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Akt-Mediated Phosphorylation and Activation of Estrogen Receptor Is Required for Endometrial Neoplastic Transformation in Pten^+/– Mice

¹ Human Genetics Program and ² Department of Pathology, Fox Chase Cancer Center, Philadelphia, Pennsylvania and ³ Weill Medical College of Cornell University, New York, New York

Requests for reprints: Antonio Di Cristofano, Human Genetics Program, Fox Chase Cancer Center, 333 Cottman Avenue, Philadelphia, PA 19111. Phone: 215-214-1647; Fax: 215-214-1623; E-mail: antonio.dicristofano{at}fccc.edu.

	Abstract

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PTEN is a tumor suppressor gene frequently mutated in human cancers. In vitro and in vivo studies have shown that PTEN can exert its tumor suppressive function through a variety of mechanisms, including regulation of cell death and cell proliferation. However, it is still unclear which of the many downstream pathways are critical in each different tissue, in vivo. Loss of PTEN is the earliest detectable genetic lesion in the estrogen-related type I (endometrioid) endometrial cancer. Pten^+/– mice develop endometrial neoplastic lesions with full penetrance, thus providing a model system to dissect the genetic and biochemical events leading to the transition from normal to hyperplastic and neoplastic endometrial epithelium. Here, we show that loss of Pten in the mouse endometrium activates Akt and results in increased phosphorylation of estrogen receptor (ER) on Ser¹⁶⁷. ER phosphorylation results, in turn, in the activation of this nuclear receptor both in vivo and in vitro, even in the absence of ligand, and in its increased ability to activate the transcription of several of its target genes. Strikingly, reduction of endometrial ER levels and activity dramatically reduces the neoplastic effect of Pten loss in the endometrium, in contrast to complete estrogen depletion. Thus, we provide for the first time in vivo evidence supporting the hypothesis that loss of Pten and subsequent Akt activation result in the activation of ER-dependent pathways that play a pivotal role in the neoplastic process. (Cancer Res 2006; 66(7): 3375-80)

	Introduction

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The PTEN tumor suppressor gene encodes a protein/lipid phosphatase whose main in vivo function is to convert phosphatidylinositol (3,4,5)-triphosphate (PIP-3), the product of phosphatidylinositol 3-kinase (PI3K) activity, into phosphatidylinositol (4,5)-biphosphate (1). The levels of PIP-3 rapidly increase upon growth factor stimulation and activation of PI3K, allowing recruitment and activation of proteins containing a pleckstrin homology domain. Among these is the Akt kinase that, upon membrane recruitment, is activated by phosphorylation (2). AKT, in turn, phosphorylates an ever-growing list of target proteins regulating key processes, such as proliferation, survival, cell size, and mRNA translation (2). Somatic deletions or mutations of PTEN have been identified in a large fraction (12-60%) of human tumors (3). Loss of PTEN is mostly associated with advanced-stage tumors. However, the endometrioid subtype of endometrial cancer (EEC) represents one remarkable exception. EEC is estrogen related, low grade, develops in premenopausal and perimenopausal women, and is often preceded by complex atypical endometrial hyperplasia (4). PTEN is completely lost or mutated in >50% of primary EECs (5) and in at least 20% of endometrial hyperplasias, the precancerous lesions of the endometrium (5, 6). Thus, loss of PTEN is a very early event in the multistep process leading to EEC.

Consistent with the human tumor data, Pten^+/– mouse mutants, in the mixed C57/BL6x129/Sv genetic background, show a striking susceptibility to develop a broad array of tumors (7, 8), including endometrial complex atypical hyperplasia and carcinoma (9, 10). The endometrial lesions are dramatically accelerated by the simultaneous inactivation of p27KIP1 (11) or Mlh1 (12), further supporting the current multistep models of endometrial tumorigenesis.

The goal of this study was to further exploit the Pten^+/– mouse model to investigate the mechanisms of endometrial neoplastic transformation upon loss of Pten.

	Materials and Methods

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Animals and treatments. Generation of Pten^+/– mice has been described (7). Ovariectomy was done on 3-week-old C57/BL6x129/Sv mice and on 14-week-old 129/Sv mice. ICI 182,780 (AstraZeneca, Wilmington, DE) was injected s.c. weekly at 0.5 mg/mouse. For diethylstilbestrol treatment, newborn mice were injected s.c. with 2 µg of diethylstilbestrol in corn oil for five consecutive days as described (13).

Luciferase assays. Ishikawa EEC cells and their derivative IT-3015 (14) were grown in DMEM/10% fetal bovine serum (FBS). Transfections were done with GeneJammer (Stratagene, La Jolla, CA) according to the manufacturer's protocol. Cells were grown for 24 hours in E₂-free medium and transfected in sextuplicate with 800 ng of ERE2-TK-LUC reporter (containing a luciferase gene regulated by two estrogen response elements) with or without 200 ng of pCMV5-ER, pCMV5-ER^S167A, pcDNA-PTEN, pcDNA-PTEN^C124S, pCMV5-MyrAKT. Three hours after transfection, the cells were treated with or without E₂ (100 nmol/L) and/or doxycycline (2 µg/mL) for 36 hours. Luciferase activity was measured with the Promega Luciferase kit (Madison, WI) according to the manufacturer's recommendations. Values were normalized by protein content because Akt activation strongly affects both the expression of Renilla luciferase–based constructs and the pCMV-ßgal reporter (data not shown).

Immunohistochemical analysis. The rabbit polyclonal antibodies used were anti-Pten (NeoMarkers, Fremont, CA), anti-phospho-AKT S473, and anti-phospho-ER S167 (Cell Signaling, Beverly, MA). Tissues were fixed in buffered 10% formalin, embedded in paraffin, and sectioned at 6 µm. Sections were subjected to antigen retrieval in 0.1 mol/L sodium citrate and counterstained with hematoxylin.

Primary endometrial epithelial cells isolation. Uteri from age-matched wild-type and Pten^+/– cohorts were removed, pooled, and immediately minced in 1-mm fragments. The tissues were incubated in 50-mL conical tubes containing 0.5% collagenase and 0.1% DNase II in HBSS for 30 to 45 minutes at 37°C, with shaking. The tubes were then kept vertical for 10 minutes at room temperature to settle the glands. The top two thirds of the supernatant, containing stromal cells, was removed, and DMEM/10% FBS was added to the glands. This procedure was repeated thrice, resulting in a final pellet of highly purified endometrial glands.

Real-time PCR. Total RNA was extracted with TRIzol (Invitrogen, Carlsbad, CA) from pooled primary endometrial epithelial cells. Two micrograms of RNA were reverse transcribed with a commercially available kit (Thermoscript, Invitrogen). cDNAs were diluted 10-fold, and 10 µL were used for real-time PCR on the ABI Prism 7900 Sequence Detection System using Taqman Master mix and primers (Applied Biosystems, Foster City, CA). Each sample was run in triplicate, and ß-actin was used to control for input RNA. Fluorescence was measured with the Sequence Detection Systems 2.0 software. After adjusting with the ß-actin control, the difference in cycle crossing points was calculated for each gene between the wild-type group and mutants. For a theoretical efficiency of 100%, the fold difference was calculated by 2 to the power of the cycle point difference. Experiments were repeated at least twice.

	Results and Discussion

Top Abstract Introduction Materials and Methods Results and Discussion References

 
To circumvent the phenotypic variability associated with mixed genetic backgrounds, we have bred the Pten allele into a pure 129/Sv strain. All Pten^+/– female mice in this genetic background develop, starting at 3 months of age, multiple endometrial hyperplastic lesions characterized by stratification of the glands; dramatically enlarged epithelial cells showing eosinophilic cytoplasm, nuclear atypia, and abnormal cell polarity (Fig. 1D ); dilation of the gland lumen; papillary formation; and increasing gland/stromal ratio. Complete loss of Pten expression is very common even in small early lesions (data not shown). Between 5 and 9 months of age, these lesions progress from extensive atypical hyperplasia to in situ carcinomas. Locally invasive carcinomas, defined by clear myometrial/serosal invasion, occur in 30% of the animals. Most animals succumb by the 10th month of age due to extensive hemorrhage and necrosis consequent to the multifocal obliteration of the uterine horns. These characteristics closely mimic both the natural history and the pathologic features of human EEC (Fig. 1G), of which this mouse is a valuable model.

View larger version (126K): [in this window] [in a new window]   Figure 1. Loss of Pten in the mouse and human endometrial epithelium is associated with Akt (S473) and ER (S167) phosphorylation. Representative sections of murine wild-type (A-C) and Pten+/– (D-F) endometrium at 25 weeks of age compared with a human grade 1 tumor (G-I), stained with H&E (A, D, and G) to show the glandular epithelium (A, arrow), with anti-phospho-Ser473-Akt (B, E, and H) and anti-phospho-Ser167-ER (C, F, and I). Note the dramatic increase in cell size upon loss of Pten (A and D). Original magnification, x400.

The development of estrogen-related neoplastic lesions in the absence of detectable hyperestrogenism suggests that there might exist a functional and physiologic link between loss of Pten and increased estrogen receptor (ER) activity. Several in vitro studies have suggested the existence of a crosstalk between Akt and ER (15, 16). Akt can phosphorylate and activate ER at Ser¹⁶⁷, in the ligand-independent transcriptional activation domain (AF1), at least in vitro and in cell culture systems (17, 18). Nevertheless, in vivo data defining the existence and physiologic relevance of this interaction, as well as its role in EEC pathogenesis, are still missing.

To assess whether this functional link exists in vivo, we did immunohistochemistry on serial uterine sections from wild-type and Pten heterozygous mice using antibodies recognizing the phosphorylated, active forms of both Akt (Ser⁴⁷³) and ER (Ser¹⁶⁷). The endometrial glands of wild-type mouse uteri express low levels of both active Akt- and Ser¹⁶⁷-phosphorylated ER (Fig. 1B and C). However, the hyperplastic endometrial glands from age-matched Pten heterozygous females showed strikingly increased phosphoprotein levels of both Akt and ER, suggesting a direct causal relationship between Akt activation and ER phosphorylation in vivo (Fig. 1E and F). This correlation was also maintained in a small pilot group of nine human grade 1 EEC samples selected based on loss of PTEN expression. As expected, all cases analyzed expressed high levels of phospho-AKT (Fig. 1H). Seventy-five percent of cases had strong phospho-ER immunoreactivity (Fig. 1I), suggesting that loss of PTEN, activation of AKT, and phosphorylation of ER may be related events also in human EEC.

To formally prove that activated Akt is able to phosphorylate ER in endometrial epithelial cells, we did transient transfection experiments in IT3015, a subclone of the PTEN null Ishikawa EC cell line, engineered to reexpress PTEN upon doxycycline treatment. Both the IT3015 cells and the original Ishikawa strain in our possession express very low levels of endogenous ER. When we transfected IT3015 cells with wild-type human ER, we could readily detect receptor phosphorylation at Ser¹⁶⁷ by Western blot, using a phospho-specific antibody (Fig. 2A ). However, drastic reduction of AKT phosphorylation upon PTEN induction resulted in a parallel decrease in the phosphorylation of ER. This inhibition was bypassed by the expression of a myristoylated, constitutively active form of AKT, which is not affected by the presence of PTEN. These data further confirm that loss of PTEN in EC cells results in the phosphorylation of ER through the activation of AKT.

View larger version (16K): [in this window] [in a new window]   Figure 2. Activated Akt phosphorylates ER, resulting in increased transcriptional activity, even in the absence of estrogen. A, Western blot analysis of ER phosphorylation in IT3015 cells in the presence or absence of activated Akt. B-D, luciferase assays done in Ishikawa (B and C) and IT3015 cells (D) transiently transfected with an estrogen-dependent reporter and the indicated expression vectors. E, RT-PCR determination of the expression levels of E-cadherin, ER, Efp/Znf147, and Gapdh in isolated primary endometrial epithelial cells. F, real-time PCR analysis of the increase in expression of a series of estrogen target genes in primary endometrial epithelial cells, normalized to ß-actin expression.

We then asked whether this increase in ER transcriptional activity upon Akt activation is also true in vivo, in a much more complex physiologic setting. First, we did semiquantitative reverse transcription-PCR (RT-PCR) on RNA extracted from purified endometrial epithelial cells. We tested the expression levels of E-cadherin, to confirm the epithelial nature of the purified cells and to further normalize for the amount of epithelial cells, and ER, to exclude an effect of Pten loss on the expression of ER in vivo. No differences were noticed between the expression levels of these genes in the two groups of mice (Fig. 2E). Next, we tested a well-established ER transcriptional target, Efp/Znf147. Endometrial epithelial cells from Pten^+/– mice expressed Znf147 mRNA at much higher levels than wild-type cells, again strongly suggesting that loss of Pten results in vivo in increased ER transcriptional activity (Fig. 2E). To better measure this effect, we employed real-time RT-PCR and compared the expression levels of a series of estrogen-induced genes in RNAs from wild-type and Pten^+/– freshly isolated endometrial epithelial cells. Overexpression of pS2, Egr-1, c-fos, Efp/Znf147, Bcat1, and Ltf was readily detected in the mutant epithelium (Fig. 2F). Collectively, these data show that loss of Pten and activation of Akt result in vivo in a considerable increase in the mRNA levels of several estrogen target genes, suggesting that Akt-mediated phosphorylation of ER can significantly enhance the receptor response to its ligand and thus contribute to the initiation of the neoplastic process.

As the effect of Akt-mediated phosphorylation on ER transcriptional activity seems to be ligand independent, one important prediction from this model is that complete estrogen depletion will not be able to entirely inhibit the neoplastic process in the Pten^+/– endometrial cells.

To determine to what extent estrogen contributes to the development of the endometrial neoplastic lesions in Pten^+/– mice, we analyzed the uteri of 32-week-old Pten^+/– mice (in the C57/BL6x129/Sv background, for this experiment only) that had been ovariectomized at 3 weeks of age. As predicted by our model, estrogen-depleted mice still developed endometrial tumors, although their average number and size was reduced by about 50%. Strikingly, estrogen depletion did not result in a significant change in the proliferation index in Pten^+/– mice (Table 1 ). These results suggest that estrogen is not absolutely necessary for tumor development in cells expressing high levels of activated Akt and ER but can anyway cooperate with Akt activation to facilitate the neoplastic process.

View larger version (64K): [in this window] [in a new window]   Figure 3. The pure ER antagonist ICI 182,780 can partially inhibit endometrial tumor development consequent to Pten loss. A, representative photomicrographs of the endometrium of Pten+/– mice at 14 weeks of age and at 20 weeks, after ovariectomy or ICI treatment. Original magnification, x400. B, Western blot analysis of Akt phosphorylation and ER levels and phosphorylation in the uterus of mice subjected to the indicated treatments. C and D, ICI treatment reduces the number of lesions and the proliferation index in the uteri of Pten+/– mice. N.A., not available: lesion number could not be scored due to the extensive fusion of neoplastic areas and disruption of uterine architecture. E, real-time PCR analysis showing the decrease in expression of a series of estrogen target genes in the uterus of ICI-treated mice, normalized to ß-actin expression. F, diethylstilbestrol (DES) treatment inhibits endometrial neoplastic transformation consequent to Pten loss: representative photomicrographs of wild-type and Pten+/– oil-treated controls and of wild-type and Pten+/– diethylstilbestrol-treated mice. Original magnification, x400.

To evaluate the effect of ER reduction/inhibition on tumor development, we scored the number of lesions in the uteri of ovariectomized and ICI-treated mice. At this stage (20 weeks of age), it was already impossible to score individual lesions in the uteri of untreated Pten^+/– mice in the 129/Sv strain. Both ovariectomized and ICI-treated mice developed focal lesions (Fig. 3A), but the number of lesions in the ICI-treated females was less than half compared with ovariectomized mice (Fig. 3C). In addition, the proliferation index, determined by staining tissue sections with an antibody against the Ki-67 marker, was severely reduced by the ICI treatment but not by hormone depletion (Fig. 3D), as already discussed above. Real-time PCR on RNA extracted from the three cohorts showed that ICI treatment was more effective than estrogen depletion at reducing the expression of several markers of estrogenic activity (Fig. 3E). These results show that a decrease in ER levels and activity can dramatically reduce the development of endometrial lesions in Pten^+/– mice.

As a parallel approach, we took advantage of one long-term effect of the synthetic estrogen diethylstilbestrol in the mouse uterus. Diethylstilbestrol administration during postnatal days 1 to 5 elicits distinct alterations in several structures of the female reproductive tract, including scattered areas of metaplasia in the uterus and cervix and persistent cornification of the vaginal epithelium. Most importantly, adult mice that were exposed to diethylstilbestrol only in this neonatal time window show a significant reduction of ER levels and an attenuation of the physiologic effects of estrogen action in the uterus, a phenotype that partially mimics ER gene disruption as exhibited by the ERKO mice (20).

We injected diethylstilbestrol or control oil vehicle in newborn wild-type and Pten^+/– mice in the 129/Sv genetic background (n = 8 per group) and sacrificed them at 25 to 27 weeks of age. By this time, the uterus of a 129/Sv Pten^+/– mouse exhibits extensive endometrial lesions. The average uterine weight of the control Pten^+/– mice, normalized for their body weight, was 5-fold greater than that of the control wild-type mice (Table 2 ). However, reduction of the estrogenic response in sexually mature mutant mice, as a consequence of diethylstilbestrol treatment, resulted in the complete abolition of the hyperplastic features characterizing the uteri of age-matched Pten^+/– mice. Real-time PCR showed that, as expected, ER levels were severely reduced in the diethylstilbestrol-treated mice (Table 2). Strikingly, upon pathologic examination of tissue sections from the dissected uteri, we could not detect any neoplastic lesions in the diethylstilbestrol-treated Pten^+/– cohort (Fig. 3F). Moreover, although several areas of complete loss of Pten expression were commonly found in the control mutant cohort, the uteri from the diethylstilbestrol-treated Pten^+/– mice showed complete retention of Pten immunostaining, further confirming the absence of any neoplastic change (data not shown). Taken together with the ICI results, these data further support the hypothesis that inhibition/down-regulation of ER can efficiently disrupt the oncogenic pathways initiated by Akt activation.

View this table: [in this window] [in a new window]   Table 2. Diethylstilbestrol treatment reduces ER levels and completely inhibits uterine hyperplasia

Although further effort is clearly warranted to unravel the relative contribution of the different ER-dependent pathways to the neoplastic process, our results not only uncover a novel pivotal tumorigenic pathway but may also provide a rationale for the failure of treatments based on the use of aromatase inhibitors (27). In addition, our findings suggest that pure ER antagonists, such as fulvestrant, alone or in combination with aromatase inhibitors, may be an effective treatment choice in EECs characterized by loss of PTEN and AKT activation.

	Acknowledgments

 
Grant support: NIH grants CA097097 (A. Di Cristofano) and CA095427 (L.H. Ellenson) and W.W. Smith Charitable Trust (A. Di Cristofano).

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

We thank W. Kruger and J.R. Testa for critical reading of the article and the Transgenic, Laboratory Animal, Biomarker, and Histopathology core facilities of Fox Chase Cancer Center.

Received 11/ 8/05. Revised 1/19/06. Accepted 2/16/06.

	References

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