Estradiol Abrogates Apoptosis in Breast Cancer Cells through Inactivation of BAD: Ras-dependent Nongenomic Pathways Requiring Signaling through ERK and Akt

Romaine Ingrid Fernando, and Jay Wimalasena^*

Department of Obstetrics and Gynecology, and the Comparative and Experimental Medicine Program, Graduate School of Medicine, University of Tennessee, Knoxville, Tennessee 37920

Submitted November 17, 2003; Revised April 16, 2004; Accepted April 18, 2004
Monitoring Editor: Keith Yamamoto

ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUMMARY
ACKNOWLEDGMENTS
REFERENCES

Estrogens such as 17- ${beta}$ estradiol (E₂) play a critical role insporadic breast cancer progression and decrease apoptosis inbreast cancer cells. Our studies using estrogen receptor-positiveMCF7 cells show that E₂ abrogates apoptosis possibly throughphosphorylation/inactivation of the proapoptotic protein BAD,which was rapidly phosphorylated at S112 and S136. Inhibitionof BAD protein expression with specific antisense oligonucleotidesreduced the effectiveness of tumor necrosis factor- ${alpha}$ , H₂O₂, andserum starvation in causing apoptosis. Furthermore, the abilityof E₂ to prevent tumor necrosis factor- ${alpha}$ -induced apoptosis wasblocked by overexpression of the BAD S112A/S136A mutant butnot the wild-type BAD. BAD S112A/S136A, which lacks phosphorylationsites for p90^RSK1 and Akt, was not phosphorylated in responseto E₂ in vitro_. E₂ treatment rapidly activated phosphatidylinositol3-kinase (PI-3K)/Akt and p90^RSK1 to an extent similar to insulin-likegrowth factor-1 treatment. In agreement with p90^RSK1 activation,E₂ also rapidly activated extracellular signal-regulated kinase,and this activity was down-regulated by chemical and biologicalinhibition of PI-3K suggestive of cross talk between signalingpathways responding to E₂. Dominant negative Ras blocked E₂-inducedBAD phosphorylation and the Raf-activator RasV12T35S inducedBAD phosphorylation as well as enhanced E₂-induced phosphorylationat S112. Chemical inhibition of PI-3K and mitogen-activatedprotein kinase kinase 1 inhibited E₂-induced BAD phosphorylationat S112 and S136 and expression of dominant negative Ras-inducedapoptosis in proliferating cells. Together, these data demonstratea new nongenomic mechanism by which E₂ prevents apoptosis.

INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUMMARY
ACKNOWLEDGMENTS
REFERENCES

The growth of human and animal tumors is a balance between cellularproliferation and death. Cell death in tumors occurs throughnecrosis and apoptosis, and highly malignant tumors often havehigh rates of both apoptosis and necrosis (Gompel et al., 2000).Thus, it is not surprising that mitogenic substances such asinsulin-like growth factor (IGF-1) also serve as cellular survivalfactors and are able to decrease rates of apoptosis. Estrogens,in particular 17- ${beta}$ estradiol (E₂), are well-characterized mitogensfor mammary tissues and epithelial cells of the female reproductivetract. Whereas estrogens exert antiapoptotic influence in neurons(Zhang et al., 2001), epithelial cells of the female reproductivetract (Leung and Wang, 1999; Choi et al., 2001), immune system,blood cells, and endothelial cells (Bynoe et al., 2000; Hayneset al., 2000), they also have significant apoptotic effectson certain classes of bone-derived cells (Hughes et al., 1996;Kameda et al., 1997) and some immune system cells (Zajchowskiand Hoffman-Goetz, 2000; Okasha et al., 2001). Furthermore,in some estrogen receptor (ER)-negative cells, overexpressionof ER often leads to apoptosis (Kushner et al., 1990) perhapsthrough activation of p38^MAPK (Srivastava et al., 1999, andreferences therein). Whereas E₂ promotes cell survival in ER-positivecells both in cell culture and in xenograft models, antiestrogensinduce apoptosis in both ER-positive and ER-negative cells (Srivastavaet al., 1999; Chen et al., 2000; Gandhi et al., 2000). Whetherthe latter results can be explained by expression of ER at lowlevels or an isoform of ER different from ER ${alpha}$ is presently unknown.

In the ER-positive MCF7 breast cancer cell line, antiapoptoticeffects of E₂ have been reported previously (Huang, 1997; Perilloet al., 2000; Ahamed et al., 2001); however, the mechanismsof action are poorly defined. It is now established that E₂induces transcription of the BCL2 gene and increases expressionof BCL2 protein, which exerts antiapoptotic action in many celltypes (Huang, 1997; Dong et al., 1999; Leung and Wang, 1999).In addition to genomic actions, E₂ has been known to exert rapid,likely nongenomic actions both in the whole animal and in culturedcells (Szego, 1974; Huang, 1997; Razandi et al., 2000a,b). Previously,we had observed that estrogens require the function of the Ras,mitogen-activated protein kinase kinase (MEK)1 and extracellularsignal-regulated kinase (ERK) pathway to induce G1/S phase transition(Ahamed et al., 2001) and elicit down-regulation of the Cdk2inhibitor p27^kip1 (Foster, 2003; Zhu et al., 2003). Given thatE₂ is now known to activate kinase-regulated signal transductionpathways in MCF7 and other cells (Migliaccio et al., 1996, andreferences therein; Singh et al., 2000; Zhang and Shapiro, 2000),we have examined potential nongenomic pathways involved in itsantiapoptotic actions, in particular the phosphatidylinositol3-kinase (PI-3K)/Akt/BAD pathway, which mediates BAD inactivationand favors cell survival. In this article, we demonstrate forthe first time that E₂ induces BAD phosphorylation through Ras/PI-3K/Aktas well as Ras/ERK/p90^RSK1 pathways, and we also show that thefunction of the PI-3K/Akt pathway is required for E₂ to blockapoptosis induced by tumor necrosis factor (TNF- ${alpha}$ ), H₂O₂, andserum withdrawal. Our data further provide evidence that BADfunction is required for induction of apoptosis in MCF7 cellsby TNF- ${alpha}$ , H₂O₂, and serum withdrawal and that overexpressionof the dual phosphorylation site mutant of BAD, but not thewild type, abolished the antiapoptotic actions of E_2.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUMMARY
ACKNOWLEDGMENTS
REFERENCES

Cell Culture, Serum Starvation, Treatment with E₂ and Other Agents
MCF7 cells (a gift from R.P. Shiu; Dubik and Shiu, 1992) werecultured in Dulbecco's modified Eagle's medium (Sigma-Aldrich,St. Louis, MO) supplemented with 5% fetal bovine serum, penicillinG, and streptomycin at 37°C in 5% CO₂. Cells were kept in1% serum for 24 h in DMEM (phenol red [PR]-free) medium andcompletely serum withdrawn for additional 24-48 h before theexperiments. Before treatments, cells were washed once withwarm phosphate-buffered saline and treated in medium free ofserum and PR. LY294002 (5 µM in 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium[MTT] assay, 20 µM in other assays) (Sigma-Aldrich) andICI182,780 (1 µM), PD98059 (50 µM) were added 1h before E₂ (1 nM in MTT assay and 10 nM in other assays) orIGF-1 (10 ng/ml). ICI182,780 is a gift from Zeneca Pharmaceuticals(Wilmington, DE). Where appropriate, cells were treated withdimethyl sulfoxide or ethanol as controls.

Cell Survival Assay
At 20-30% confluence, cells were treated in triplicates in 24-wellplates. At 24-h intervals, MTT assay was performed accordingto the manufacturer's (Sigma-Aldrich) protocol. Briefly, MTT(5 mg/ml) was added to equal 1/10 the culture volume and incubatedfor 3 h. Medium was removed, and the converted dye was solubilizedin ice-cold isopropanol. Absorbency of dye was measured at 560nm with background subtraction at 630 nm on a microplate reader(EL 340 Bio Kinetics Reader; Bio-Tek Instruments, Winooski,VT)

DNA Fragmentation Assay (Cell Death Detection ELISA^PLUS)
Apoptosis was induced with H₂O₂ (2 mM) for 1.5 h, TNF- ${alpha}$ (10 ng/ml)for 8 h, or by complete removal of growth factors for 72 h.Cells were pretreated with E₂ or IGF-1 for 1 h before apoptoticstimuli. DNA fragmentation was quantified using enzyme-linkedimmunosorbent assay (ELISA) kit (Cell Death ELISA; Roche Diagnostics,Indianapolis, IN) with slight modification to the manufacturer'sprotocol. Briefly, 50,000 cells of each treatment were lysedin 100 µl of lysis buffer, and a fraction of the supernatantwas subjected to reaction for 2 h with the immunocomplex ofanti-DNA conjugated with peroxidase, which binds to nucleosomalDNA, and antihistone-biotin, which interacts with streptavidin-coatedwells in a microtiter plate. At the end of the incubation, substratewas added, and color development was quantified at 405-nm wavelength.

Adenoviral Infections
PTEN (kindly donated by Dr. R Bookstein; Cheney et al., 1999),DNAkt (kindly donated by Dr. K Walsh; Kureishi et al., 2000),and LacZ (Q.Biogene, Carlsbad, CA) were transduced at 60, 30,and 30 multiplicity of infection (MOI), respectively. OptimumMOIs were determined by analyzing DNA profiles (by flow cytometry)in response to virus dosage. To study DNA fragmentation withTNF- ${alpha}$ or H₂O₂, cells were maintained in DMEM (PR free) with 2.5%fetal bovine serum for 24 h after infection followed by inductionof apoptosis. In 2A, cells were completely serum withdrawn foradditional 48 h after infection.

Western Blot Analysis
Cells were washed once with ice-cold phosphate-buffered salineand lysed with buffer containing 50 mM Tris-HCl, 1% NP-40, 0.25%sodium deoxycholate, 150 mM NaCl, 1 nM EGTA, 1 mM phenylmethylsulfonylfluoride, 1 µg/ml leupeptin, 1 mM NaVO₃, 1 mM NaF.

For the detection of poly(ADP-ribose) polymerase (PARP) cleavage,cells were lysed in ice-cold buffer containing 50 mM Tris-HCl,6.5 M urea, 5% mercaptoethanol, 2% SDS, and protease inhibitors,sonicated for 20 s, and briefly centrifuged to remove cell debris(Xu et al., 2002).

For cytochrome c detection, cytosolic fraction was preparedas described in Hirai and Wang (2001) with some modifications.Cells were suspended in hypotonic buffer containing 3.3 mM HEPES,pH 7.5, 1.7 mM KCl, 0.25 mM MgCl₂, 0.17 mM EGTA, and 0.17 mMEDTA, 6.6 µg/ml leupeptin, 0.3 mM phenylmethylsulfonylfluoride, 16.7 mM NaF, 66.7 µM Na₃VO₄, and 8.3 mM sodium ${beta}$ -glycerophosphate. After incubation on ice for 30 min, cellswere homogenized with a Dounce homogenizer and centrifuged at1000 x g for 5min at 4°C to discard unbroken cells and nuclei.The resulting supernatant was centrifuged at 10,000 x g for10 min at 4°C to obtain the heavy-membrane fraction (pellet)and the cytosol (supernatant).

Aliquots of cell extracts containing 50-100 µg of totalproteins or immunoprecipitates of desired proteins were resolvedon SDS-PAGE, transferred to nitrocellulose membranes, and probedwith specific antibodies to phospho-ERKs [pTEpY] (Promega, Madison,WI), phospho-BAD [S112 and S136] (Upstate Biotechnology, LakePlacid, NY), ERK2, PTEN, BAD, PARP, cytochrome c, Ras, and Akt(Santa Cruz Biotechnology, Santa Cruz, CA) followed by secondaryantibody conjugated with horseradish peroxidase (Santa CruzBiotechnology). Required concentrations of antibodies for Westernblot analyses were determined using manufacturers' protocols.Proteins were detected by ECL (Amersham Biosciences, Piscataway,NJ). The band intensities/fold activities were measured by SigmaGel software (Jandel Scientific, Winooski, VT).

Immunocomplex Kinase Activity Assays
Antibodies against ERK2, Akt, GSK3 ${beta}$ , p85 (PI-3K), and proteinA/G plus beads were purchased from Santa Cruz Biotechnology.Anti p90^RSK1antibody, soluble BAD, and IRS-1 were purchasedfrom Upstate Biotechnology. Myelin basic protein (MBP) was fromInvitrogen (Carlsbad, CA). One hundred to 200 µg of totalprotein was immunoprecipitated with antibody in excess and proteinA/G plus beads at 4°C overnight. Precipitates were washedthree times with TG buffer (250 mM NaCl, 20 nM Tris, 0.5% NP-40)and once with kinase buffer (50 nM HEPES, pH 7.4, 15 mM MgCl₂).Kinase reactions were performed by incubating immunoprecipitatesand the specific substrates (0.2-1 µg/sample) in kinasemixture (20 µM ATP, 5 µCi of [ ${gamma}$ -³²P]ATP, 1 mM dithiothreitol,0.1 mM Na₃VO₄ in kinase buffer) for 30 min at room temperature.Reactions were stopped with 4x Laemmli's sample buffer and wereresolved on SDS-PAGE. Band intensities of phosphorylated substratesin autoradiograms were measured by densitometry.

Phosphorylation Assay (Nonradioactive) with BAD Mutants
p-GEX-BAD^wt/mutant (kindly donated by Drs. P Cohen; Lizcanoet al., 2000) and AM Tolkovsky; Virdee et al., 2000) were grownin Escherichia coli, and proteins were isolated using glutathione-agarosebeads (Sigma-Aldrich) followed by elution in the presence ofreduced glutathione. Ten micrograms of BAD protein was incubatedwith 75 µg of whole cell lysate in 50 µl of kinasebuffer in the presence of 25 µM ATP for 30 min. At theend of the reaction, 15 µl of agarose-conjugated glutathionewas added and shaken for 1 h at 40°C. Beads were collected,washed three times with TG buffer, and resuspended in 25 µlof 2x Laemmli's sample buffer.

Treatment with BAD Oligonucleotides
BAD antisense oligonucleotides (with phosphorothioate linkages)were synthesized and purified by Sigma-Genosys (Woodlands, TX).Cells were transfected twice with LipofectAMINE Plus reagentaccording to the manufacturer's (Invitrogen) protocol 48 h apart.Transfections were carried out in six-well plates with 1 µgof oligonulceotide per well. Twenty-four hours after the secondtransfection, cells were treated and collected for desired analyses.Antisense oligonucleotides used in this study encoded complimentarysequences to the coding regions including translation initiation(BAD antisense 1) and termination codon (BAD antisense 2) sitesfor the human BAD gene. Oligonucleotide sequences used wereBAD antisense 1, 5'-TGGGATCTGTAACATGCT-3'; BAD antisense 1 (scrambled/control),5'-GGTTAGGTCAATTACTCG-3'; and BAD antisense 2, 5'-CGAAGGTCACTGGGA-3'.Cells were treated with H₂O₂ or TNF- ${alpha}$ (with or without E₂) orcompletely serum withdrawn for 72 h to induce apoptosis. DNAcontent was analyzed by flow cytometry and sub-G₁ populationwas considered as apoptotic (Ormerod et al., 1992).

Transient Transfection, Microscopic Analysis of Nuclear Morphology, and Confocal Microscopy
MCF7 cells grown on coverslips were transiently transfectedwith FLAG-tagged BAD mutants and enhanced green fluorescentprotein (EGFP, 15% of total DNA) by using LipofectAMINE Plusreagent according to the manufacturer's (Invitrogen) protocol.The BAD constructs used in this study were human BAD wild-type(Wt) and human BAD serine75 and serine99 (equivalent to mouseserine112 and serine136, respectively) mutated to alanine (Dm)and were kindly donated by Dr. H.G. Wang (Hirai and Wang, 2001).Coverslips were fixed in 3% paraformaldehyde and mounted onto glass slides. Nuclei were stained with 3 µg/ml Hoechst33342 (Sigma-Aldrich) and analyzed for the blue (DNA) and green(EGFP) fluorescence by using a fluorescence microscope (LeitzDMRB) or the confocal microscope. Cells expressing EGFP wereconsidered as coexpressing BAD mutants. We have previously validatedthe coexpression of plasmid constructs in MCF7 cells (Foster,2003). Morphological changes in the nuclei were analyzed andcondensed/shrunk nuclei were counted as apoptotic as opposedto normal round nuclei (Candolfi et al., 2002).

FLAG-wtBAD and RasN17, RasV12T35S (kindly donated by Drs. G.L.Johnson and C.M. Counter (Hamad et al., 2002, respectively)or empty vector were cotransfected at 1:1 ratio for coexpressionstudies. For macroscopic analyses, cells grown on coverslipswere transfected with Ras or empty vector constructs togetherwith EGFP (15% of total DNA) and processed and analyzed as describedabove.

Statistical Analysis
Statistical analysis was performed using Student's t test (Prism;GraphPad Software, San Diego, CA), and p $≤$ 0.05 is consideredsignificant.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUMMARY
ACKNOWLEDGMENTS
REFERENCES

Inhibition of Apoptosis in MCF7 Cells by E₂ Is Dependent on the PI-3K/Akt Pathway
Previous work in our laboratory has shown that estrogens decreasedcell death and apoptosis induced in MCF7 cells by mitogen withdrawal(Ahamed et al., 2001). Recent work indicates that inductionof cell growth by E₂ in MCF7 cells may require activity of thePI-3K pathway (Lobenhofer et al., 2000) and the Ras/ERK pathway(Castoria et al., 2001). Furthermore, we reported that G1/Sphase transition and Cdk2 activation induced by estrogens isinhibited by dominant-negative (DN) Ras mutants (Ahamed et al.,2001; Foster, 2003; Zhu et al., 2003), and the MEK1 inhibitorPD98059 abrogated the increase in cyclin D1 accumulation resultingfrom estrogen treatment (Ahamed et al., 2001).

Given this background, we sought to determine whether PI-3Kplays an important role in estrogen action with respect to cellgrowth and apoptosis. In preliminary experiments (our unpublisheddata), we verified that E₂ promoted cell survival/growth underlow serum conditions and further established that the PI-3Kinhibitor wortmannin inhibited this effect of E₂. To confirmthe requirement of PI-3K activity for the cell survival inducedby E₂, MCF7 cells were treated with E₂ in the presence or absenceof LY294002, a specific PI-3K inhibitor (Sanchez-Margalet etal., 1994) in serum-free medium. In the absence of E₂, therewas significant cell loss reflected in MTT uptake over a 5-dperiod (p < 0.05). E₂ completely blocked this decrease andmaintained MTT uptake at or above day 1 level (Figure 1A). Treatmentwith LY294002 abolished the ability of E₂ to increase cell numbersas indicated by MTT uptake (day 2) or maintain cell survival(day 4, 5) and also reduced viability in the control culturesat day 4 and 5. These results suggest that survival of MCF7cells under conditions of serum withdrawal requires PI-3K activityand that the ability of E₂ to protect cells from death as wellas to induce growth is blocked by abrogation of PI-3K activity.MTT results simply demonstrate the amount of live cells presentunder given conditions and, in the case of E₂, this is may presentthe sum of antiapoptotic and mitogenic effects.

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Figure 1. Inhibition of cell death in MCF7 cells by E₂. (A) MCF7 cells were serum deprived after 20% confluence and treated in PR-free medium with indicated stimuli. LY294002 (5 µM) was added 30 min before E₂ (1 nM) treatment. MTT uptake was measured at 24-h intervals in four replicates for each treatment. Results are presented as the percentages compared with day 0 (MTT uptake taken as 100%), and data represent the mean from three independent experiments. E₂ treatment groups are significantly different from control, LY294002, or LY294002 + E₂ at days 2, 4, and 5 (p $≤$ 0.05). (B) Apoptosis was induced by TNF- ${alpha}$ (10 ng/ml) for 8 h or H₂O₂ (2 mM) for 1.5 h. Cells were pretreated with E₂ (10 nM) with/without 100-fold excess ICI 182,780, 17- ${alpha}$ estradiol (10 nM) for 1 h before addition of apoptotic stimuli. DNA fragmentation was assayed using Cell Death ELISA (see MATERIALS AND METHODS), and data represent the mean of three independent experiments with triplicates per experiment for each treatment. Results are expressed as fold changes of apoptosis compared with untreated controls. The percentage of apoptotic cells in the untreated cultures is 2-5% as measured by this and other methods such as Hoechst 33342 staining for DNA and microscopic analysis of cell morphology. The ICI + E₂+TNF- ${alpha}$ group is not different from TNF- ${alpha}$ only group (p > 0.05). (^**p < 0.005, ^*p < 0.05). (C) Seventy-five micrograms of cell lysate protein was resolved on SDS-PAGE and Western blotted with anti-PARP antibody that recognizes parent and cleaved bands at 116 and 85 kDa, respectively. Actin levels are shown as protein loading control. Shown is a representative autoradiogram of three independent experiments that produced comparable results. (D) One hundred micrograms of cytoplasmic protein of cells treated with indicated agents were subjected to Western blotting with cytochrome c and actin antibodies. Experiment was repeated two to three times with comparable results.

The above-mentioned results and prior observations suggest thatE₂ may decrease apoptosis in MCF7 cells. Because TNF- ${alpha}$ inducesapoptosis through activation of caspases 3, 6, 7, and 8 and/orJNK activation (Budihardjo et al., 1999) in a variety of celltypes, including MCF7 cells (Burow et al., 1999; Guicciardiet al., 2000; Tang et al., 2001), we treated MCF7 cells withTNF- ${alpha}$ in the presence of E₂, 17- ${alpha}$ estradiol (an estrogen of lowpotency), E₂ plus an excess of the specific E₂ antagonist ICI182,780.TNF- ${alpha}$ increased apoptosis as measured by DNA fragmentation byfour- to fivefold, and E₂ was able to reduce this effect significantly,whereas 17 ${alpha}$ -estradiol had no protective effect. The presenceof an excess of the E₂ antagonist blocked the protective effectof E₂ in TNF- ${alpha}$ -treated cells (Figure 1B). PARP cleavage, a well-knownlate event in the apoptosis process (Duriez and Shah, 1997),was induced by TNF- ${alpha}$ , and this cleavage was significantly blockedby E₂ pretreatment (Figure 1C)

The reactive oxygen species H₂O₂ is known to induce apoptosisin a variety of cell types, including MCF7 cells (Kim et al.,2000), and the apoptotic effect of H₂O₂ in these cells is decreasedby pretreatment with E₂ or overexpression of BCL2 in a synergisticmanner (Perillo et al., 2000). Furthermore, E₂ and overexpressionof BCL2 exhibit additive inhibitory effects on cleavage of PARP(Duriez and Shah, 1997) induced by H₂O₂. In confirmation ofthese data, we found that E₂ pretreatment can block DNA fragmentationas well as PARP cleavage induced by 2 mM H₂O₂ (Figure 1, B and C).Pretreatment with 17- ${alpha}$ estradiol had no significant protectiveeffect against H₂O₂, suggesting that E₂ effects are unlikelyto be due to its potential free radical scavenger function (Behlet al., 1997).

Apoptotic effects of certain stimuli, including those activatingthe extrinsic pathway, are manifested at least in part via theireffects on mitochondrial membrane integrity (Downward, 1999;Gross et al., 1999). Release of cytochrome c from dysfunctionalmitochondria contributes to the formation of the apoptosome,which ultimately activates the downstream caspase pathways (Budihardjoet al., 1999). Because the results presented in Figure 1, A-C,would predict that E₂ may preserve mitochondrial integrity inthe presence of apoptotic stimuli, we sought to determine whetherE₂ would preserve mitochondrial integrity by assessing cytoplasmiccytochrome c protein level (Figure 1D). In untreated or E₂ only-treatedcells, cytoplasmic cytochrome c was undetectable. As expected,H₂O₂, TNF- ${alpha}$ , and serum withdrawal (see below) increased cytochromec in the cytoplasm. Cotreatment with E₂ decreased cytochromec release induced by TNF- ${alpha}$ to a similar extent as that observedin cells cotreated with serum and TNF- ${alpha}$ . Together, these resultssuggest that E₂ protects cells against apoptosis induced byTNF- ${alpha}$ , H₂O₂, and serum withdrawal (our unpublished data), possiblyby maintaining mitochondrial integrity.

Estradiol Effects on H₂O₂-, TNF- ${alpha}$ -, and Serum Withdrawal-induced Apoptosis Are Abolished by Dominant Negative Akt (DNAkt) and Wild-Type PTEN
To establish the role of the PI-3K pathway in E₂-induced antiapoptosis,we used adenoviral vectors to interfere with operation of thispathway. Cells were transduced with adenoviral wild-type PTEN/MMAC(Figure 2D) that effectively decreases activity of the PI-3Kpathway by hydrolysis of PI-3K products (Maehama and Dixon,1999), and overexpression of PTEN has been used to decreasePI-3K products in other studies (Nakashima et al., 2000). Asdepicted in Figure 2, overexpression of PTEN completely blockedthe ability of E₂ or IGF-1 to prevent apoptosis induced by serumwithdrawal (A), H₂O₂ (B), and TNF- ${alpha}$ (C) compared with adenoviralLacZ (control)-infected cultures. Akt/PKB is a downstream targetof PI-3K pathway that promotes cell survival in a number ofcell types (Downward, 1998; Datta et al., 1999). Overexpressionof DNAkt (Figure 2D) enhanced apoptosis induced by the agentsand completely reversed the effects of either IGF-1 or E₂ onapoptosis prevention (Figure 2, A-C). These data together withdata derived using chemical inhibitors (Figure 1A) stronglysuggest that PI-3K/ Akt pathway is essential for the antiapoptoticeffects of E₂ or IGF-1 in MCF7 cells. We repeatedly observedthat DNA fragmentation (measured by the Cell Death ELISA) inviral-transduced cells was below the levels observed in parentalcells (1.8-2.5 vs. 4-5 fold, compare Figures 1B and 2), whichlead to an apparent decrease in the magnitude of apoptosis asmeasured by the Cell Death ELISA in Figure 2.

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Figure 2. Inhibition of apoptosis in MCF7 cells by E₂ is dependent on the PI-3K/Akt pathway. Viral vectors were used to overexpress PTEN, DNAkt, and Lac-Z (control) at predetermined MOIs. Forty-eight hours after the infection apoptosis was induced by complete serum withdrawal for additional 48 h (A), with H₂O₂ (2 mM) for 1.5 h (B), and with TNF- ${alpha}$ (10 ng/ml) for 8 h (C). Where indicated, cells were pretreated with E₂ (10 nM) or IGF-1 (10 ng/ml) for 1 h before apoptotic stimuli. DNA fragmentation was measured as in Figure 1B. Results are expressed as fold change in apoptosis compared with control (untreated) for each infection and represent values of at least three independent experiments with three replicates for each treatment per experiment. In Lac-Z group, serum-starved sample is different from Lac-Z + E₂ at p < 0.005 (^**); Lac-Z + E₂ is different from PTEN + E₂ or DNAkt + E₂ at p < 0.005 (^*). In Lac-Z group, H₂O₂-treated sample is different from Lac-Z + E₂ at p < 0.05; Lac-Z + E₂ is different from PTEN + E₂ and DNAkt + E₂ at p < 0.005. In Lac-Z group, TNF- ${alpha}$ -treated sample is different from Lac-Z + E₂ at p < 0.005; Lac-Z + E₂ is different from PTEN + E₂ and DNAkt + E₂ at p < 0.05 and p < 0.005, respectively. (D) Demonstrates overexpression of PTEN and DNAkt by Western blot analysis.

Estradiol Induces BAD Phosphorylation
BAD is a proapoptotic BH3 domain-containing protein (Gross etal., 1999; Adams and Cory, 2001), which forms heterodimers withBCL2 or BCLxl (Condorelli et al., 2001) resulting in cytochromec release from mitochondria. Antiapoptotic agents such as IGF-1induce BAD phosphorylation at specific serine residues, andphosphorylated BAD is sequestered away from its site of actionin the mitochondria by binding to cytosolic 14-3-3 proteins(Datta et al., 1997). Because BAD is phosphorylated on serine136 (S136) by Akt (Datta et al., 1997), we ascertained the abilityof E₂ to induce phosphorylation of BAD at specific residuesby using BAD phosphorylation site mutants as in vitro substrates(Figure 3A). Clearly E₂- or IGF-1-treated cell extracts wereunable to induce phosphorylation of BAD at S112 in the serine-to-alaninemutant (S112A), whereas S136 phosphorylation was enhanced three-to fourfold. Similar specificity was observed when the S136ABAD mutant was used as the substrate (Figure 3A, right). Whenthe double phosphoryaltion site mutant (DM) was used as a substrate,only a small fraction of the phosphorylation that was observedwith single mutants was detectable. Multiple immunoreactivebands have been previously observed when recombinant BAD wasused as a substrate (Datta et al., 1997).

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Figure 3. Estradiol induces BAD phosphorylation. (A) Glutathione-tagged BAD proteins (BAD S112A, BAD S136A, and BADS112/136A [DM]) were subjected to in vitro kinase assay for 30 min with extracts from MCF7 cells that were treated with E₂ (10 nM) or IGF-1 (10 ng/ml) for 15 min. Proteins were separated using agarose-conjugated glutathione and resolved on SDS-PAGE. BAD phosphorylation at S112/S136 and total BAD protein levels were measured by Western blot. (B) Cells were treated as in A with E₂ (10 nM) or IGF-1 (10 ng/ml) for 15 min, and endogenous BAD phosphorylation was detected by Western blot by using phospho-specific BAD antibodies for S112 and S136. Same blot was probed with anti-BAD antibody. Fold stimulation (compared with untreated control) was calculated by densitometry, and the graph represents values of three independent experiments. (C) MCF7 cells were treated with indicated stimuli (TNF- ${alpha}$ [10 ng/ml] for 8 h or H₂O₂ [2 mM] for 1.5 h) with or without 1-h E₂ pretreatment. Equal amounts of whole cell lysate were subjected to Western blotting with anti-phospho and total BAD antibodies. Change in phosphorylation compared with untreated control was calculated by densitometry. Shown is a representative of two independent experiments with comparable results.

We also measured BAD phosphorylation in vivo by Western blotanalysis. After treatment with E₂ or IGF-1 for 15 min, bothS112 and S136 phosphorylations were enhanced (>3-fold), andtotal BAD levels were unchanged in this time frame (Figure 3B).

Because our results demonstrated that E₂ can induce BAD phosphorylationin vitro and in vivo and can prevent cell death in responseto several stimuli, we studied the possible changes in phosphorylationstatus of BAD during apoptosis induction. E₂ increased endogenousBAD phosphorylation at S112 and S136 above the basal level severalfold,whereas TNF- ${alpha}$ and H₂O₂ decreased it below control level (Figure 3C).Cotreatment with E₂ and H₂O₂ or TNF- ${alpha}$ restored the BAD phosphorylationto above-control levels. Together, these data strongly suggestthat E₂ as well as IGF-1 exert antiapoptotic actions partlythrough phosphorylation and inactivation of the proapoptoticBAD protein and that phosphorylation of BAD is a consequenceof activation of Akt and possibly ERK/p90^RSK1 because S112 isa target site for p90^RSK1 (Downward, 1999).

Inhibition of BAD Is a Critical Event in Estradiol-induced Antiapoptosis in MCF7 Cells
Because the effects of apoptotic agents on decreasing BAD phosphorylation(inactivation) were largely reversed by E₂, BAD inactivationmay be a potential nongenomic effect of E₂, which results incell survival. To further understand the involvement of BADin cell death and survival in MCF7 cells, we used antisenseoligonucleotides to prevent the translation of BAD mRNA. Theantisense sequences, BAD antisense 1 (BAD As 1) containing thecomplementary sequence to the translation initiation codon andBAD antisense 2 (BAD As 2) containing complementary sequenceto the translation termination codon were equally effectivein down-regulating BAD protein level (Figure 4A), whereas ascrambled oligonucleotide corresponding to BAD As1 (controloligo) was not. Quantification of DNA by flow-cytometry revealeda large reduction of the sub-G₁ fraction-apoptotic cells (Ormerodet al., 1992) in TNF- ${alpha}$ -treated (Figure 4B) as well as serum-starved(our unpublished data) cells in BAD As1- and BAD As2-treated,but not in control oligonucleotide-treated cells. E₂ did nothave an additional effect alone or together with TNF- ${alpha}$ , in antisense-treatedcells compared with control oligonucleotide treated cells (ourunpublished data). These observations suggest a critical roleof BAD in apoptosis in MCF7 cells and agree with a previousstudy where BAD overexpression resulted in apoptosis of mammaliancells (Ottilie et al., 1997; Virdee et al., 2000). Change inapoptosis due to TNF- ${alpha}$ was calculated by subtracting sub-G1 fractionof untreated from sub-G1 fraction of TNF- ${alpha}$ -treated cells foreach oligonucleotide-treated population. Data from three independentexperiments are shown in Figure 4C. Introduction of BAD As1or BAD As2 significantly reduced the magnitude of apoptosisin response to TNF- ${alpha}$ (^*p < 0.05), H₂O₂, and complete serumstarvation (our unpublished data). We next measured DNA fragmentationin oligonucleotide-treated cells in the presence or absenceof TNF- ${alpha}$ . TNF- ${alpha}$ induced four- to fivefold DNA fragmentation abovethe basal level (comparable to Figure 1B) in control oligonucleotide-or LipofectAMINE-treated cells. BAD As1 drastically reducedthis effect of TNF- ${alpha}$ (^**p < 0.005) and maintained the DNAfragmentation near the basal level (Figure 4D). Similar resultswere observed using BAD As2 (our unpublished data). These dataclearly suggest a critical involvement of BAD in cell survivaland death in response to several agents in MCF7 breast cancerepithelial cells and agree with the reduction in basal BAD phosphorylationinduced by TNF- ${alpha}$ and H₂O₂ in the absence of E₂ (Figure 3C).

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Figure 4. BAD inhibition is a critical event in TNF- ${alpha}$ -induced apoptosis and its prevention by E₂ in MCF7 cells. (A) MCF7 cells were treated with BAD antisense (BAD As1 and BAD As2) and control oligonucleotides (see MATERIALS AND METHODS), and protein extracts were subjected to Western blotting with anti-BAD and actin antibodies. BAD expression levels measured by densitometry are shown below the BAD blot. (B) Oligonucleotide-treated cells were stimulated with TNF- ${alpha}$ (10 ng/ml) for 8 h as described in MATERIALS AND METHODS. Cells were fixed in 70% ethanol and stained with propidium iodide. DNA content was analyzed by flow cytometry, and sub-G1 population was obtained as a measure of apoptosis. The experiment was repeated three times with comparable results, and representative histograms are shown. The percentage below each histogram indicates the respective sub-G1 (M4) fraction. (C) Results (mean ± SD) of three experiments as in B are presented in the graph. Change in apoptosis due to TNF- ${alpha}$ was calculated by subtracting sub-G1 fraction of the untreated from that of TNF- ${alpha}$ -treated sample (sub-G1_TNF - sub-G1_untreated) for each oligonucleotide-treated population. (^*p < 0.05 compared with LipofectAMINE or control oligo-treated samples). (D) Oligonucleotide-treated cells were stimulated with TNF- ${alpha}$ (10 ng/ml) for 8 h, and DNA fragmentation was assayed by Cell Death ELISA (see MATERIALS AND METHODS). Data represent mean (± SD) O.D. values at 490 nm (which is proportional to DNA fragmentation) of three independent experiments with triplicates for each treatment. (^**p < 0.005 compared with LipofectAMINE or control oligo-treated samples). (E) MCF7 cells grown on coverslips (two coverslips per treatment) were cotransfected with FLAG-BAD constructs (wild-type [wt] and dual phosphorylation site mutant [dm]) with EGFP. Twenty-four hours after the transfection, cells were treated with TNF- ${alpha}$ (10 ng/ml) for 8 h with or without 1-h pretreatment with E₂ (10 nM). Cells were fixed in 3% paraformaldehyde, mounted on to glass slides, and stained with Hoechst 33342. Two hundred cells expressing EGFP were randomly selected from each slide, and nuclear morphology was analyzed. Round nuclei with clear periphery were considered as live and shrunk nuclei were considered as dead (Candolfi et al., 2002

). The percentage of apoptotic nuclei in the transfected population is shown on the y-axis. Four independent experiments were carried out to validate data. WtBAD-expressing cells treated with E₂ and TNF- ${alpha}$ had significantly less apoptosis than similarly treated dmBAD-expressing cells (#p < 0.05) or TNF- ${alpha}$ -treated wtBAD-expressing cells (^*p < 0.05). (F) Cells expressing FLAG-tagged wtBAD, dmBAD, or empty vector pcDNA3 at indicated doses were treated with TNF- ${alpha}$ with or without and E₂ and analyzed as in D. In 1, reduction of apoptosis in response to E₂ is graphed against the dose of BAD. The percentage of reduction was calculated by the formula [100 - (apoptosis _TNF-+E2 ÷ apoptosis _TNF x 100)]. In 2 and 3, the fold apoptosis compared with untreated control for each transfection is presented. Nonlinear regression curves for data points were drawn using GraphPad Prism software (GraphPad Software). Means of two independent experiments for each dose are presented in the graphs. Panel 4 shows the result of a representative experiment with pcDNA3 at the regular dose. Same treatments with untransfected MCF7 cells show comparable results (Figure 1B).

To assess the effects on BAD in E₂-induced cell survival andconsequent changes in cellular morphology, we transiently expressedwild-type BAD (wtBAD) and dual phosphorylation site mutant ofBAD (dmBAD) where S112 and S136 are mutated to unphosphorylatablealanine, together with an EGFP expression vector. After thedesired treatments, coverslip cultures were stained with Hoechst33342 and mounted on to glass slides. As shown in Figure 4E,E₂ reduced the TNF- ${alpha}$ -induced apoptosis in wtBAD expressing cellsby >50%, and importantly had no protective effect in dmBAD-expressingcells. Pretreatment of E₂ had the same protective effect againstTNF- ${alpha}$ in cells expressing the control vector pcDNA3 or EGFP alone(our unpublished data). It must be emphasized that the overexpressionof dmBAD did not alter the number of apoptotic nuclei comparedwith those in pcDNA3- or EGFP-transfected cultures. There isan absolute requirement for TNF- ${alpha}$ to induce apoptosis in dmBADas well as wtBAD expressing cells. The magnitude of apoptosisobserved with cell counting ( $~$ 8- to 9-fold in Figure 4E) is somewhathigher than that observed with DNA fragmentation ELISA assay(4- to 5-fold in Figures 1B and 4D) in response to TNF- ${alpha}$ . Possibleexplanation for such differences in magnitude may be the factthat only a fraction of all the cells (i.e., the transfectedpopulation) is counted in Figure 4E, whereas in Figures 1B and4D DNA fragmentation of the whole population is measured.

Similarly transfected and treated cells were examined by theconfocal microscopy to further analyze the cellular morphologicalchanges (Supplementary Figure 1). TNF- ${alpha}$ -induced cellular shrinkageand atypical structure of nuclei in MCF7 cells as has been describedpreviously for fibroblast (Luschen et al., 2000) and neuronalcells (Candolfi et al., 2002). It was difficult to observe thechromatin clumping (typical for apoptosis) in TNF- ${alpha}$ -treated cellsdue to shrinkage of the nuclei as opposed to this feature readilyapparent in paclitaxel-treated cells (our unpublished data).Under these conditions, expression of exogenous wtBAD or mostimportantly, dmBAD (white arrows in florescence images and respectivedifferential interference contrast images) did not enhance basalapoptosis (1 and 4). Treatment with TNF- ${alpha}$ in wt and dmBAD-transfectedcells clearly induced apoptotic changes (2 and 5). Whereas E₂was able to impede morphological effects of TNF- ${alpha}$ in wtBAD-expressingcells (3), it was unable to counteract the effects of TNF- ${alpha}$ indmBAD-expressing cells (6 and 7). Black arrows in 6 and 7 pointto the untransfected cells that preserve the normal morphology.Under these conditions, expression of EGFP alone did not inducemorphological changes (white arrows in the insert). These observationsfurther support the proposed crucial role of BAD in MCF7 cellsand the critical importance of the two specific phosphorylationsites in BAD for the antiapoptotic effects of E₂. It is veryclear that dmBAD by itself does not induce apoptosis in theabsence of TNF- ${alpha}$ . This suggests that in these mammary carcinomacells, there are mechanisms to possibly sequester BAD away frommitochondria independent of S112 and S136 phosphorylation andbinding to 14-3-3 proteins, thus making dmBAD ineffective asan apoptosis inducer by itself. Antiapoptotic effect of E₂ wasfurther evaluated in cells expressing increasing levels of BAD.MCF7 cells were transfected with 1/4x, 1/2x, 1x, and 2x (x =regular dose = 0.6 µg of DNA for 10 cm²) of each constructand were treated with TNF- ${alpha}$ with or without E₂. DNA fragmentationwas assayed as in Figure 4D. As shown in Figure 4F, 1, E₂ reducedapoptosis by 45-60% in the wtBAD-expressing cells, irrespectiveof the dose, in agreement with Figure 4E. E₂-mediated protectionwas dampened by the overexpression of dmBAD by 50% or more.A moderate dose dependency in response to dmBAD was observedin TNF- ${alpha}$ as well as the E₂ + TNF- ${alpha}$ -treated cells (Figure 4F, 3).The values of apoptosis as measured by ELISA in pcDNA3, wtBAD,and dmBAD were unrelated to the dose of DNA. Therefore, whenthe DNA fragmentation values were averaged for the three typesof transfections there was absolutely no difference among theconstructs (O.D. values at 405 nm of 0.15, 0.16, and 0.15 forpcDNA3, wtBAD, and dmBAD, respectively). Increasing doses ofwtBAD did not influence the basal apoptosis, TNF- ${alpha}$ -induced apoptosis,or the protection offered by E₂ as shown in Figure 4F, 2. Panel4 demonstrates the fold induction of apoptosis in pcDNA3-expressingcells at regular dose of BAD. In wtBAD-transfected cells (Figure 4F, 1 and 2)E₂ is able to decrease the apoptosis due to TNF- ${alpha}$ to the same extent as in untransfected or pcDNA3-transfectedcells (Figures 1B and 4F, 4) by 50-60% when measured by theELISA method. Therefore, untransfected cells are unlikely toinfluence results in the wtBAD-transfected cells. In contrast,the inability of E₂ to prevent apoptosis in dmBAD mutant transfectedcells is likely to be underrated as the ELISA measurement isan average of transfected and untransfected cells. In the latter,E₂ will prevent apoptosis in the majority of the cells, therebydiluting the apoptotic effect of dmBAD-transfected cells. Together,the data in Figure 4, E and F, and Supplementary Figure 1 stronglysuggest that dmBAD is not an apoptosis inducer by itself inMCF7 cells. This reinforces our notion that in these cells,TNF- ${alpha}$ (and perhaps other apoptotic stimuli) is able to translocatecytoplasmic BAD to its mitochondrial sites of action irrespectiveof phosphorylation at S112 and S136 residues.

Estradiol-induced BAD Phosphorylation Requires Ras-activated Signaling Pathways, and Ras Function Is Critical for Cell Survival of MCF7 Cells
Previous studies in our laboratory had demonstrated that E₂induced p27^kip1 degradation and entry of quiescent MCF7 cellsto the cell cycle requires Ras activity (Ahamed et al., 2001,2002; Foster et al., 2001). Other investigators have demonstratedthat E₂ rapidly activated Ras in MCF7 cells (Keshamouni et al.,2002), and recent work in our laboratory (Foster, 2003) demonstratedthat Ras activity is required for nuclear export and degradationof p27^kip1 in response to E₂. The phosphorylation of BAD atS112 and S136 has been proposed to be mediated by ERK/p90^RSK1and PI-3K/Akt pathways, respectively, in addition to other mechanisms(Downward, 1999, and references therein). Given the role ofRas discussed above and the evidence that the PI-3K and ERKpathways are activated by E₂ (as discussed below), we used chemicalinhibitors LY294002 and PD98059 to inhibit these pathways, respectively,and determined the effects of these treatments on BAD phosphorylation.As shown in Figure 5A, E₂ induced BAD phosphorylation on S136as well as S112 was completely abrogated by LY294002, supportingthe idea of cross talk between the MAPK/p90^RSK1 and PI-3K/Aktpathways in enhancing the BAD phosphorylation (discussed underFigure 7). Similarly PD98059 effectively reduced the phosphorylationof BAD at S112 as determined by Western blots; however, theMEK inhibitor had considerably less effect on BAD S136 phosphorylation(compare E₂ vs. PD + E₂ on BAD phosphorylation on S136). Noneof the treatments changed total BAD levels in this time frame.

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Figure 5. Estradiol-induced BAD phosphorylation is mediated through Ras-activated signaling pathways. (A) MCF7 cells were pretreated with LY294002 (20 µM) or PD98059 (50 µM) for 1 h before E₂ treatment for 15 min. BAD phosphorylation at S112 or S136 and total BAD protein level were measured in cell lysates by Western blotting. LY294002 and PD98059 had minimal effects on BAD basal phosphorylation. Whereas LY294002 reversed the phosphorylation at both S112 and S136 residues induced by E₂, PD98059 effectively blocked S112 phosphorylation and partially reduced S136 phosphorylation in response to E₂. Blots shown are from a representative experiment that was repeated at least three times with similar results. (B) 1, FLAG-tagged wtBAD was cotransfected with empty vector pcDNA3, RasN17, or RasV12T35S (selective Raf activator) at 1:1 ratio into MCF7cells. Twenty-four hours after the transfection, cells were serum withdrawn for additional 24 h and treated with E₂ for 15 min. Cell lysates were analyzed for phosphorylated BAD (endogenous/exogenous), endogenous total BAD, and FLAG by Western blotting. Note that RasN17 abolished E₂-induced BAD phosphorylation and E₂ further enhanced the RasV12T35S-induced BAD phosphorylation at both S112 and S136. Panel 2 shows the Ras levels in untransfected and Ras-overexpressing cells. Blots shown are from a representative experiment that was repeated twice with comparable results. (C) Cells grown on coverslips (as triplicates) were cotransfected with EGFP together with indicated constructs. Cells were maintained in complete medium for 48 h after the transfection, fixed in 3% paraformaldehyde, stained with Hoechst 33342, and mounted on to glass slides. In RasN17-transfected cultures, the floating cells were collected and cyto-spun on to glass slides. At these time points the amount of floating cells observed in other cultures were negligible. Nuclear morphology of cells with green fluorescence was scored either as normal or apoptotic using fluorescence microscopy. In untransfected control cultures, cells were randomly selected for scoring. Two hundred cells/nuclei were counted from each slide. Mean results of two experiments are shown in the graph. Representative images are shown in the supplementary Figure 2. Note that expression of empty vector, EGFP, or RasV12T35 did not increase the number of detached cells.

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Figure 7. 17- ${beta}$ -Estradiol induces activity of ERKs and p90^RSK1. (A) Serum-starved MCF7 cells were treated with E₂ (10 nM) for indicated times. ERK2 immunoprecipitates were subjected to in vitro kinase assay with MBP as a substrate. Band intensities were quantified by densitometry. Graph presents data from three experiments (^*p < 0.05 and ^**p < 0.005 compared with time 0). (B) MCF7 cells were treated with E₂ (10 nM) with or without pretreatment of LY294002 (20 µM) or ICI182,780 (1 µM) for 1 h. Cell lysates were assayed by Western blot by using phospho-ERK and ERK2 antibodies. (C) Adenoviral PTEN and Lac-Z (control)-infected cells were serum deprived and treated with IGF-1 (10 ng/ml) or E₂ (10 nM) for 15 min. Panel 1, Western blot analyses of cell lysates with phospho-ERK and ERK2 antibodies. Panel 2, ERK2 immunoprecipitates from the above-mentioned lysates were subjected to in vitro kinase assay with MBP in the presence of [ ${gamma}$ -³²P]ATP, and band intensities are presented in the graph. Data shown are representative of three independent experiments. Panel 3 shows the overexpression of PTEN by the viral vector. (D) Cells were treated as in C. Akt and p90^RSK1 immunoprecipitates were subjected to in vitro kinase assays with BAD as a substrate in the presence of [ ${gamma}$ -³²P]ATP. Band intensities of two experiments are shown in the graphs.

Because Ras is a well-known upstream regulator of the PI-3K/Aktand MEK/ERK/p90^RSK1 pathways, we analyzed the effects of inhibitionof endogenous Ras by using dominant negative Ras RasN17 (DNRas)or selectively activating the MEK/ERK pathway with RasV12T35S(Hamad et al., 2002) in transient transfection experiments.FLAG-tagged BAD was cotransfected with control empty vector,RasN17, or RasV12T35S into MCF7 cells. Twenty-four hours afterthe transfection, cells were serum withdrawn for another 24h and stimulated with E₂ for 15 min. BAD phosphorylation wasassessed by Western blotting. Clearly, the ability of E₂ toincrease both S112 and S136 phosphorylation (Figure 5B, 1, lane2)of exogenous as well as endogenous BAD was inhibited by RasN17(lane 4), which by itself did not regulate BAD phosphorylation(lane 3). The MEK/ERK-selective activator RasV12T35S by itselfsignificantly activated BAD S112 phosphorylation and moderatelyactivated exogenous BAD S136 phosphorylation (lane 5), and E₂was able to enhance this effect (lane 6). Together, the resultsin Figure 5, A and B, strongly indicate that the ability ofE₂ to stimulate BAD phosphorylation and thereby prevent apoptosisis mediated through Ras-activated MEK/ERK and PI-3K/Akt pathways.

To directly analyze the apoptotic effects of RasN17 in thesecells, we stained nuclei of Ras-transfected cells and studiedthem by using the confocal microscope. Nuclei correspondingto EGFP-expressing cells (cotransfected with Ras or controlvector) were counted, and the graph (Figure 5C) shows the numberof fragmented nuclei as a percentage of total number of cells.Transient overexpression of RasN17 induced seven- to eightfoldapoptosis over a 48-h period, whereas the expression of RasV12T35Sor empty vector had minimum effects on apoptosis observed incells coexpressing EGFP. Representative morphological data areshown in Supplementary Figure 2 (1-5), which clearly demonstratesthat expression of EGFP, empty vector, or RasV12T35S (1-3) didnot alter nuclear morphology. However, RasN17-induced apoptoticnuclear morphology in the detached dead cells (5), whereas untransfectedattached cells from the same cultures (4) had normal nuclei.These results demonstrate that Ras function is required to protectMCF7 cells from dying even in the presence of growth mediumand that this effect may be mediated at least partly by phosphorylatingand inactivating proapoptotic BAD. The observation that E₂ inducedBAD phosphorylation was abolished by inactivation of endogenousRas (Figure 5B) further highlights the involvement of Ras-mediatedpathways in E₂ signaling and demonstrates that Ras plays a criticalrole in the antiapoptosis mediated by E₂ in MCF7 breast cancercells.

Estradiol Activates the PI-3K/Akt Pathway, Leading to Phosphorylation of Downstream Targets
Activation of PI-3K and Akt and Inactivation of GSK3 ${beta}$ by E₂ Theabove-mentioned data strongly argues that the ability of E₂to decrease apoptosis in MCF7 cells is at least partly mediatedby the PI-3K/Akt pathway. Transient activation (measured byS473 phosphorylation) of Akt by E₂ in MCF7 cells was reportedpreviously (Castoria et al., 2001; Razandi et al., 2002) (seeDISCUSSION) while this work was in progress (Fernando and Wimalasena,2000, 2002). Our data suggest that the PI-3K/Akt pathway mayneed to be activated for a prolonged period to maintain BADin an inactivated (phosphorylated) state. Therefore, we measureddetailed kinetic behavior of the PI-3K response to E₂. PI-3Kactivation was determined by phosphorylation of IRS-1 on S612by in vitro kinase assay using immunoprecipitates of the p85subunit of PI-3K. As shown in Figure 6A, E₂ was able to rapidlyactivate PI-3K approximately threefold, similar in magnitudeto the activation elicited by IGF-1. A detailed time courseof Akt catalytic activity measured by in vitro kinase assays(n = 3) using Akt immunoprecipitates and BAD as the substrateis shown in Figure 6B. Treatment with E₂ does not change proteinlevels of Akt in this time period (our unpublished data). Thesedata demonstrate that in contrast to the results from the S473phosphorylation assay (Castoria et al., 2001), catalytic activityof Akt is increased at least for 120 min. GSK3 ${beta}$ is a downstreamtarget of Akt (Cross et al., 1995) and because of its potentialrole in the cell cycle, we determined GSK3 ${beta}$ activity by in vitrokinase assay using immunoprecipitates of GSK3 ${beta}$ . As shown in Figure 6C,E₂ rapidly and strongly inhibited GSK3 ${beta}$ activity. As expected,another Akt activator IGF-1 also completely inhibited GSK3 ${beta}$ activity.The effect of E₂ was sustained for 60 min (our unpublished data),and such a time course is compatible with the increase in cyclinD1 protein observed 3-4 h after E₂ addition to quiescent cells(Foster and Wimalasena, 1996; Foster et al., 2001).

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Figure 6. 17- ${beta}$ -Estradiol activates the PI-3K/Akt pathway. Serum-deprived MCF7 cells were treated with E₂ (10 nM) or IGF-1 (10 ng/ml) for indicated times. Immunoprecipitates of PI-3K (A), GSK3 ${beta}$ (C), and p90^RSK1 (E) were subjected to in vitro kinase assay with respective substrates in the presence of [ ${gamma}$ -³²P]ATP. Reactions were resolved by SDS-PAGE, and autoradiograms were obtained. Fold activation/inhibition compared with time 0 was determined by densitometry. Representative autoradiograms are shown along with graphs depicting mean values (± SD) of three or more independent experiments. Protein level of p90^RSK1 at these time points is shown below E. (B) Graph represents results (mean ± SD) of three independent in vitro kinase assays for Akt with BAD as substrate (^**p < 0.005 or ^*p < 0.05 compared with time 0). (D) Immunoprecipitates of p90^RSK1 from cells treated as in A were subjected to in vitro kinase assay with agarose conjugated BAD. BAD was collected, resolved on SDS-PAGE, and Western blotted with anti-phospho S112 BAD antibody, and fold stimulation was determined by densitometry. The experiment was repeated two times with comparable results.

Activation of ERKs by Estradiol. It is known that p90^RSK1 isphosphorylated at S364 and T574 residues by ERKs, leading toits activation (Dalby et al., 1998), and our results on BADphosphorylation imply that E₂ activates p90^RSK1. Therefore,we directly determined that E₂ rapidly activates p90^RSK1 byin vitro kinase assay using immunoprecipitates of p90^RSK1 (Figure 6, D and E),which shows that p90^RSK1 is activated within 5min by E₂. A number of studies reported that E₂ rapidly activatesERK1 and 2 in MCF7 cells (Improta-Brears et al., 1999, and referencestherein) and in a number of other cell types (Singh et al.,1999; Kousteni et al., 2001). However, others failed to observeE₂-mediated ERK activation in MCF7 cells (Dupont et al., 2000;Lobenhofer et al., 2000; Caristi et al., 2001), and E₂-inducedERK activity may not be a result of activation of the Ras/Rafsignal transduction pathway but may follow rapid increase inintracellular Ca²⁺ (Improta-Brears et al., 1999). Furthermore,we had previously demonstrated that increased cyclin D1 synthesisin response to estrogens is partly blocked by the MEK1 inhibitorPD98059 and that dominant negative ERK2 partially inhibitedthe induction of cell cycle transit by estrogens (Ahamed etal., 2001). Therefore, we measured a detailed time course ofERK activation by E_2. We found that E₂ rapidly activated ERK2with maximum activation of fivefold observed within 15 min (Figure 7A)and significant ERK2 activation was sustained for at least120 min. Enhancement of ERK activity by E₂ was partly blockednot only by pretreatment with the PI-3K inhibitor LY294002 butalso by the specific estrogen antagonist ICI182,780 (Figure 7B).Given the above-mentioned results and recent work indicatingthat there is cross talk between the PI-3K and ERK pathways(Hawes et al., 1996; Wennstrom and Downward, 1999), we exploredthis interaction further by overexpression of adenoviral PTEN.Whereas E₂ or IGF-1 activated ERKs in control Ad virus-infectedcells, PTEN overexpression ( $~$ 3x over the basal level; Figure 7C, 3)partly blocked ERK activation observed at 15 min of treatmentwith these two agonists (Figure 7C, 1). In confirmation of thesedata by using phospho-specific ERK antibodies, PTEN also partlyinhibited ERK2 activity measured by MBP phosphorylation in anin vitro kinase assay (Figure 7C, 2). In extracts from similarlytreated cells, BAD phosphorylation in vitro by Akt and p90^RSK1was also selectively abrogated by PTEN overexpression (Figure 7D),demonstrating that PTEN overexpression inhibited Akt andp90^RSK1 activation. These results suggest that the PI-3K pathwaymay regulate the ERK response in addition to the Akt responsein MCF7 cells and provide evidence for cross talk between thesesignal pathways in response to E₂ or IGF-1 under our experimentalconditions.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUMMARY
ACKNOWLEDGMENTS
REFERENCES

Regulation of Apoptosis by E₂
E₂ is known to support cell survival or induce cell death/apoptosisdepending on the cell context (Choi et al., 2001; Okasha etal., 2001). Most of E₂'s actions on cell survival or death,as for many other steroid hormone actions, have been attributedto gene regulation. Emerging evidence for nongenomic actionsof E₂ (reviewed in Kelly and Levin, 2001) prompted us to examinethe signaling mechanisms of E₂ with respect to regulation ofcell survival in MCF7 breast cancer cells. We had previouslyshown that estrogens were able to decrease apoptosis inducedby mitogen withdrawal in MCF7 cells (Ahamed et al., 2001). Ourpresent study shows that E₂ significantly reduces apoptosisinduced by TNF- ${alpha}$ , H₂O₂, and serum withdrawal by using signaltransduction pathways that lead to phosphorylation and inactivationof proapoptotic protein BAD. In Figure 8 we summarize our resultsand present a model on how E₂ is able to promote cell survivaland abrogate apoptosis in MCF7 cells. However, E₂ is unableto counteract the apoptosis-inducing effects of other agentssuch paclitaxel (our unpublished data); this observation isin contrast to recently published work (Razandi et al., 2002).

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Figure 8. Schematic diagram showing the proposed survival mechanism induced by 17- ${beta}$ -estradiol. Estradiol activates ERK/p90^RSK1 and PI-3K/Akt pathways possibly through Ras-dependent mechanisms. On activation of these signal pathways, proapoptotic BAD is phosphorylated at S112 and S136. Phoshphorylated BAD is sequestrated by 14-3-3 (and possibly by other molecules), thus preventing its action on the mitochondrial membrane. This mechanism ensures cell survival and may constitute the antiapoptotic effects observed when the apoptotic stimuli are present simultaneously with E₂. E₂ could not exert this protective effect when phosphorylation sites in BAD are mutated to unphosphorylatable residues. E₂-mediated signaling pathway is indicated by black arrows. Apoptotsis-inducing agents change mitochondrial membrane integrity and facilitate the release of substances such as cytochrome c into the cytoplasm. These in turn mediate a cascade of reactions, eventually leading to apoptosis that can be readily identified by characteristic features pointed out in the figure. Inhibition of BAD protein level by antisense mRNA could drastically reduce the amount of apoptosis observed with apoptotic agents, providing evidence for the critical involvement of BAD in this scenario. Signal pathways mediated by apoptotic stimuli are indicated by white arrows. Dominant negative Ras (RasN17) dramatically increases apoptosis even under exponential growth conditions and blocked the protective effects of E₂, suggesting an essential cell survival role for Ras.

Role of BAD in Apoptosis and Its Regulation by E₂
E₂ effects on BCL2 family members have been described previously:in cells where survival is promoted, E₂ increased mRNA (Perilloet al., 2000) and protein levels of antiapoptotic BCL2 (Donget al., 1999; Choi et al., 2001) or down-regulated proapoptoticBak protein (Leung et al., 1998). In contrast to regulationof BCL2 and Bak at the transcriptional level, we find that E₂rapidly induces phosphorylation of BAD at two serine residues(112 and 136) without altering BAD protein levels (Figure 3B),suggestive of activation of nongenomic signal pathways. Giventhe fact that proapoptotic effects of BAD are decreased by phosphorylationand consequent sequestration by 14-3-3 proteins (Downward, 1999),we sought to determine whether E₂-induced phosphorylation ofBAD is important for the antiapoptotic functions of E₂.

BAD complexes with BCL2 and BCLxl, and leads to loss of mitochondrialintegrity (Hirai and Wang, 2001); therefore, release of cytochromec into the cytoplasm is expected after BAD "activation." Theapoptotic stimuli increased the cytochrome c levels in the cytoplasm,and cotreatment with E₂ reduced this effect concomitant withimproved cell survival (Figure 1D). This suggests the restorationof mitochondrial integrity at least to some degree in E₂-treatedcells and may account for antiapoptotic effects of E₂. In cellstreated with TNF- ${alpha}$ and H₂O₂, the extent of S112/136 BAD phosphorylationwas lower than that observed in control cultures (Figure 3C),implicating the activation of BAD by these apoptotic stimuli.Estrogen treatment in this context restored phosphorylationto control levels. These experiments, along with those demonstratingthat E₂ prevents apoptosis in cells overexpressing wild-typebut not the double phosphorylation site mutant (S112A/S136A)of BAD (Figure 4, E-F), suggest that BAD phosphorylation hasa central role in apoptosis of MCF7 cells. Remarkably, the overexpressionof BAD (S112A/S136A) did not cause apoptosis by itself, suggestingthat in addition to phospho-serine-mediated cytosolic 14-3-3binding there may be other mechanisms to sequester BAD awayfrom mitochondria. These mechanisms effectively inactivatingBAD are counteracted by apoptotic stimuli such as TNF- ${alpha}$ . Bindingof BAD to other cellular proteins such as glucokinase has beendemonstrated in the rat liver (Danial et al., 2003).

To confirm the importance of BAD in MCF7 cells, we used antisenseoligonucleotides to suppress BAD protein translation (Figure 4A)and analyzed the effects of selected agents on MCF7 cellsurvival. Diminution of BAD in MCF7 cells significantly reducedthe extent of apoptosis induced by TNF- ${alpha}$ (Figure 4, B-D). Thisobservation is in accordance with previously published studieswhere overexpression of BAD was shown to enhance cell death(Ottilie et al., 1997; Virdee et al., 2000). The fact that antisenseBAD blocked ability of TNF- ${alpha}$ to induce apoptosis (Figure 4, C and D)suggests that BAD phosphorylation/inactivation has acentral role in apoptosis of MCF7 cells in response to stimulisuch as TNF- ${alpha}$ .

Agents such as TNF- ${alpha}$ and H₂O₂ have been shown to have mixed effectson BAD protein levels and phosphorylation. TNF- ${alpha}$ increased phosphorylationof BAD through PI-3K pathway in neutrophils (Cowburn et al.,2002), and in HeLa cells (Pastorino et al., 1999) where cellsurvival rather than the cell death was promoted. TNF- ${alpha}$ alsoinduced the production of more potent truncated form of BADin a caspase 3-dependent manner, leading to apoptosis in Jurkatcells (Condorelli et al., 2001). Similarly, H₂O₂ but not superoxideanion (O₂^-) has been shown to increase BAD protein levels incardiomyocytes, leading to apoptosis (von Harsdorf et al., 1999).Serum starvation may modulate activity of BAD and other apoptosisregulators, and such effects may be reversed by addition ofgrowth factors or by manipulating signal transduction pathways(Yano et al., 1998; Bai et al., 1999). Recent