²^,³^,^*

Department of Medicine² and Molecular Biology Institute,³ University of California at Los Angeles, and Department of Medicine, Cedars-Sinai Medical Center,¹ Los Angeles, California 90095

Received 29 July 1998/Returned for modification 1 October 1998/Accepted 17 March 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Mitogen-activated protein (MAP) kinases phosphorylate the estrogen receptor and activate transcription from estrogen receptor-regulatedgenes. Here we examine potential interactions between the MAPkinase cascade and androgen receptor-mediated gene regulation.Specifically, we have studied the biological effects of mitogen-activatedprotein kinase kinase kinase 1 (MEKK1) expression in prostatecancer cells. Our findings demonstrate that expression of constitutivelyactive MEKK1 induces apoptosis in androgen receptor-positive butnot in androgen receptor-negative prostate cancer cells. Reconstitutionof the androgen receptor signaling pathway in androgen receptor-negativeprostate cancer cells restores MEKK1-induced apoptosis. MEKK1also stimulates the transcriptional activity of the androgen receptorin the presence or absence of ligand, whereas a dominant negativemutant of MEKK1 impairs activation of the androgen receptor byandrogen. These studies demonstrate an unanticipated link betweenMEKK1 and hormone receptor signaling and have implications forthe molecular basis of hormone-independent prostate cancergrowth.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Steroid hormones play a critical role in the development and maintenance of multiple organs, including mammary glands (estrogens),the uterine lining (progesterone), and the adrenal medulla (glucocorticoids)(19, 26). In addition to responding to their ligands, steroidhormone receptors are modified by kinase signaling pathways whichdirectly or indirectly alter the biological response to hormones(27). In the case of the androgen receptor, one model systemfor functional studies is the prostate gland. Prostate developmentis dependent on androgen, and normal prostate secretory epithelialcells undergo apoptosis in response to androgen withdrawal (9).Prostate cancer cells are also dependent on androgen for growthbut eventually acquire the ability to proliferate in the absenceof androgen in patients after prolonged anti-androgen drug therapy(2, 35). Although androgen independent, these cells continueto express androgen-responsive genes, indicating ligand-independentactivation of the androgen receptor signaling pathway. Definingthe mechanism for this conversion to androgen independence willhave important implications in prostate cancer therapy (47).

A number of protein kinase signaling pathways have been implicated in androgen receptor signaling. Protein kinase A can activateandrogen receptor-mediated gene transcription in the absence ofandrogen (23, 38). The protein kinase C activator and tumorpromoter 12-O-tetradecanoylphorbol-13-acetate negatively regulatesandrogen receptor-mediated gene transcription through a presumedinteraction of c-jun and androgen receptor (43). Epidermal growthfactor (EGF), keratinocyte growth factor (KGF), or insulin-likegrowth factor 1 (IGF-1) can activate transcription from androgenreceptor-regulated genes in prostate cancer cells (11, 42).Transgenic mice expressing KGF under the control of the hormone-responsivemouse mammary tumor virus promoter develop prostatic hyperplasia,suggesting that tonic exposure to certain growth factors resultsin dysregulated prostate growth in vivo (28). These reportsestablish that interactions between androgen receptor and non-steroidreceptor signaling pathways exist, but the molecular details areunclear.

Because many of these growth factors activate the mitogen-activated protein (MAP) kinase pathway, we hypothesized that isolatedactivation of this pathway may affect androgen receptor-mediatedgene regulation and the prostate cancer cell phenotype. In particular,we examined the effect of MAP kinase kinase kinase 1 (MEKK1) signalingin prostate cancer cells. Activation of MEKK1 results in the downstreamactivation of MKK4 (SEK1) and subsequently JNK (36), as wellas phosphorylation of I $kappa$ B kinase leading to the release of NF- $kappa$ B(30, 37, 56). JNK activation is associated with diverseoutcomes which vary in different cell types and in the presenceof concurrent signals from other pathways. JNK activation is necessaryfor cellular transformation by the Bcr-Abl oncogene (14, 41)but is also associated with apoptosis in response to growth factordeprivation or withdrawal of extracellular matrix (anoikis) (5,53). Constitutively active alleles of MEKK1 induce apoptosisin diverse cell types (25, 51). A model for MEKK1-mediatedapoptosis has emerged in which genotoxic stress leads to phosphorylationand activation of MEKK1 followed by MEKK1-initiated cleavage ofDEVD-directed caspases. MEKK1 is itself a target for cleavageby caspases, which leads to further activation of MEKK1 by removalof a negative regulatory domain (5, 50). Thus, MEKK1 participatesin a caspase activation loop which requires both the kinase activityof MEKK1 as well as the caspase recognition site, permitting itscleavage bycaspases.

Here we address the role of the MEKK pathway in prostate cancer. Our findings demonstrate that expression of constitutivelyactive MEKK1 leads to apoptosis of androgen receptor-positivebut not of androgen receptor-negative prostate cancer cells. Reconstitutionof the androgen receptor pathway sensitizes prostate cancer cellsto MEKK1-induced apoptosis. MEKK1 also activates androgen-regulatedgene expression in an androgen receptor-dependent fashion. Thesedata demonstrate cross-talk between the androgen receptor signalingpathway and MEKK1 that results in transcriptional regulation ofandrogen receptor-regulated genes andapoptosis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cell culture and reagents. LNCaP, PC3, and DU145 human prostate cells were obtained from the American Type Culture Collection and maintained in phenolred-free RPMI with 10% fetal calf serum (FCS) or 10% charcoal-strippedFCS (Gemini, Thousand Oaks, Calif.). LAPC4 cells were derivedfrom a human prostate cancer xenograft implanted in SCID miceand express wild-type androgen receptor (exons 2 to 8) (29).LAPC4 cells were grown in Iscove's medium with 10% FCS. R1881was used as a synthetic androgen (DuPont-NEN), and Casodex wasused as an androgen receptor antagonist (ICI, Cheshire, UnitedKingdom).

Plasmids, transfections, and retroviral infections. The cDNAs for MEKK $Delta$ (MEKK-dominant active or MEKK $Delta$ -DA) and MEKK $Delta$ (K432M) (MEKK-dominant negative or MEKK $Delta$ -DN) (a kind giftof Michael Karin) were subcloned into pCDNA3 and the retroviralpSR $alpha$ MSV-tkNeo vector (36). MEKK $Delta$ is a truncated form of MEKK1in which amino acids 1 to 351 have been deleted and MEKK $Delta$ (K432M)contains a mutation in the ATP-binding site rendering it catalyticallyinactive. Cells were infected with amphotropically packaged retrovirusand selected in G418. Transient transfection of cells was performedby lipid-mediated gene transfer with Lipofectamine (Gibco-BRL)or TFX-50 (Promega, Madison, Wis.). Successful gene transfer wasconfirmed by cotransfection with a vector encoding enhanced greenfluorescent protein (GFP; Clontech). 2X-TRE-luciferase was usedto measure activator protein 1 activity. For androgen receptor-regulatedgene transcription, a 600-bp fragment of the prostate-specificantigen (PSA) promoter with an additional 2.4-kb enhancer sequencecloned upstream of luciferase (PSA P/E-luc) was used (39). Additionally,an androgen-regulated reporter vector was created by multimerizingfour consensus androgen receptor response elements from the PSApromoter (ARE-I) cloned upstream of the chloramphenicol acetyltransferase(CAT) gene in the pBXG0 vector and referred to as 4X-ARE/E4-CAT(a gift from Michael Carey). For the ZEBRA reporter experiments,pZRE-5/E4-CAT was used with pZEBRA driven by a simian virus 40enhancer (31). Full-length wild-type androgen receptor was expressedby using a cytomegalovirus-driven plasmid expression vector (agift of Marco Marcelli) (34). The plasmid pCDNA3-JBD was usedto inhibit JNK1 activity. This construct contains the domain ofJIP-1 that binds JNK-1 (JBD) cloned into pCDNA3 (14).

The protocol used for transfection of cell lines was as follows. Cells were plated at a density of 5 × 10⁵ cells in a 60-mm-diameter dish on the day prior to transfection.In all cases, the total amount of transfected DNA was kept constantwith control vector. For LNCaP and LAPC4 cells, TFX-50 (Promega)was used to transfect cells. A total of 4.4 µg of DNA and 20 µlof lipid reagent was added to the cells in Optimem (Gibco). Aftera 1-h incubation, medium containing 10% charcoal-stripped serumwas added to the cells. For DU145, PC3 and 293T cells, Lipofectamine(Gibco) was used to transfect cells. A total of 4.4 µg of DNAand 18 µl of lipofectamine was added to the cells in Optimem.After a 5-h incubation, medium containing 10% charcoal-strippedserum was added to the cells. In some cases, androgen (R1881)or Casodex was added with the medium containing 10% charcoal-strippedserum. Luciferase assays, CAT assays, and apoptosis measurementswere performed 48 h after transfection unless otherwisestated.

Reporter assays. Luciferase activity was measured with a Luciferase Assay Kit (Promega). Cells were lysed in 100 µl of 1× lysis buffer, and20 µl was used to react with luciferase substrate. Light unitswere measured with a luminometer. CAT activity was measured witha CAT enzyme-linked immunosorbent assay (ELISA) kit (Boehringer-Mannheim)or by conventional CAT assay as previously described (41). Sampleswere analyzed by thin-layer chromatography and exposed to a Stormphosphorimager screen. Radioactivity was quantitated by usingImageQuantsoftware.

Kinase assays and Western blots. JNK, ERK, and p38 kinase activity were measured as previously described (41). Briefly, equal numbers of cells were lysedin radioimmunoprecipitation assay buffer and JNK1 (sc474; SantaCruz), ERK1/2 (Zymed), or p38 (sc535-G; Santa Cruz) was immunoprecipitatedwith antibodies as indicated. Immunoprecipitates were reactedwith the substrates glutathione S-transferase (GST)-c-jun (1-79),myelin basic protein, or GST-ATF-2, respectively, in the presenceof [ $gamma$ -³²P]ATP and analyzed by sodium dodecyl sulfate (SDS)-10% polyacrylamidegel electrophoresis (PAGE). In indicated cases, FLAG-tagged JNK1was immunoprecipitated with anti-FLAG-conjugated beads (Sigma)and reacted with GST-jun as described above. For MEKK Westernblots, anti-MEKK1 was used at 0.5 µg/ml (sc252; Santa Cruz) withanti-rabbit horseradish peroxidase secondary (Jackson Laboratories).For androgen receptor Western blots, whole-cell lysates were analyzedby 8% PAGE and reacted with rabbit anti-human androgen receptorantibody (N-20, sc816; Santa Cruz) used at a 1:500dilution.

Apoptosis assays. Apoptosis was detected morphologically by using acridine orange or transfected GFP. A fluorescent microscope was used to count200 fluorescent cells per condition, and the percentage of blebbingcells was calculated. Cells were scored by an investigator blindedto the experimental condition. DNA staining of cells was performedwith Hoechst 33258. At 48 h after transient transfection, cellswere rinsed with phosphate-buffered saline, fixed with paraformaldehyde4% for 15 min, permeabilized with Triton X-100 0.5%, and thenstained in the dark with Hoechst dye at 2.5 µg/ml (53). Chromatincondensation was used as an additional morphologic marker of apoptosisin cells cotransfected withGFP.

Statistical analysis. Statistical analysis was performed by parametric analysis using the paired Student t test and MicrosoftExcel.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Expression of activated MEKK1 induces apoptosis in androgen receptor-positive but not in androgen receptor-negative prostate cancer cells. The androgen receptor-positive prostate cancer cell line LNCaP is a well-characterized model for the study of androgen receptor-mediatedgrowth and signal transduction (32, 48). We examined the roleof the stress-activated MAP kinase signaling pathway in LNCaPcells by utilizing retroviruses expressing a truncated, constitutivelyactive form of MEKK1 (MEKK $Delta$ -DA) and a catalytically inactive mutantcontaining a point mutation in the ATP binding site (MEKK $Delta$ -DN)(36). At 48 h after infection with retrovirus, MEKK $Delta$ -DA- andMEKK $Delta$ -DN-infected cells expressed similar levels of the truncatedMEKK1 protein (Fig. 1a). Biochemical characterization of LNCaPcells stably expressing MEKK $Delta$ -DA demonstrated selective activationof the JNK pathway (sixfold) over parental cells and minimal p38(twofold) or ERK activation (Fig. 1b). After antibiotic selection,populations of cells stably expressing MEKK $Delta$ -DA were derived.In five independent experiments, these cells consistently demonstratedreduced MEKK $Delta$ -DA protein expression compared with MEKK $Delta$ -DN (Fig.1a). These data suggest that high-level expression of MEKK $Delta$ -DAis not well tolerated in LNCaP cells, as reported previously infibroblasts (25, 51). To look directly for effects on growth,the LNCaP sublines were plated at equal densities, and cells werecounted after 5 days in culture. In five independent experimentsin which mass populations of cells were selected, LNCaP cellsexpressing MEKK $Delta$ -DA were difficult to expand compared with Neocontrol cells or MEKK $Delta$ -DN-expressing cells (Fig. 2b). These findingsdemonstrate that the expression of MEKK $Delta$ -DA impairs the expansionof LNCaP cells in vitro.

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FIG. 1. Biochemical characterization of LNCaP cells stably expressing mutant MEKK1. (a) MEKK1 immunoblot blot of LNCaP cells before and after G418 selection. LNCaP cells were infected with retrovirus pSR $alpha$ MEKK $Delta$ -DA or pSR $alpha$ MEKK $Delta$ -DN or Neo control virus. Whole-cell lysates were prepared from cells on the day after retroviral infection prior to G418 selection (unselected) or 2 weeks after G418 selection (G418-selected). The expression of truncated MEKK1 protein is similar in cells infected with pSR $alpha$ MEKK $Delta$ -DA or pSR $alpha$ MEKK-DN immediately after infection, suggesting similar viral titers. After G418 selection, however, surviving cells express lower amounts of MEKK $Delta$ -DA. Full-length MEKK1 is a 190-kDa protein not shown on this blot. This C-terminal-directed antibody recognizes a cleaved form of endogenous MEKK1 which runs at approximately 78-kDa and is the same in all lanes (5, 56). Equal protein loading was confirmed by protein assay and Ponceau S staining. (b) In vitro kinase assays of LNCaP sublines stably expressing MEKK isoforms as indicated. Cells expressing MEKK $Delta$ -DA show approximately sixfold activation of JNK activity compared with control cells but only twofold activation of p38 kinase activity. A JNK1 immunoblot demonstrates the relative amounts of immunoprecipitated JNK1 in the different sublines.

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FIG. 2. Effect of stable expression of MEKK $Delta$ -DA in prostate cancer cell lines. (a) MEKK immunoblot of DU145 and PC3 cells after infection with pSR $alpha$ MEKK $Delta$ -DA retrovirus or Neo control virus. Whole-cell lysates were prepared from cells 2 weeks after G418 selection. Equal protein loading was confirmed by protein assay and Ponceau S staining. (b) Change in cell number of prostate cancer cell lines stably expressing MEKK $Delta$ -DA. After antibiotic selection, DU145, PC3, and LNCaP sublines were plated at 100,000 cells per 60-mm-diameter plate, and the cell numbers were calculated after 5 days in culture. Data are expressed as the percentage of cells on day 5 in the sublines (Neo or MEKK $Delta$ -DA) compared with the parental line. Experiments were performed in duplicate, and this is one representative of three independently derived stable cell lines. (c) Cell cycle analysis of LNCaP cells stably expressing mutant MEKK isoforms. Subconfluent LNCaP cells growing in 10% FCS were permeabilized, stained with propidium iodide, and analyzed on a Becton Dickinson flow cytometer. There are no differences between MEKK $Delta$ -DA-expressing cells and Neo control cells with regard to G₁, S, and G₂ peaks.

To determine whether MEKK $Delta$ -DA functioned similarly in other prostate cancer cell lines, we extended our analysis to DU145and PC3 cells, which differ from LNCaP because they do not expressandrogen receptor and do not require androgen for growth. DU145and PC3 cells were infected with retrovirus expressing MEKK $Delta$ -DAor Neo control, and sublines which expressed MEKK $Delta$ -DA were derivedby antibiotic selection (Fig. 2a). Unlike LNCaP cells, there wasno difficulty in expanding MEKK $Delta$ -DA-expressing DU145 and PC3 cells.To assess the effect of MEKK $Delta$ -DA on PC3 and DU145 growth, eachsubline was plated at an equal density, and cell counts were determinedafter 5 days and compared to Neo control sublines. In contrastto LNCaP cells, MEKK $Delta$ -DA expression did not impair the growthof PC3 or DU145 cells in three experiments with independentlyselected sublines (Fig. 2c). We then asked whether our difficultyin expanding the LNCaP cells which stably express MEKK $Delta$ -DA wasdue to cell cycle arrest or an increase in cell death. Cell cycleanalysis of propidium iodide-stained MEKK $Delta$ -DA cells showed nodifferences in the percentage of cells in G₁, S, or G₂ comparedwith the Neo control (Fig. 2c). However, when the morphology ofthe cells was examined after staining with acridine orange, wenoted changes in LNCaP cells stably expressing MEKK $Delta$ -DA, suchas cytoplasmic blebbing and detachment, that are suggestive ofapoptosis.

To determine whether MEKK $Delta$ -DA induces apoptosis in LNCaP cells, a quantitative, short-term transient-transfection assay wasutilized. LNCaP cells were transiently cotransfected with MEKK $Delta$ -DAand a vector expressing GFP to visualize the morphology of thetransfected cells. Approximately 25% of GFP-positive cells cotransfectedwith MEKK $Delta$ -DA showed cytoplasmic blebbing, a morphologic featureof apoptosis, whereas GFP-positive cells cotransfected with controlvector or kinase-inactive MEKK $Delta$ -DN did not (Fig. 3). Our conclusionthat MEKK1 induces apoptosis was confirmed independently by thedemonstration of chromatin condensation in a high fraction ofGFP-positive cells in plates transfected with MEKK $Delta$ -DA but notwith the control Neo vector (Fig. 3c). We conclude that the difficultyin expanding LNCaP cells expressing MEKK $Delta$ -DA is most likely aresult of the induction of apoptosis, a finding similar to thoseof earlier studies with fibroblasts and T cells (16, 25).

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FIG. 3. Effect of transient MEKK $Delta$ -DA expression on apoptosis in androgen receptor-negative and androgen receptor-positive prostate cancer cell lines. (a) LNCaP cells were transiently transfected with GFP (0.4 µg) and cotransfected with Neo or MEKK $Delta$ -DA (0.6 µg), and the total amount of transfected DNA (4 µg) was kept constant with Neo control vector. DU145, PC3, and LAPC4 cells were transfected with 3.6 µg of pCDNA3 Neo or MEKK $Delta$ -DA and cotransfected with GFP (0.4 µg). Apoptotic cells demonstrate cytoplasmic blebbing (arrows). Cells were scored for apoptosis 48 h after transfection. The transfection efficiencies for each cell line are as follows: LNCaP Neo, 40 to 50%; MEKK $Delta$ -DA, 40 to 50%; DU145 Neo, 20 to 30%; MEKK $Delta$ -DA, 20 to 30%; PC3 Neo, 30 to 40%; MEKK $Delta$ -DA, 30 to 40%; LAPC4 Neo, 20 to 30%; MEKK $Delta$ -DA, 20 to 30%. (b) Graph represents three independent experiments in which 200 green fluorescent cells were counted and scored for cytoplasmic blebbing 48 h after transfection. For LNCaP cells, these experiments were also performed with transfected kinase-inactive MEKK $Delta$ -DN (3 µg) which did not induce apoptosis. (c) LNCaP cells were transiently transfected with GFP (0.4 µg) and cotransfected with Neo or MEKK $Delta$ -DA (0.6 µg), and the total amount of transfected DNA (4 µg) was kept constant with Neo control vector. DU145 cells were transfected with 3.6 µg of pCDNA3 Neo or MEKK $Delta$ -DA and cotransfected with GFP (0.4 µg). At 48 h after transfection, cells were stained with the DNA dye Hoechst 33258, and GFP-positive cells were scored for chromatin condensation. There was no increase in chromatin condensation in DU145 cells transfected with Neo or MEKK $Delta$ -DA. White arrows indicate GFP-positive cells, and yellow arrows indicate GFP-positive cells showing chromatin condensation.

Next, we analyzed the effect of MEKK $Delta$ -DA expression on apoptosis in androgen receptor-negative DU145 cells and PC3 cells byusing the transient-cotransfection assay described above. In contrastto LNCaP cells, there was no increase in the morphologic featuresof apoptosis in DU145 cells or PC3 cells expressing MEKK $Delta$ -DA at48 h after transfection (Fig. 3). We extended the analysis inPC3 and DU145 cells to 72 and 96 h after transient transfectionwith MEKK $Delta$ -DA to look for delayed effects on apoptosis, but wecontinued to find no differences in apoptosis between Neo- andMEKK $Delta$ -DA-transfected cells (data not shown). These data demonstratethat the ability of MEKK $Delta$ -DA to impair growth or induce apoptosisis restricted to certain prostate cancer celllines.

Because MEKK $Delta$ -DA-induced apoptosis occurred in the androgen receptor-positive LNCaP cell line but not in two androgen receptor-negativeprostate cell lines, we analyzed the effect of MEKK $Delta$ -DA in anothermodel of androgen receptor-positive prostate cancer developedin our laboratory (29). LAPC4 cells express wild-type androgenreceptor (exons 2 to 8) and secrete PSA. Similar to LNCaP, transienttransfection of MEKK $Delta$ -DA induced apoptosis in LAPC4 cells (Fig.3). These data suggest that androgen receptor-positive prostatecancer cells are sensitive to MEKK $Delta$ -DA-induced apoptosis, whereasandrogen receptor-negative cells arenot.

MEKK $Delta$ -DA-induced apoptosis is JNK independent but caspase dependent. One reason for the failure of DU145 and PC3 cells to undergo apoptosis may be a defect in the ability of MEKK $Delta$ -DA to activatethe JNK pathway in these cells. To address this question, we testedthe ability of MEKK $Delta$ -DA to activate JNK and AP-1 transcriptionalactivity in androgen receptor-positive and androgen receptor-negativecell lines. To allow for differences in transfection efficienciesbetween prostate cancer cell lines, we transfected LNCaP, DU145,and PC3 cells with MEKK $Delta$ -DA and FLAG-tagged JNK1 and performedan in vitro kinase assay with anti-FLAG immunoprecipitated JNK1(Fig. 4a). As expected, an anti-FLAG immunoblot showed differentlevels of immunoprecipitated FLAG-JNK1 protein from the threecell lines, a finding consistent with distinct transfection efficiencies.However, JNK was activated four- to sixfold by MEKK $Delta$ -DA in allthree cell lines when adjusted to the level of immunoprecipitatedJNK protein. Cotransfection of the 2X-TRE-luciferase reporterconstruct revealed similar findings of AP-1 activation in responseto the transfection of MEKK $Delta$ -DA in all three cell lines (datanot shown). These data demonstrate that MEKK $Delta$ -DA is capable ofJNK activation in prostate cancer cell lines regardless of theirsensitivity to MEKK $Delta$ -DA-induced apoptosis.

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FIG. 4. Role of JNK activation in MEKK $Delta$ -DA-induced apoptosis. (a) Comparison of JNK activation in prostate cancer cell lines in response to MEKK $Delta$ -DA. LNCaP, DU145, and PC3 cells were transfected with FLAG-tagged JNK1 (2 µg) and cotransfected with Neo or MEKK $Delta$ -DA (2 µg). The top panel shows a JNK assay in which 100 µg of total cellular protein was immunoprecipitated with anti-FLAG antibody and reacted with GST-c-jun. The bottom panel shows an anti-FLAG immunoblot. LNCaP cells have approximately sixfold-higher amount of transfected JNK1 than DU145 cells as determined by densitometry analysis. When corrected for this difference in transfected protein, MEKK $Delta$ -DA-induced JNK activation is approximately four- to sixfold in all three cell lines. (b) Effect of JNK inhibition on MEKK $Delta$ -DA-induced apoptosis in LNCaP cells. LNCaP cells were cotransfected with MEKK $Delta$ -DA (0.6 µg) or Neo and pCDNA3-JBD (JNK1 inhibitor), p35 (caspase inhibitor), or vector control. (Left panel) Effect of transfected JBD on MEKK $Delta$ -DA-induced c-jun transcriptional activity as measured by a 5X-Gal-luciferase reporter (0.4 µg) and gal4-jun (0.4 µg). (Right panel) Transfected cells were scored for apoptosis 48 h after transfection.

To directly test the role of the JNK pathway in MEKK-mediated apoptosis in androgen receptor-positive cell lines, we examinedthe effects of JNK inhibition in the transient-transfection assay.LNCaP cells were cotransfected with MEKK $Delta$ -DA and JBD, a truncatedform of JIP-1, a selective inhibitor of JNK1 (14). As suspectedfrom related studies in other cell types, JBD inhibited MEKK $Delta$ -DA-mediatedactivation of jun as measured by a gal4-jun reporter system, thusconfirming the activity of JBD in LNCaP cells. However, JBD failedto block MEKK $Delta$ -DA-mediated apoptosis, whereas cotransfection ofthe baculovirus-derived caspase inhibitor p35 did (57) (Fig.4b). Taken together, these data indicate that MEKK $Delta$ -DA-inducedapoptosis is JNK independent but caspase dependent. This conclusionis in agreement with recent studies of MEKK function in fibroblasts(25, 51).

Modulation of androgen receptor function influences the sensitivity of MEKK $Delta$ -DA-induced apoptosis. A major difference between the prostate cancer cell lines sensitive to MEKK1-induced apoptosis and those resistant to MEKK1-inducedapoptosis is the presence of a functional androgen receptor pathway.The LNCaP and LAPC4 prostate cancer cell lines express the androgenreceptor, whereas DU145 and PC3 do not. Based on these observations,we hypothesized that the androgen receptor pathway may be requiredfor MEKK1-induced apoptosis in prostate cancer cells. We usedthree approaches to test this hypothesis: reconstitution of theandrogen receptor pathway in androgen receptor-negative cells,pharmacologic inhibition of the androgen receptor pathway in androgenreceptor-positive cells, and amplification of androgen receptorsignaling in androgen receptor-positive cells. First, we reconstitutedthe androgen receptor pathway in DU145 cells by transfecting androgenreceptor and treating the cells with androgen. Expression of wild-typeandrogen receptor with or without androgen did not induce significantlevels of apoptosis (Fig. 5a). Expression of MEKK $Delta$ -DA with theandrogen receptor in the absence of ligand also did not resultin apoptosis. However, the combination of MEKK $Delta$ -DA, androgen receptor,and androgen did induce apoptosis in a dose-response manner, asincreasing doses of MEKK $Delta$ -DA induced more apoptosis with a fixedamount of androgen receptor (Fig. 5a). Kinase-inactive MEKK $Delta$ -DNfailed to induce apoptosis in this assay, indicating that kinaseactivity is required (Fig. 5b). These data demonstrate that reconstitutionof the androgen receptor pathway rescues the apoptosis defectin DU145 cells and support the hypothesis that the androgen receptorpathway is required for MEKK $Delta$ -DA-induced apoptosis in prostatecancer cells. The fact that additional ligand is required forMEKK $Delta$ -DA-induced apoptosis in DU145 cells but not LNCaP cellsmay be a consequence of androgen receptor overexpression or cell-typedifferences.

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FIG. 5. Modulation of androgen receptor function alters the sensitivity of prostate cancer cells to MEKK $Delta$ -DA-induced apoptosis. Reconstitution of the androgen receptor signaling pathway in DU145 cells. DU145 cells were cotransfected with MEKK $Delta$ -DA, as indicated, and androgen receptor (AR) (1.8 µg) in the presence or absence of androgen R1881 (10 nM). This graph is an average of the results from eight independent experiments. The P value for the combined experiments is 0.002 as determined by the paired Student t test for MEKK $Delta$ -DA plus androgen receptor plus R1881 versus MEKK $Delta$ -DA plus androgen receptor. (b) Morphology of DU145 reconstituted with androgen receptor and androgen R1881 and cotransfected with MEKK $Delta$ -DN (top row) or MEKK $Delta$ -DA (bottom row) 48 h after transfection. White arrows indicate GFP-positive cells, and yellow arrows indicate GFP-positive cells showing chromatin condensation. (c) Effect of the androgen receptor antagonist Casodex on MEKK $Delta$ -DA-induced apoptosis. Graph of LNCaP transfected with 0.6 µg of MEKK $Delta$ -DA or Neo control vector and treated with the androgen receptor antagonist Casodex (10 µM) as indicated. Graph represents results of four independent experiments in which 200 green fluorescent cells were counted and scored for cytoplasmic blebbing; P = 0.004 as determined by the paired Student t test for MEKK $Delta$ -DA versus MEKK $Delta$ -DA plus Casodex. Cells were scored for apoptosis at 48 h after transfection. (d) Graph of LNCaP transfected with 0.6 µg of pCDNA3 containing MEKK $Delta$ -DA or the empty vector and cotransfected with androgen receptor (1.8 µg) as indicated. Graph represents three independent experiments in which 200 green fluorescent cells were counted and scored for cytoplasmic blebbing at 48 h after transfection; P = 0.01 as determined by the paired Student t test for MEKK $Delta$ -DA versus MEKK $Delta$ -DA plus androgen receptor.

A corollary to the hypothesis that MEKK $Delta$ -DA-induced apoptosis in prostate cancer cells requires functional androgen receptoris that blockade of androgen receptor signaling should protectagainst MEKK $Delta$ -DA-induced apoptosis in androgen receptor-positiveprostate cancer cells. We tested this hypothesis pharmacologicallyby using the androgen receptor antagonist casodex (49). To establishthe activity of Casodex in our model, LNCaP cells were transfectedwith a reporter plasmid containing the promoter (P) and enhancer(E) of the androgen-dependent PSA gene fused to luciferase (PSAP/E-luc) (39). PSA is a prostate-specific, secreted kallikreinprotein that is widely used as a serum marker to diagnose andmonitor prostate cancer in patients (20). The promoter and enhancerboth contain well-characterized androgen receptor binding siteswhich mediate androgen responsiveness (7, 44). Since theexpression of PSA is androgen dependent, anti-androgen therapycauses a drop in PSA levels in serum, whereas relapse of androgen-independentcancer is heralded by a rise in PSA in serum. As expected, theandrogen analog R1881 induced 13-fold activation of PSA P/E-lucin LNCaP cells (Fig. 6a) (39). Casodex partially inhibited PSAP/E-luc induction by ca. 40% (Fig. 6a, compare fourth and eighthcolumns). In the apoptosis experiments, the same concentrationof Casodex partially inhibited MEKK $Delta$ -DA-induced apoptosis by 40%and did not by itself induce apoptosis in parental LNCaP cells(Fig. 5c). The effect of Casodex was specific for androgen receptor-positivecells because Casodex had no effect on androgen receptor-independent,MEKK $Delta$ -DA-mediated apoptosis of HEK293 cells (data not shown).Together with the androgen receptor reconstitution experiments,these data argue for a link between the androgen receptor andthe MEKK $Delta$ -DA pathway leading to apoptosis in prostate cancer cells.

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FIG. 6. MEKK $Delta$ -DA increases the transcriptional activity of androgen receptor-regulated promoters. (a) Graph of PSA P/E-luc transcriptional activity in LNCaP cells. LNCaP cells were transfected with MEKK $Delta$ -DA (0.6 µg) or MEKK $Delta$ -DN or Neo control vector (3.6 µg) and cotransfected with a PSA P/E-luc reporter construct (0.4 µg). R1881 was added to a final concentration of 10 nM, and Casodex was added at a final concentration of 10 µM. This graph represents an average of six independent experiments; P = 0.009 as determined by the paired Student t test for MEKK $Delta$ -DA compared to the control. (b) Graph of PSA P/E-luc transcriptional activity in DU145. DU145 were cotransfected with MEKK $Delta$ -DA or Neo control vector (1.6 µg), androgen receptor (1.8 µg), and PSA-luc reporter (0.4 µg). R1881 was added to a final concentration of 10 nM. Luciferase activity was measured 48 h after transfection. This graph represents an average of six experiments; P = 0.01 for MEKK $Delta$ -DA versus MEKK $Delta$ -DA plus androgen receptor.

Since pharmacologic inhibition of androgen receptor function diminished MEKK $Delta$ -DA-induced apoptosis, we reasoned that moreandrogen receptor expression in androgen receptor-positive cellsmay increase their sensitivity to MEKK $Delta$ -DA-induced apoptosis.To test this hypothesis, LNCaP cells were transfected with wild-typeandrogen receptor in the presence or absence of MEKK $Delta$ -DA (Fig.5d). Overexpression of androgen receptor did not cause apoptosisabove control levels. Coexpression of androgen receptor and MEKK $Delta$ -DAinduced apoptosis in over 40% of the cells, a significant increasecompared to the expression of MEKK $Delta$ -DA alone. These data indicatethat overexpression of androgen receptor in cells with an intactandrogen receptor pathway enhances MEKK $Delta$ -DA-inducedapoptosis.

One potential mechanism of MEKK $Delta$ -DA-induced apoptosis in LNCaP cells is an alteration in the level of androgen receptor expressionin androgen receptor-positive prostate cancer cells. To addressthis issue, androgen receptor expression was measured by immunoblotin LNCaP cells transfected with Neo or MEKK $Delta$ -DA, LNCaP cells transfectedwith additional androgen receptor, and LNCaP cells stably infectedwith MEKK $Delta$ -DA or control virus. No differences were seen in theendogenous expression of androgen receptor in LNCaP cells transientlyor stably expressing MEKK $Delta$ -DA (data not shown); therefore, MEKK $Delta$ -DAdoes not regulate endogenous androgen receptorexpression.

Activation of the MEKK1 pathway stimulates androgen-receptor regulated gene expression. Activation of the tyrosine kinase receptors for KGF and IGF-1 or protein kinase A activation increases androgen receptor-mediatedgene transcription in the absence of androgen, suggesting cross-talkwith the androgen receptor pathway (11, 38). Because MEKK $Delta$ -DAinduces apoptosis in prostate cancer cells in an androgen receptor-dependentfashion, we hypothesized that MEKK1 signaling may also affectandrogen receptor-mediated gene transcription. To test this hypothesis,LNCaP cells were transfected with the PSA P/E-luc reporter plasmiddescribed above and cotransfected with MEKK $Delta$ -DA in the presenceor absence of androgen. Experiments were performed in medium containingcharcoal-stripped serum to exclude potential effects of steroidhormones in FCS. MEKK $Delta$ -DA activated the reporter 14-fold in theabsence of androgen (Fig. 6a). Thus, the expression of MEKK $Delta$ -DAresults in androgen-independent PSA transcriptional activationthat is similar in magnitude to the treatment of cells with androgen.The combination of MEKK $Delta$ -DA and androgen led to further activationof PSA P/E-luc transcription (average fold induction of 30). Totest whether transcriptional activation of PSA P/E-luc by MEKK $Delta$ -DArequired its kinase activity, LNCaP cells were transiently transfectedwith kinase inactive MEKK $Delta$ -DN. MEKK $Delta$ -DN had no effect on transcriptionalactivation, demonstrating that the kinase activity of MEKK1 isrequired for thiseffect.

We explored the role of the androgen receptor in MEKK $Delta$ -DA induction of PSA transcriptional activity by using two complementarystrategies. First, we asked if the androgen receptor antagonistCasodex inhibited MEKK $Delta$ -DA activation of PSA P/E-luc in LNCaPcells. PSA P/E-luc activity in cells cotransfected with MEKK $Delta$ -DAwas reduced by Casodex from 14-fold to 4-fold (Fig. 6a, comparesecond and seventh columns). These results suggest that ligand-independentactivation of the PSA promoter-enhancer by MEKK $Delta$ -DA is mediatedby the androgen receptor. To confirm this hypothesis we performedfurther experiments in androgen receptor-negative DU145 cells.The absence of endogenous androgen receptor expression in DU145allowed us to study the effect of MEKK $Delta$ -DA on the PSA promoter-enhancerin the presence or absence of transfected androgen receptor. Androgeninduced activation of PSA P/E-luc a modest twofold when androgenreceptor was included in the transfection (Fig. 6b), a resultconsistent with previous reports (55). Transfection of MEKK $Delta$ -DAin the absence of androgen receptor also activated PSA P/E-luctwofold. However, the combination of androgen receptor and MEKK $Delta$ -DAresulted in an average eightfold activation which was not enhancedfurther by androgen. In conjunction with the Casodex experiments,these data indicate that the effect of MEKK $Delta$ -DA on PSA transcriptionalactivity requires the androgenreceptor.

In addition to androgen receptor binding sites (AREs), the PSA promoter contains other transcription factor binding motifs,such as AP-1 recognition sites (46). Since MEKK $Delta$ -DA activatestranscription factors such as AP-1, a potential mechanism forcross-talk between MEKK $Delta$ -DA signaling and the androgen receptorpathway is through cooperative effects between AP-1 sites andAREs in the PSA promoter and enhancer (8). Alternatively, MEKK $Delta$ -DA-mediatedinduction of the PSA promoter may function solely through activationof the androgen receptor. We addressed this issue by examiningthe effect of MEKK $Delta$ -DA on an artificial promoter consisting offour AREs multimerized upstream of the E4-CAT reporter gene (4X-ARE/E4-CAT)in DU145 cells. In the absence of transfected androgen receptor,neither MEKK $Delta$ -DA nor androgen activated the 4X-ARE/E4-CAT reporter(Fig. 7a). Androgen activated the 4X-ARE/E4-CAT reporter 38-foldafter reconstitution with androgen receptor. Cotransfection ofandrogen receptor and MEKK $Delta$ -DA enhanced activation of the reporterfrom 38-fold to 170-fold in the presence of ligand. These effectsare specific to AREs because MEKK $Delta$ -DA had no effect on the parentalE4-CAT reporter pBXG0, which lacks the AREs (Fig. 7b, lanes 1and 2) or on the pZRE5-E4-CAT reporter in which the ARE siteswere replaced with sites for the Epstein-Barr virus (EBV) transcriptionfactor ZEBRA (Fig. 7b, lanes 3 and 4). These data indicate thatthe effect of MEKK $Delta$ -DA on androgen receptor-mediated gene activationcan be mediated through AREs in the absence of AP-1 sites. Incontrast to the ligand-independent effects of MEKK $Delta$ -DA in thecontext of the natural PSA promoter, ligand binding of androgento androgen receptor is required to mediate the effect of MEKK $Delta$ -DAon an artificial template containing only AREs. These differencesmay be a consequence of additional, ARE-independent effects ofthe PSA promoter. Alternatively, the effects of MEKK1 on thesereporters, as well as apoptosis, may not be strictly correlated.

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FIG. 7. MEKK $Delta$ -DA specifically increases the transcriptional activity of androgen receptor on a minimal promoter element. (a) Effect of MEKK $Delta$ -DA on transcriptional activation of a promoter consisting of pure androgen response elements in DU145. A promoter consisting of four multimerized androgen response elements, 4X-ARE/E4-CAT (0.4 µg) was transfected into DU145 as in Fig. 6b. CAT production was analyzed by ELISA as described in Materials and Methods and by conventional CAT assay. ImageQuant software was used to analyze phosphorimager data for the conventional CAT assay. This is one representative experiment of four total. (b) Effect of MEKK $Delta$ -DA on the transcriptional activation of a promoter consisting of ZEBRA response elements in DU145 cells. For these experiments, DU145 stably expressing androgen receptor or Neo-infected cells were transfected with the vectors as indicated: 0.8 µg of reporter plasmid, 0.8 µg of ZEBRA transcription factor, and 2.4 µg of MEKK $Delta$ -DA or Neo vector control. The data shown were obtained with androgen receptor-expressing DU145 cells.

One potential explanation for the enhanced transcriptional activation of androgen receptor-regulated genes by MEKK $Delta$ -DA isthat MEKK $Delta$ -DA is having nonspecific effects on the general transcriptionmachinery. To test this possibility, we examined the effects ofMEKK $Delta$ -DA on another reporter system based on the EBV-derived transcriptionfactor ZEBRA. This system is ideal for addressing the specificityof MEKK $Delta$ -DA-induced transcriptional activation because the relationshipbetween ZEBRA, its binding to core promoter elements, and theactivation of the general transcription machinery have been carefullycharacterized (31). If MEKK $Delta$ -DA acts nonspecifically, we wouldexpect enhanced activation of pZRE5-E4-CAT in the presence ofMEKK $Delta$ -DA. However, MEKK $Delta$ -DA had no effect on ZEBRA-mediated inductionof pZRE5-E4-CAT (Fig. 7b, lanes 5 and 6). These data argue forspecificity in the effects of MEKK $Delta$ -DA on androgen receptor-mediatedtranscription.

Based on our finding that MEKK $Delta$ -DA-induced apoptosis of prostate cancer cells is dependent on androgen receptor signalingand that MEKK $Delta$ -DA activates androgen receptor-dependent transcription,we sought to determine whether the MEKK signaling pathway playsa role in ligand-mediated activation of the androgen receptorin prostate cells. To test this possibility, we measured the effectsof the dominant negative mutant, MEKK $Delta$ -DN, on androgen-regulatedgene expression (36). As expected, MEKK $Delta$ -DA activated the PSAP/E-luc reporter in LNCaP cells. To validate the ability of MEKK $Delta$ -DNto function as an MEKK antagonist, LNCaP cells were cotransfectedwith MEKK $Delta$ -DA and MEKK $Delta$ -DN (Fig. 8, left panel). MEKK $Delta$ -DN inhibitedMEKK $Delta$ -DA-induced transcriptional activation of the PSA P/E-lucreporter between 50 and 75%. We then tested the ability of MEKK $Delta$ -DNto inhibit androgen-mediated PSA P/E-luc activation. In four independentexperiments, MEKK $Delta$ -DN inhibited R1881-induced transcriptionalactivation of the PSA P/E-luc reporter in a dose-dependent fashion(Fig. 8, right panel). When similar experiments were performedwith the 4X-ARE-CAT reporter in DU145 cells, we failed to seesignificant effects of MEKK $Delta$ -DN on R1881-mediated activation ofthis reporter (data not shown). Therefore, the inhibitory effectsof MEKK $Delta$ -DN on the PSA P/E-luc reporter may be related to cis-actingelements which influence the outcome of androgen receptor activationin the context of a natural promoter.

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FIG. 8. Expression of MEKK $Delta$ -DN inhibits androgen-mediated activation of PSA P/E-luc. (Left panel) Effect of MEKK $Delta$ -DN on MEKK $Delta$ -DA-induced PSA P/E-luc activity. LNCaP cells were transfected with MEKK $Delta$ -DA (0.6 µg) and cotransfected with 3.6 µg (6:1 ratio) of MEKK $Delta$ -DN as indicated. This is one representative experiment of three total, all with similar results. (Right panel) Effect of increasing amounts of MEKK $Delta$ -DN on R1881-induced PSA P/E-luc activity. LNCaP cells were transfected with increasing amounts of MEKK $Delta$ -DN as indicated in the presence of R1881 (10 nM). This is one representative experiment of four total, all with similar results.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Previous work on MEKK1 function has defined a role for this pathway in signaling involving the stress response (6, 13),NF- $kappa$ B activation (30, 56), and integrin receptor engagement(5, 18). Results presented here provide evidence of a rolein androgen receptor signaling in prostate cells. At a transcriptionallevel a constitutively active allele of MEKK1 stimulates naturaland artificial androgen-responsive promoter templates in an androgenreceptor-dependent fashion. In addition, transcriptional activationof the androgen receptor by androgen is impaired when a dominantnegative mutant of MEKK1 is coexpressed. Taken together, theseresults suggest that the MEKK1 pathway plays a role in modulatingthe transcriptional response of the androgen receptor to ligands.Importantly, this cross-talk extends beyond the level of transcriptionto the biological response of cells to MEKK1 signaling. Consistentwith previous reports in fibroblasts and T cells (16, 25),constitutive activation of MEKK1 induces apoptosis in prostatecancer cells. However, the apoptotic effect in prostate cellsoccurs only when the androgen receptor signaling pathway is intact.The evidence supporting this conclusion are the correlation ofMEKK $Delta$ -DA-induced apoptosis with androgen receptor expression,the ability of androgen receptor expression to restore the abilityof MEKK $Delta$ -DA to induce apoptosis in androgen receptor-negativeprostate cancer cells, the potentiation of MEKK $Delta$ -DA-induced apoptosisby overexpression of androgen receptor in androgen receptor-positiveprostate cancer cells, and the partial inhibition of MEKK $Delta$ -DA-inducedapoptosis by androgen receptor blockade. In summary, our resultsestablish a pattern of cross-talk between the MEKK1 and the androgenreceptor pathways in prostate cells at a transcriptional and biologicallevel.

The discovery of an interaction between the androgen receptor and MEKK1 signaling pathways adds to growing evidence that anumber of different tyrosine and serine-threonine kinases canaffect the function of steroid hormone receptors (4, 10,11, 27). The molecular basis for each distinct example ofcross-talk remains unknown and is the focus of much current research.A better understanding of this mechanism is likely to have importantimplications for hormone receptor regulation in cancer cells.In the case of MEKK1, its large size (196 kDa) and known abilityto assemble in multiprotein complexes (12, 30, 56), as wellas to interact with an array of signaling proteins (15, 54,56), raise the possibility of a multiprotein signaling complexinvolving the androgen receptor in prostate cells. Alternatively,MEKK1 may activate a signaling cascade that indirectly leads toposttranslational modifications of the androgen receptor whichaffect its function, a possibility analogous to reported effectsof the ERK pathway on the estrogen receptor (4, 24, 27,58). It is also possible that MEKK1 affects coactivators, suchas ARA-70 and GRIP-1 (22, 55), rather than androgen receptoritself or that it functions through transcription factors, suchas c-jun (3, 43, 52), which act cooperatively with theandrogen receptor to facilitate gene expression. More researchis needed to sort through these variousmodels.

MEKK1-induced apoptosis is known to occur in non-androgen-receptor-expressing cells such as fibroblasts (25), human embryonalkidney cells, and fibrosarcoma cells (51). In some settings,UV irradiation, chemotherapy, or tumor necrosis factor $alpha$ are requiredto elicit the apoptotic phenotype, suggesting that MEKK1-inducedapoptosis may require additional signals to initiate the apoptoticcascade. Our results would argue that androgen receptor signalingmay be such a signal in prostate cells. This idea may seem paradoxicalsince androgen confers a survival and/or proliferative signalin prostate secretory epithelial cells. However, excess androgenreceptor signaling in certain settings is detrimental to cellgrowth and survival. For example, androgen inhibits the growthof androgen receptor-positive LNCaP cells at high concentrationsin vitro (48), and androgen receptor-negative PC3 cells transfectedwith a constitutively active androgen receptor have delayed growthcompared with mock-transfected cells (33). Consistent with thesereports, we find that excess androgen induces low levels of apoptosisin LNCaP cells in vitro (1). We hypothesize that excess stimulationof the androgen receptor signaling pathway, through MEKK1 activationor excess androgen, can lead to apoptosis of prostate cancer cells.This scenario is consistent with more extensively characterizedsignaling molecules such as the glucocorticoid receptor (17,21) and c-Myc (1a, 45), which can induce either cell cycleprogression or apoptosis in distinct cellular or environmentalcontexts.

In addition to the implications for hormone receptor signaling, our results offer potential insight into the mechanisms ofprostate cancer progression. Anti-androgen therapy is the primaryclinical treatment of metastatic prostate cancer and induces temporaryremissions in the majority of patients. Eventually, prostate cancercells regrow despite anti-androgen therapy, and the majority continueto express androgen receptor (40) and androgen-regulated genessuch as PSA. This phenotype suggests that alternative, androgen-independentsignaling pathways are utilized to activate the androgen receptorin these cells. Our observation that MEKK1 can substitute forandrogen in androgen receptor-dependent transcription raises thepossibility that this pathway may function in the progressionto androgen independence. Further experiments with animal modelsand clinical material are required to address this hypothesis.Alternatively, the androgen receptor-dependent apoptotic functionof activated MEKK1 in prostate cells might provide a therapeuticopportunity in androgen-independent prostate cancers. Becauseof its ability to sensitize cells to genotoxic stress (25, 51),expression of MEKK1 may be considered a strategy for cancer genetherapy.

	ACKNOWLEDGMENTS

We thank Michael Carey and Yuriy Shostak for assistance and reagents used to perform 4X-ARE/E4-CAT experiments and the ZEBRAreporter assay. We thank David Chang for use of a fluorescentmicroscope and helpful discussions. We thank Michael Karin, MarcoMarcelli, and Arie Belldegrun for providing necessaryplasmids.

This work was supported by grants from the James S. McDonnell Foundation, the Margaret Early Trust, and CapCURE. M.T.A.-M.was supported by a Crohn's and Colitis Foundation of America CareerDevelopment Award. A.C. was supported by a Howard Hughes MedicalInstitute Medical Student ResearchFellowship.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Medicine, 11-934 Factor Bldg., Box 951678, UCLA Division of Hematology-Oncology,10833 LeConte Ave., Los Angeles, CA 90095. Phone: (310) 206-5585.Fax: (310) 206-8502. E-mail: csawyers{at}med1.medsch.ucla.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Abreu-Martin, M. T., and C. L. Sawyers. Unpublished data.

1a. Amati, B., and H. Land. 1994. Myc-Max-Mad: a transcription factor network controlling cell cycle progression, differentiation and death. Curr. Opin. Genet. Dev. 4:102-108[Medline].

2. Brandstrom, A., P. Westin, A. Bergh, S. Cajander, and J. E. Damber. 1994. Castration induces apoptosis in the ventral prostate but not in an androgen-sensitive prostatic adenocarcinoma in the rat. Cancer Res. 54:3594-3601[Abstract/Free Full Text].

3. Bubulya, A., S. C. Wise, X. Q. Shen, L. A. Burmeister, and L. Shemshedini. 1996. c-Jun can mediate androgen receptor-induced transactivation. J. Biol. Chem. 271:24583-24589[Abstract/Free Full Text].

4. Bunone, G., P. A. Briand, R. J. Miksicek, and D. Picard. 1996. Activation of the unliganded estrogen receptor by EGF involves the MAP kinase pathway and direct phosphorylation. EMBO J. 15:2174-2183[Medline].

5. Cardone, M. H., G. S. Salvesen, C. Widmann, G. Johnson, and S. M. Frisch. 1997. The regulation of anoikis: MEKK-1 activation requires cleavage by caspases. Cell 90:315-323[Medline].

6. Chen, Y. R., X. Wang, D. Templeton, R. J. Davis, and T. H. Tan. 1996. The role of c-Jun N-terminal kinase (JNK) in apoptosis induced by ultraviolet C and gamma radiation. Duration of JNK activation may determine cell death and proliferation. J. Biol. Chem. 271:31929-31936[Abstract/Free Full Text].

7. Cleutjens, K. B., H. A. van der Korput, C. C. van Eekelen, H. C. J. van Rooij, P. W. Faber, and J. Trapman. 1997. An androgen response element in a far upstream enhancer region is essential for high, androgen-regulated activity of the prostate-specific antigen promoter. Mol. Endocrinol. 11:148-161[Abstract/Free Full Text].

8. Cleutjens, K. B., C. C. van Eekelen, H. A. van der Korput, A. O. Brinkmann, and J. Trapman. 1996. Two androgen response regions cooperate in steroid hormone regulated activity of the prostate-specific antigen promoter. J. Biol. Chem. 271:6379-6388[Abstract/Free Full Text].

9. Colombel, M., S. Gil Diez, F. Radvanyi, R. Buttyan, J. P. Thiery, and D. Chopin. 1996. Apoptosis in prostate cancer. Molecular basis to study hormone refractory mechanisms. Ann. N. Y. Acad. Sci. 784:63-69[Medline].

10. Craft, N., Y. Shostak, M. Carey, and C. L. Sawyers. 1999. A mechanism for hormone-independent prostate cancer through modulation of androgen receptor signaling by the HER-2/neu tyrosine kinase. Nat. Med. 5:280-285[Medline].

11. Culig, Z., A. Hobisch, M. V. Cronauer, C. Radmayr, J. Trapman, A. Hittmair, G. Bartsch, and H. Klocker. 1994. Androgen receptor activation in prostatic tumor cell lines by insulin-like growth factor-I, keratinocyte growth factor, and epidermal growth factor. Cancer Res. 54:5474-5478[Abstract/Free Full Text].

12. Deak, J. C., J. V. Cross, M. Lewis, Y. Qian, L. A. Parrott, C. W. Distelhorst, and D. J. Templeton. 1998. Fas-induced proteolytic activation and intracellular redistribution of the stress-signaling kinase MEKK1. Proc. Natl. Acad. Sci. USA 95:5595-5600[Abstract/Free Full Text].

13. Derijard, B., M. Hibi, I. H. Wu, T. Barrett, B. Su, T. Deng, M. Karin, and R. J. Davis. 1994. JNK1: a protein kinase stimulated by UV light and Ha-Ras that binds and phosphorylates the c-Jun activation domain. Cell 76:1025-1037[Medline].

14. Dickens, M., J. S. Rogers, J. Cavanagh, A. Raitano, Z. Xia, J. R. Halpern, M. E. Greenberg, C. L. Sawyers, and R. J. Davis. 1997. A cytoplasmic inhibitor of the JNK signal transduction pathway. Science 277:693-696[Abstract/Free Full Text].

15. Fanger, G. R., C. Widmann, A. C. Porter, S. Sather, G. L. Johnson, and R. R. Vaillancourt. 1998. 14-3-3 proteins interact with specific MEK kinases. J. Biol. Chem. 273:3476-3483[Abstract/Free Full Text].

16. Faris, M., N. Kokot, K. Latinis, S. Kasibhatla, D. R. Green, G. A. Koretzky, and A. Nel. 1998. The c-Jun N-terminal kinase cascade plays a role in stress-induced apoptosis in Jurkat cells by upregulating Fas ligand expression. J. Immunol. 160:134-144[Abstract/Free Full Text].

17. Feng, Z., A. Marti, B. Jehn, H. J. Altermatt, G. Chicaiza, and R. Jaggi. 1995. Glucocorticoid and progesterone inhibit involution and programmed cell death in the mouse mammary gland. J. Cell Biol. 131:1095-1103[Abstract/Free Full Text].

18. Frisch, S. M., K. Vuori, D. Kelaita, and S. Sicks. 1996. A role for Jun-N-terminal kinase in anoikis; suppression by bcl-2 and crmA. J. Cell Biol. 135:1377-1382[Abstract/Free Full Text].

19. Gadducci, A., and A. R. Genazzani. 1997. Steroid hormones in endometrial and breast cancer. Eur. J. Gynaecol. Oncol. 18:371-378[Medline]. (Review.)

20. Garnick, M., and W. Fair. 1996. Prostate cancer: emerging concepts. Part II. Ann. Intern. Med. 125:205-212[Abstract/Free Full Text].

21. Helmberg, A., N. Auphan, C. Caelles, and M. Karin. 1995. Glucocorticoid-induced apoptosis of human leukemic cells is caused by the repressive function of the glucocorticoid receptor. EMBO J. 14:452-460[Medline].

22. Hong, H., K. Kohli, A. Trivedi, D. L. Johnson, and M. R. Stallcup. 1996. GRIP1, a novel mouse protein that serves as a transcriptional coactivator in yeast for the hormone binding domains of steroid receptors. Proc. Natl. Acad. Sci. USA 93:4948-4952[Abstract/Free Full Text].

23. Ikonen, T., J. J. Palvimo, P. J. Kallio, P. Reinikainen, and O. A. Janne. 1994. Stimulation of androgen-regulated transactivation by modulators of protein phosphorylation. Endocrinology 135:1359-1366[Abstract].

24. Jenster, G., P. E. de Ruiter, H. A. van der Korput, G. G. Kuiper, J. Trapman, and A. O. Brinkmann. 1994. Changes in the abundance of androgen receptor isotypes: effects of ligand treatment, glutamine-stretch variation, and mutation of putative phosphorylation sites. Biochemistry 33:14064-14072[Medline].

25. Johnson, N. L., A. M. Gardner, K. M. Diener, C. A. Lange-Carter, J. Gleavy, M. B. Jarpe, A. Minden, M. Karin, L. I. Zon, and G. L. Johnson. 1996. Signal transduction pathways regulated by mitogen-activated/extracellular response kinase kinase kinase induce cell death. J. Biol. Chem. 271:3229-3237[Abstract/Free Full Text].

26. Karin, M. 1998. New twists in gene regulation by glucocorticoid receptor: is DNA binding dispensable? Cell 93:487-490[Medline].

27. Kato, S., H. Endoh, Y. Masuhiro, T. Kitamoto, S. Uchiyama, H. Sasaki, S. Masushige, Y. Gotoh, E. Nishida, H. Kawashima, et al. 1995. Activation of the estrogen receptor through phosphorylation by mitogen-activated protein kinase. Science 270:1491-1494[Abstract/Free Full Text].

28. Kitsberg, D. I., and P. Leder. 1996. Keratinocyte growth factor induces mammary and prostatic hyperplasia and mammary adenocarcinoma in transgenic mice. Oncogene 13:2507-2515[Medline].

29. Klein, K. A., R. E. Reiter, J. Redula, H. Moradi, X. L. Zhu, A. R. Brothman, D. J. Lamb, M. Marcelli, A. Belldegrun, O. N. Witte, and C. L. Sawyers. 1997. Progression of metastatic human prostate cancer to androgen independence in immunodeficient SCID mice. Nat. Med. 3:402-408[Medline].

30. Lee, F. S., J. Hagler, Z. J. Chen, and T. Maniatis. 1997. Activation of the IkappaB alpha kinase complex by MEKK1, a kinase of the JNK pathway. Cell 88:213-222[Medline].

31. Lehman, A. M., K. B. Ellwood, B. E. Middleton, and M. Carey. 1998. Compensatory energetic relationships between upstream activators and the RNA polymerase II general transcription machinery. J. Biol. Chem. 273:932-939[Abstract/Free Full Text].

32. Lim, D. J., X. L. Liu, D. M. Sutkowski, E. J. Braun, C. Lee, and J. M. Kozlowski. 1993. Growth of an androgen-sensitive human prostate cancer cell line, LNCaP, in nude mice. Prostate 22:109-118[Medline].

33. Marcelli, M., S. J. Haidacher, S. R. Plymate, and R. S. Birnbaum. 1995. Altered growth and insulin-like growth factor-binding protein-3 production in PC3 prostate carcinoma cells stably transfected with a constitutively active androgen receptor complementary deoxyribonucleic acid. Endocrinology 136:1040-1048[Abstract].

34. Marcelli, M., W. Tilley, C. Wilson, J. Griffin, J. Wilson, and M. McPhaul. 1990. Definition of the human androgen receptor gene structure permits the identification of mutations that cause androgen resistance: premature termination of the receptor protein at amino acid residue 588 causes complete androgen resistance. Mol. Endocrinol. 4:1105-1116[Abstract/Free Full Text].

35. McConkey, D. J., G. Greene, and C. A. Pettaway. 1996. Apoptosis resistance increases with metastatic potential in cells of the human LNCaP prostate carcinoma line. Cancer Res. 56:5594-5599[Abstract/Free Full Text].

36. Minden, A., A. Lin, M. McMahon, C. Lange-Carter, B. Derijard, R. J. Davis, G. L. Johnson, and M. Karin. 1994. Differential activation of ERK and JNK mitogen-activated protein kinases by Raf-1 and MEKK. Science 266:1719-1723[Abstract/Free Full Text].

37. Nakano, H., M. Shindo, S. Sakon, S. Nishinaka, M. Mihara, H. Yagita, and K. Okumura. 1998. Differential regulation of IkappaB kinase alpha and beta by two upstream kinases, NF-kappaB-inducing kinase and mitogen-activated protein kinase/ERK kinase kinase-1. Proc. Natl. Acad. Sci. USA 95:3537-3542[Abstract/Free Full Text].

38. Nazareth, L. V., and N. L. Weigel. 1996. Activation of the human androgen receptor through a protein kinase A signaling pathway. J. Biol. Chem. 271:19900-19907[Abstract/Free Full Text].

39. Pang, S., J. Dannull, R. Kaboo, Y. Xie, C.-L. Tso, K. Michel, J. B. deKernion, and A. S. Belldegrun. 1997. Identification of a positive regulatory element responsible for tissue-specific expression of prostate-specific antigen. Cancer Res. 57:495-499[Abstract/Free Full Text].

40. Prins, G. S., R. J. Sklarew, and L. P. Pertschuk. 1998. Image analysis of androgen receptor immunostaining in prostate cancer accurately predicts response to hormonal therapy. J. Urol. 159:641-649[Medline].

41. Raitano, A. B., J. R. Halpern, T. M. Hambuch, and C. L. Sawyers. 1995. The Bcr-Abl leukemia oncogene activates Jun kinase and requires Jun for transformation. Proc. Natl. Acad. Sci. USA 92:11746-11750[Abstract/Free Full Text].

42. Reinikainen, P., J. J. Palvimo, and O. A. Janne. 1996. Effects of mitogens on androgen receptor-mediated transactivation. Endocrinology 137:4351-4357[Abstract].

43. Sato, N., M. D. Sadar, N. Bruchovsky, F. Saatcioglu, P. S. Rennie, S. Sato, P. H. Lange, and M. E. Gleave. 1997. Androgenic induction of prostate-specific antigen gene is repressed by protein-protein interaction between the androgen receptor and AP-1/c-Jun in the human prostate cancer cell line LNCaP. J. Biol. Chem. 272:17485-17494[Abstract/Free Full Text].

44. Schurr, E. R., G. A. Henderson, L. A. Kmetec, J. D. Miller, H. G. Lamparski, and D. R. Henderson. 1996. Prostate-specific antigen expression is regulated by an upstream enhancer. J. Biol. Chem. 271:7043-7051[Abstract/Free Full Text].

45. Shi, Y., J. M. Glynn, L. J. Guilbert, T. G. Cotter, R. P. Bissonnette, and D. R. Green. 1992. Role for c-myc in activation-induced apoptotic cell death in T cell hybridomas. Science 257:212-214[Abstract/Free Full Text].

46. Sun, Z., J. Pan, and S. P. Balk. 1997. Androgen receptor-associated protein complex binds upstream of the androgen-responsive elements in the promoters of human prostate-specific antigen and kallikrein 2 genes. Nucleic Acids Res. 25:3318-3325[Abstract/Free Full Text].

47. Tang, D. G., and A. T. Porter. 1997. Target to apoptosis: a hopeful weapon for prostate cancer. Prostate 32:284-293[Medline].

48. van Steenbrugge, G., C. van Uffelen, J. Bolt, and F. Schroder. 1991. The human prostatic cancer cell line LNCaP and its derived sublines: an in vitro model for the study of androgen sensitivity. J. Steroid Biochem. Mol. Biol. 40:207-214[Medline].

49. Veldscholte, J., C. Berrevoets, C. Ris-Stalpers, G. Kuiper, G. Jenster, J. Trapman, A. Brinkmann, and E. Mulder. 1992. The androgen receptor in LNCaP cells contains a mutation in the ligand binding domain which affects steroid binding characteristics and response to anti-androgens. J. Steroid Biochem. Mol. Biol. 41:665-669[Medline].

50. Widmann, C., S. Gibson, and G. L. Johnson. 1998. Caspase-dependent cleavage of signaling proteins during apoptosis. A turn-off mechanism for anti-apoptotic signals. J. Biol. Chem. 273:7141-7147[Abstract/Free Full Text].

51. Widmann, C., N. L. Johnson, A. M. Gardner, R. J. Smith, and G. L. Johnson. 1997. Potentiation of apoptosis by low dose stress stimuli in cells expressing activated MEK kinase 1. Oncogene 15:2439-2447[Medline].

52. Wise, S. C., L. A. Burmeister, X.-F. Zhou, A. Bubulya, J. L. Oberfield, M. J. Birrer, and L. Shemshedini. 1998. Identification of domains of c-jun mediating androgen receptor transactivation. Oncogene 16:2001-2009[Medline].

53. Xia, Z., M. Dickens, J. Raingeaud, R. J. Davis, and M. E. Greenberg. 1995. Opposing effects of ERK and JNK-p38 MAP kinases on apoptosis. Science 270:1326-1331[Abstract/Free Full Text].

54. Xu, S., and M. H. Cobb. 1997. MEKK1 binds directly to the c-Jun N-terminal kinases/stress-activated protein kinases. J. Biol. Chem. 272:32056-32060[Abstract/Free Full Text].

55. Yeh, S., and C. Chang. 1996. Cloning and characterization of a specific coactivator, ARA₇₀, for the androgen receptor in human prostate cells. Proc. Natl. Acad. Sci. USA 93:5517-5521[Abstract/Free Full Text].

56. Yin, M. J., L. B. Christerson, Y. Yamamoto, Y. T. Kwak, S. Xu, F. Mercurio, M. Barbosa, M. H. Cobb, and R. B. Gaynor. 1998. HTLV-I Tax protein binds to MEKK1 to stimulate IkappaB kinase activity and NF-kappaB activation. Cell 93:875-884[Medline].

57. Zhou, Q., J. F. Krebs, S. J. Snipas, A. Price, E. S. Alnemri, K. J. Tomaselli, and G. S. Salvesen. 1998. Interaction of the baculovirus anti-apoptotic protein p35 with caspases. Specificity, kinetics, and characterization of the caspase/p35 complex. Biochemistry 37:10757-10765[Medline].

58. Zhu, X., and J. P. Liu. 1997. Steroid-independent activation of androgen receptor in androgen-independent prostate cancer: a possible role for the MAP kinase signal transduction pathway? Mol. Cell. Endocrinol. 134:9-14[Medline].

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Yeh, S., Hu, Y.-C., Rahman, M., Lin, H.-K., Hsu, C.-L., Ting, H.-J., Kang, H.-Y., Chang, C. (2000). Increase of androgen-induced cell death and androgen receptor transactivation by BRCA1 in prostate cancer cells. Proc. Natl. Acad. Sci. USA 97: 11256-11261 [Abstract] [Full Text]

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1.	Abreu-Martin, M. T., and C. L. Sawyers. Unpublished data.
1a.	Amati, B., and H. Land. 1994. Myc-Max-Mad: a transcription factor network controlling cell cycle progression, differentiation and death. Curr. Opin. Genet. Dev. 4:102-108[Medline].
2.	Brandstrom, A., P. Westin, A. Bergh, S. Cajander, and J. E. Damber. 1994. Castration induces apoptosis in the ventral prostate but not in an androgen-sensitive prostatic adenocarcinoma in the rat. Cancer Res. 54:3594-3601[Abstract/Free Full Text].
3.	Bubulya, A., S. C. Wise, X. Q. Shen, L. A. Burmeister, and L. Shemshedini. 1996. c-Jun can mediate androgen receptor-induced transactivation. J. Biol. Chem. 271:24583-24589[Abstract/Free Full Text].
4.	Bunone, G., P. A. Briand, R. J. Miksicek, and D. Picard. 1996. Activation of the unliganded estrogen receptor by EGF involves the MAP kinase pathway and direct phosphorylation. EMBO J. 15:2174-2183[Medline].
5.	Cardone, M. H., G. S. Salvesen, C. Widmann, G. Johnson, and S. M. Frisch. 1997. The regulation of anoikis: MEKK-1 activation requires cleavage by caspases. Cell 90:315-323[Medline].
6.	Chen, Y. R., X. Wang, D. Templeton, R. J. Davis, and T. H. Tan. 1996. The role of c-Jun N-terminal kinase (JNK) in apoptosis induced by ultraviolet C and gamma radiation. Duration of JNK activation may determine cell death and proliferation. J. Biol. Chem. 271:31929-31936[Abstract/Free Full Text].
7.	Cleutjens, K. B., H. A. van der Korput, C. C. van Eekelen, H. C. J. van Rooij, P. W. Faber, and J. Trapman. 1997. An androgen response element in a far upstream enhancer region is essential for high, androgen-regulated activity of the prostate-specific antigen promoter. Mol. Endocrinol. 11:148-161[Abstract/Free Full Text].
8.	Cleutjens, K. B., C. C. van Eekelen, H. A. van der Korput, A. O. Brinkmann, and J. Trapman. 1996. Two androgen response regions cooperate in steroid hormone regulated activity of the prostate-specific antigen promoter. J. Biol. Chem. 271:6379-6388[Abstract/Free Full Text].
9.	Colombel, M., S. Gil Diez, F. Radvanyi, R. Buttyan, J. P. Thiery, and D. Chopin. 1996. Apoptosis in prostate cancer. Molecular basis to study hormone refractory mechanisms. Ann. N. Y. Acad. Sci. 784:63-69[Medline].
10.	Craft, N., Y. Shostak, M. Carey, and C. L. Sawyers. 1999. A mechanism for hormone-independent prostate cancer through modulation of androgen receptor signaling by the HER-2/neu tyrosine kinase. Nat. Med. 5:280-285[Medline].
11.	Culig, Z., A. Hobisch, M. V. Cronauer, C. Radmayr, J. Trapman, A. Hittmair, G. Bartsch, and H. Klocker. 1994. Androgen receptor activation in prostatic tumor cell lines by insulin-like growth factor-I, keratinocyte growth factor, and epidermal growth factor. Cancer Res. 54:5474-5478[Abstract/Free Full Text].
12.	Deak, J. C., J. V. Cross, M. Lewis, Y. Qian, L. A. Parrott, C. W. Distelhorst, and D. J. Templeton. 1998. Fas-induced proteolytic activation and intracellular redistribution of the stress-signaling kinase MEKK1. Proc. Natl. Acad. Sci. USA 95:5595-5600[Abstract/Free Full Text].
13.	Derijard, B., M. Hibi, I. H. Wu, T. Barrett, B. Su, T. Deng, M. Karin, and R. J. Davis. 1994. JNK1: a protein kinase stimulated by UV light and Ha-Ras that binds and phosphorylates the c-Jun activation domain. Cell 76:1025-1037[Medline].
14.	Dickens, M., J. S. Rogers, J. Cavanagh, A. Raitano, Z. Xia, J. R. Halpern, M. E. Greenberg, C. L. Sawyers, and R. J. Davis. 1997. A cytoplasmic inhibitor of the JNK signal transduction pathway. Science 277:693-696[Abstract/Free Full Text].
15.	Fanger, G. R., C. Widmann, A. C. Porter, S. Sather, G. L. Johnson, and R. R. Vaillancourt. 1998. 14-3-3 proteins interact with specific MEK kinases. J. Biol. Chem. 273:3476-3483[Abstract/Free Full Text].
16.	Faris, M., N. Kokot, K. Latinis, S. Kasibhatla, D. R. Green, G. A. Koretzky, and A. Nel. 1998. The c-Jun N-terminal kinase cascade plays a role in stress-induced apoptosis in Jurkat cells by upregulating Fas ligand expression. J. Immunol. 160:134-144[Abstract/Free Full Text].
17.	Feng, Z., A. Marti, B. Jehn, H. J. Altermatt, G. Chicaiza, and R. Jaggi. 1995. Glucocorticoid and progesterone inhibit involution and programmed cell death in the mouse mammary gland. J. Cell Biol. 131:1095-1103[Abstract/Free Full Text].
18.	Frisch, S. M., K. Vuori, D. Kelaita, and S. Sicks. 1996. A role for Jun-N-terminal kinase in anoikis; suppression by bcl-2 and crmA. J. Cell Biol. 135:1377-1382[Abstract/Free Full Text].
19.	Gadducci, A., and A. R. Genazzani. 1997. Steroid hormones in endometrial and breast cancer. Eur. J. Gynaecol. Oncol. 18:371-378[Medline]. (Review.)
20.	Garnick, M., and W. Fair. 1996. Prostate cancer: emerging concepts. Part II. Ann. Intern. Med. 125:205-212[Abstract/Free Full Text].
21.	Helmberg, A., N. Auphan, C. Caelles, and M. Karin. 1995. Glucocorticoid-induced apoptosis of human leukemic cells is caused by the repressive function of the glucocorticoid receptor. EMBO J. 14:452-460[Medline].
22.	Hong, H., K. Kohli, A. Trivedi, D. L. Johnson, and M. R. Stallcup. 1996. GRIP1, a novel mouse protein that serves as a transcriptional coactivator in yeast for the hormone binding domains of steroid receptors. Proc. Natl. Acad. Sci. USA 93:4948-4952[Abstract/Free Full Text].
23.	Ikonen, T., J. J. Palvimo, P. J. Kallio, P. Reinikainen, and O. A. Janne. 1994. Stimulation of androgen-regulated transactivation by modulators of protein phosphorylation. Endocrinology 135:1359-1366[Abstract].
24.	Jenster, G., P. E. de Ruiter, H. A. van der Korput, G. G. Kuiper, J. Trapman, and A. O. Brinkmann. 1994. Changes in the abundance of androgen receptor isotypes: effects of ligand treatment, glutamine-stretch variation, and mutation of putative phosphorylation sites. Biochemistry 33:14064-14072[Medline].
25.	Johnson, N. L., A. M. Gardner, K. M. Diener, C. A. Lange-Carter, J. Gleavy, M. B. Jarpe, A. Minden, M. Karin, L. I. Zon, and G. L. Johnson. 1996. Signal transduction pathways regulated by mitogen-activated/extracellular response kinase kinase kinase induce cell death. J. Biol. Chem. 271:3229-3237[Abstract/Free Full Text].
26.	Karin, M. 1998. New twists in gene regulation by glucocorticoid receptor: is DNA binding dispensable? Cell 93:487-490[Medline].
27.	Kato, S., H. Endoh, Y. Masuhiro, T. Kitamoto, S. Uchiyama, H. Sasaki, S. Masushige, Y. Gotoh, E. Nishida, H. Kawashima, et al. 1995. Activation of the estrogen receptor through phosphorylation by mitogen-activated protein kinase. Science 270:1491-1494[Abstract/Free Full Text].
28.	Kitsberg, D. I., and P. Leder. 1996. Keratinocyte growth factor induces mammary and prostatic hyperplasia and mammary adenocarcinoma in transgenic mice. Oncogene 13:2507-2515[Medline].
29.	Klein, K. A., R. E. Reiter, J. Redula, H. Moradi, X. L. Zhu, A. R. Brothman, D. J. Lamb, M. Marcelli, A. Belldegrun, O. N. Witte, and C. L. Sawyers. 1997. Progression of metastatic human prostate cancer to androgen independence in immunodeficient SCID mice. Nat. Med. 3:402-408[Medline].
30.	Lee, F. S., J. Hagler, Z. J. Chen, and T. Maniatis. 1997. Activation of the IkappaB alpha kinase complex by MEKK1, a kinase of the JNK pathway. Cell 88:213-222[Medline].
31.	Lehman, A. M., K. B. Ellwood, B. E. Middleton, and M. Carey. 1998. Compensatory energetic relationships between upstream activators and the RNA polymerase II general transcription machinery. J. Biol. Chem. 273:932-939[Abstract/Free Full Text].
32.	Lim, D. J., X. L. Liu, D. M. Sutkowski, E. J. Braun, C. Lee, and J. M. Kozlowski. 1993. Growth of an androgen-sensitive human prostate cancer cell line, LNCaP, in nude mice. Prostate 22:109-118[Medline].
33.	Marcelli, M., S. J. Haidacher, S. R. Plymate, and R. S. Birnbaum. 1995. Altered growth and insulin-like growth factor-binding protein-3 production in PC3 prostate carcinoma cells stably transfected with a constitutively active androgen receptor complementary deoxyribonucleic acid. Endocrinology 136:1040-1048[Abstract].
34.	Marcelli, M., W. Tilley, C. Wilson, J. Griffin, J. Wilson, and M. McPhaul. 1990. Definition of the human androgen receptor gene structure permits the identification of mutations that cause androgen resistance: premature termination of the receptor protein at amino acid residue 588 causes complete androgen resistance. Mol. Endocrinol. 4:1105-1116[Abstract/Free Full Text].
35.	McConkey, D. J., G. Greene, and C. A. Pettaway. 1996. Apoptosis resistance increases with metastatic potential in cells of the human LNCaP prostate carcinoma line. Cancer Res. 56:5594-5599[Abstract/Free Full Text].
36.	Minden, A., A. Lin, M. McMahon, C. Lange-Carter, B. Derijard, R. J. Davis, G. L. Johnson, and M. Karin. 1994. Differential activation of ERK and JNK mitogen-activated protein kinases by Raf-1 and MEKK. Science 266:1719-1723[Abstract/Free Full Text].
37.	Nakano, H., M. Shindo, S. Sakon, S. Nishinaka, M. Mihara, H. Yagita, and K. Okumura. 1998. Differential regulation of IkappaB kinase alpha and beta by two upstream kinases, NF-kappaB-inducing kinase and mitogen-activated protein kinase/ERK kinase kinase-1. Proc. Natl. Acad. Sci. USA 95:3537-3542[Abstract/Free Full Text].
38.	Nazareth, L. V., and N. L. Weigel. 1996. Activation of the human androgen receptor through a protein kinase A signaling pathway. J. Biol. Chem. 271:19900-19907[Abstract/Free Full Text].
39.	Pang, S., J. Dannull, R. Kaboo, Y. Xie, C.-L. Tso, K. Michel, J. B. deKernion, and A. S. Belldegrun. 1997. Identification of a positive regulatory element responsible for tissue-specific expression of prostate-specific antigen. Cancer Res. 57:495-499[Abstract/Free Full Text].
40.	Prins, G. S., R. J. Sklarew, and L. P. Pertschuk. 1998. Image analysis of androgen receptor immunostaining in prostate cancer accurately predicts response to hormonal therapy. J. Urol. 159:641-649[Medline].
41.	Raitano, A. B., J. R. Halpern, T. M. Hambuch, and C. L. Sawyers. 1995. The Bcr-Abl leukemia oncogene activates Jun kinase and requires Jun for transformation. Proc. Natl. Acad. Sci. USA 92:11746-11750[Abstract/Free Full Text].
42.	Reinikainen, P., J. J. Palvimo, and O. A. Janne. 1996. Effects of mitogens on androgen receptor-mediated transactivation. Endocrinology 137:4351-4357[Abstract].
43.	Sato, N., M. D. Sadar, N. Bruchovsky, F. Saatcioglu, P. S. Rennie, S. Sato, P. H. Lange, and M. E. Gleave. 1997. Androgenic induction of prostate-specific antigen gene is repressed by protein-protein interaction between the androgen receptor and AP-1/c-Jun in the human prostate cancer cell line LNCaP. J. Biol. Chem. 272:17485-17494[Abstract/Free Full Text].
44.	Schurr, E. R., G. A. Henderson, L. A. Kmetec, J. D. Miller, H. G. Lamparski, and D. R. Henderson. 1996. Prostate-specific antigen expression is regulated by an upstream enhancer. J. Biol. Chem. 271:7043-7051[Abstract/Free Full Text].
45.	Shi, Y., J. M. Glynn, L. J. Guilbert, T. G. Cotter, R. P. Bissonnette, and D. R. Green. 1992. Role for c-myc in activation-induced apoptotic cell death in T cell hybridomas. Science 257:212-214[Abstract/Free Full Text].
46.	Sun, Z., J. Pan, and S. P. Balk. 1997. Androgen receptor-associated protein complex binds upstream of the androgen-responsive elements in the promoters of human prostate-specific antigen and kallikrein 2 genes. Nucleic Acids Res. 25:3318-3325[Abstract/Free Full Text].
47.	Tang, D. G., and A. T. Porter. 1997. Target to apoptosis: a hopeful weapon for prostate cancer. Prostate 32:284-293[Medline].
48.	van Steenbrugge, G., C. van Uffelen, J. Bolt, and F. Schroder. 1991. The human prostatic cancer cell line LNCaP and its derived sublines: an in vitro model for the study of androgen sensitivity. J. Steroid Biochem. Mol. Biol. 40:207-214[Medline].
49.	Veldscholte, J., C. Berrevoets, C. Ris-Stalpers, G. Kuiper, G. Jenster, J. Trapman, A. Brinkmann, and E. Mulder. 1992. The androgen receptor in LNCaP cells contains a mutation in the ligand binding domain which affects steroid binding characteristics and response to anti-androgens. J. Steroid Biochem. Mol. Biol. 41:665-669[Medline].
50.	Widmann, C., S. Gibson, and G. L. Johnson. 1998. Caspase-dependent cleavage of signaling proteins during apoptosis. A turn-off mechanism for anti-apoptotic signals. J. Biol. Chem. 273:7141-7147[Abstract/Free Full Text].
51.	Widmann, C., N. L. Johnson, A. M. Gardner, R. J. Smith, and G. L. Johnson. 1997. Potentiation of apoptosis by low dose stress stimuli in cells expressing activated MEK kinase 1. Oncogene 15:2439-2447[Medline].
52.	Wise, S. C., L. A. Burmeister, X.-F. Zhou, A. Bubulya, J. L. Oberfield, M. J. Birrer, and L. Shemshedini. 1998. Identification of domains of c-jun mediating androgen receptor transactivation. Oncogene 16:2001-2009[Medline].
53.	Xia, Z., M. Dickens, J. Raingeaud, R. J. Davis, and M. E. Greenberg. 1995. Opposing effects of ERK and JNK-p38 MAP kinases on apoptosis. Science 270:1326-1331[Abstract/Free Full Text].
54.	Xu, S., and M. H. Cobb. 1997. MEKK1 binds directly to the c-Jun N-terminal kinases/stress-activated protein kinases. J. Biol. Chem. 272:32056-32060[Abstract/Free Full Text].
55.	Yeh, S., and C. Chang. 1996. Cloning and characterization of a specific coactivator, ARA₇₀, for the androgen receptor in human prostate cells. Proc. Natl. Acad. Sci. USA 93:5517-5521[Abstract/Free Full Text].
56.	Yin, M. J., L. B. Christerson, Y. Yamamoto, Y. T. Kwak, S. Xu, F. Mercurio, M. Barbosa, M. H. Cobb, and R. B. Gaynor. 1998. HTLV-I Tax protein binds to MEKK1 to stimulate IkappaB kinase activity and NF-kappaB activation. Cell 93:875-884[Medline].
57.	Zhou, Q., J. F. Krebs, S. J. Snipas, A. Price, E. S. Alnemri, K. J. Tomaselli, and G. S. Salvesen. 1998. Interaction of the baculovirus anti-apoptotic protein p35 with caspases. Specificity, kinetics, and characterization of the caspase/p35 complex. Biochemistry 37:10757-10765[Medline].
58.	Zhu, X., and J. P. Liu. 1997. Steroid-independent activation of androgen receptor in androgen-independent prostate cancer: a possible role for the MAP kinase signal transduction pathway? Mol. Cell. Endocrinol. 134:9-14[Medline].