Abstract
Survivin (BIRC5) is a cell survival gene that is overexpressed in endometrial cancer and has been implicated to have a physiological role in normal endometrial function. To determine whether survivin gene expression is regulated by reproductive steroid hormones in the human endometrium, RNA was prepared from normal cycling women in the proliferative and secretory phases of the menstrual cycle. RNA was also isolated from 21 endometrial biopsies from premenopausal women at baseline and following 3 months of treatment with depot medroxyprogesterone acetate. Finally, RNA was isolated from endometrial biopsies from ten healthy postmenopausal women participating in a clinical trial of estrogen replacement therapy at baseline and following 6 months of treatment with conjugated equine estrogen. Quantitative RT-PCR analysis was used to determine survivin, insulin-like growth factor binding protein 1 (IGFBP1), Ki67, and IGF1 gene expression levels. Survivin gene expression was highest in the proliferative phase of the menstrual cycle and showed a statistically significant 4-fold increase in expression following chronic treatment with estrogens; this was strongly correlated with increased Ki67, a marker of proliferation. Survivin gene expression decreased 4.6-fold following chronic progestin treatment in the human endometrium. These data suggest that survivin transcript is regulated by estrogens and progestins in the disease-free human endometrium. The data also suggest that survivin transcript may be used as a biomarker of estrogen and progestin treatment efficacy, but validation studies must be conducted to support this conclusion.
Introduction
The human endometrium is a dynamic tissue that lines the uterine cavity. It is composed of both epithelial and stromal cells and is cyclically regenerated. The reproductive cycle in human females is driven through neuroendocrine signaling. Both positive and negative feedback loops within the hypothalamus and pituitary control steroid hormone production in the ovaries. Increased estrogen (E2) drives the endometrium into the proliferative phase of the cycle. As the cycle progresses, progesterone (P4) is secreted by the ovary, which inhibits proliferation and restructures the endometrium into a secretory tissue in anticipation of fertilization. If fertilization does not occur, the endometrium is shed and the local drop in hormone levels reactivates the cycle (Knobil 1972, Bischof et al. 1974). Several lines of evidence suggest that apoptosis also plays a significant role in the normal cycling of the human endometrium (Kokawa et al. 1996, Vaskivuo et al. 2000, Harada et al. 2004).
Survivin (BIRC5) is a member of the inhibitor of apoptosis (IAP) gene family. Survivin has received much attention as a mediator of cell survival due to its dual function in both apoptosis and cell cycle regulation. The pattern of survivin gene expression is distinct from the other IAPs. Survivin is highly expressed during embryonic and fetal development and is overexpressed in virtually all tumor types (Ambrosini et al. 1997, Li & Altieri 1999, O'Driscoll et al. 2003) including endometrial cancer (Lehner et al. 2002, Takai et al. 2002, Pallares et al. 2005, Nabilsi et al. 2009). In contrast, survivin is negligibly expressed in most highly differentiated adult tissues. It is, however, expressed in the cycling human endometrium (Konno et al. 2000, Tarkowski et al. 2000, Lehner et al. 2002, Fukuda & Pelus 2006), in the decidua and villus of early pregnant women (Li et al. 2002), and in non-malignant endometrial pathologies such as endometriosis (Tarkowski et al. 2001, Ueda et al. 2002, Goteri et al. 2005, Fujino et al. 2006) and endometrial hyperplasia (Tarkowski et al. 2000, Chen et al. 2009), suggesting that it may play a role in endometrial physiology and pathology.
Information on survivin function in normal tissues has been limited as survivin knockout mice suffer from embryonic lethality. Animal models have implicated a physiological role for survivin in the murine endometrium, but the precise function of survivin in endometrial tissue is unclear. High expression of survivin has been found in the endometrium of mice exhibiting defective implantation and subsequent pregnancy loss (Garcia et al. 2007, Li et al. 2008). Loss of survivin expression has also been described in the decidua of interleukin-11 receptor α null mice which are infertile due to aberrations in decidualization and trophoblast invasion (Garcia et al. 2007). Studies in endometrial cancer-derived Ishikawa cells indicate that silencing of survivin decreases cell proliferation and increases apoptosis via down-regulation of cyclin D1 and phospho-retinoblastoma protein and activation of caspase-3 and caspase-8 (Ai et al. 2006).
Since the endometrium is a hormone-responsive tissue, we hypothesized that if survivin is involved in maintaining normal tissue homeostasis, then it may be regulated by reproductive steroid hormones in the normal human endometrium. Studies in hormone-responsive cell lines indicate that survivin transcript and protein levels are increased by E2 treatment (Nakayama et al. 2000, Sayeed et al. 2007), and in Ishikawa cells, the induction is reversed upon treatment with the estrogen receptor antagonist Fulvestrant (Chen et al. 2009). Also in hyperplastic endometria and in Ishikawa cells, survivin protein is decreased by progestin treatment, and in Ishikawa cells, this decrease is reversed by treatment with the P4 receptor antagonist RU486 (Chen et al. 2009). The effects of estrogen and P4 administration on survivin expression in disease-free human endometrium have not been reported.
In this study, we measured survivin gene expression levels in vivo in cycling human endometrium before and after treatment with progestins and in postmenopausal endometrium after treatment with estrogens.
Materials and Methods
Endometrial samples
All human tissue samples were obtained from patients under protocols approved by Institutional Review Boards at the University of Texas Health Science Center and MD Anderson Cancer Center. Formalin-fixed, paraffin-embedded (FFPE) sections of human endometrial biopsies were obtained from the Department of Pathology, University of Texas MD Anderson Cancer Center (Houston, TX, USA) from 12 women who underwent biopsy for the clinical evaluation of abnormal vaginal bleeding as previously described (McCampbell et al. 2006). The endometrial samples were classified as proliferative (n=7) or secretory (n=5) according to Noyes criteria (Noyes et al. 1975) after microscopic examination of H&E-stained slides. For the proliferative phase endometrial biopsies, women ranged in age from 29 to 50 years (mean of 40.4 years), and body mass index (BMI) ranged from 17.1 to 52.3 kg/m2 (mean of 29.5 kg/m2). For the secretory phase endometrial biopsies, women ranged in age from 31 to 46 years (mean of 41.8 years), and BMI ranged from 19.3 to 30.3 kg/m2 (mean of 22.6 kg/m2). There was no significant difference in the mean age or BMI between women with proliferative or secretory phase endometrium (P=0.6 and P=0.2 respectively).
The RNA used for analysis of P4 regulation of survivin gene expression was obtained from healthy cycling women who were enrolled in a chemoprevention trial of depot medroxyprogesterone acetate (DEPO; 150 mg i.m. DEPO, Pharmacia & UpJohn) for prevention of endometrial cancer. The endometrial biopsies were timed so that they were performed between days 8 and 10 (proliferative phase) of the woman's menstrual cycle. All of the baseline (pre-treatment) endometrial biopsies used in this study were microscopically confirmed by a gynecologic pathologist to be in proliferative phase according to Noyes criteria. The group included women between the ages of 25 and 48 years (mean age=36.8 years), and mean BMI=28.4 kg/m2 (range 19.3–48.4 kg/m2) with no prior hysterectomy, no history of prior pelvic radiation, no chemotherapy for 2 years, and no use of oral contraceptives or hormones for 4 months prior to initiation of the study. Women also had to have no medical contraindication to use DEPO, including known or suspected pregnancy, undiagnosed vaginal bleeding, active thrombophlebitis or past history of thromboembolic disorders or cerebral vascular disease, gall bladder disease, history of diabetes, coronary artery disease, or a current tobacco smoker age >35.
The RNA used for the analysis of estrogen regulation of survivin expression in postmenopausal women was obtained from a randomly selected subset (n=10) of a large group of healthy postmenopausal women (n=210) participating in a clinical trial of estrogen replacement therapy as previously described (Deng et al. 2003, 2005). The group included women between the ages of 44 and 59 years (mean age=50.7 years), mean BMI=24.4 kg/m2 (range 19.3–28.6 kg/m2), mean serum E2=9.7 pg/ml (range 1.4–19.3 pg/ml), mean FSH=86.3 mIU/ml (range 51.7–148.2 mIU/ml), and mean prolactin=7.2 ng/ml (range 3.0–24.7 ng/ml). Endometrial biopsies were obtained at baseline and after 6 months of Premarin (0.625 mg/day conjugated equine estrogen, Wyeth-Ayerst) treatment. All endometrial biopsies were microscopically examined to confirm the absence of endometrial pathology (hyperplasia or carcinoma). Tissues were frozen in liquid nitrogen and stored at −80 °C. Frozen tissues were homogenized in TRI Reagent, and RNA was precipitated with isopropanol, applied to RNeasy spin columns (Qiagen), eluted, and treated with RNase-free DNase for 30 min at 37 °C, followed by heat inactivation at 75 °C and storage at −80 °C. RNA was isolated from FFPE tissues as previously described (McCampbell et al. 2006).
Quantitative real-time RT-PCR
All TaqMan quantitative real-time RT-PCR (QPCR) assays were designed with Primer Express software. The assays were developed, and all reactions were completed at the Quantitative Genomics Core Laboratory (UT-Houston Medical School, Houston, TX, USA). Forty nanograms of RNA from each sample were assayed in triplicate with a fourth reverse transcriptase negative control as previously described (Xie et al. 2007). The results were analyzed using SDS 1.9.1 software (Applied Biosystems, Carlsbad, CA, USA) with SuperROX (BioSearch, Novato, CA, USA) as a reference dye. Transcripts were quantified against a standard curve comprised of five serial log dilutions of known DNA quantity. The mean transcript levels for all assays were normalized to 18s rRNA transcript levels of the housekeeping gene. Data are presented as a median ratio of (transcript/18s rRNA). Survivin and 18s assay sequences have been reported as follows (Nabilsi et al. 2009): insulin-like growth factor binding protein 1 (IGFBP1; NM_000596): 620+GGGACGCCATCAGTACC, 681−CCATTTTTTGATGTTGGTGAC, 638+FAM-ATGATGGCTCGAAGGCTCTCCA-BHQ1; IGF1 (M27544): 187+TCCAACCCAATTATTTAAGTGCTGC, 278−ACAGCGCCAGGTAGAAGAGA, 227+FAM-AAGGTGAAGATGCACACCATGTCCTCCTC-BHQ1; Ki67 (NM_002417): 3323+AAGTTCACACGGACGTCAG, 3391−GATGCTCTTGCCATCTCC, 3347+FAM-ACCACGCACACGCACAGAGAG-BHQ1.
Statistical analysis
In all cases, we assumed that our data were not normally distributed, and statistical significance was calculated using either paired or unpaired non-parametric t-tests as appropriate. Wilcoxon signed-rank test was used to determine significance in matched (paired) samples for both patient treatment groups. A Mann–Whitney U test was used to determine significance from unpaired samples. A Spearman's rank correlation test was used to determine significant correlations between changes in transcript expression. All types of analysis were conducted in GraphPad Prism 5 statistical software (La Jolla, CA, USA), and a P value <0.05 was considered significant.
Results
Survivin mRNA is differentially expressed in the cycling human endometrium
The proliferative and secretory phases of the reproductive cycle in the human endometrium are dominated by E2 and P4 signaling respectively. Previous reports on survivin gene expression in the cycling human endometrium have been conflicting (Konno et al. 2000, Tarkowski et al. 2000, Lehner et al. 2002). To determine whether survivin transcript is physically expressed in the cycling human endometrium, QPCR analysis was conducted on RNA isolated from proliferative (n=7) and secretory (n=5) phase endometrial biopsies. Survivin gene expression levels were nearly 50-fold higher in proliferative endometrial biopsies compared to secretory biopsies (median proliferative=4.08, median secretory=0.08; P=0.01; Fig. 1). Since differences between these two phases are largely driven by steroid hormone signaling, we hypothesized that survivin transcript levels are increased in response to E2 and decreased in response to P4 in the human endometrium.
Survivin mRNA levels are decreased in response to P4 treatment in the human endometrium
To determine whether endometrial tissue from women treated for 3 months with DEPO responded physiologically to progestin treatment, post treatment biopsies were examined histologically. The presence of microscopic changes associated with non-proliferative endometrium (presence of endometrial stromal cells that are pre-decidualized, characterized by stromal cells with increased eosinophilic cytoplasm and acquisition of an epithelioid shape; presence of secretory-type or inactive endometrial glands) indicated a good response to progestins. Of the 21 post treatment endometrial biopsies, 19 exhibited features consistent with a good response to progestin treatment (Fig. 2a). Two biopsies showed a poor response indicated by the absence of these changes and/or the presence of mitotic figures in the endometrial glands and/or stroma (Fig. 2b).
To determine whether DEPO treatment induced expression of known P4-responsive genes, we measured the transcript levels of IGFBP1, a gene that is strongly expressed in the secretory endometrium and is known to be induced by P4 in the endometrium (Bell et al. 1991, Gao et al. 1994a,b). IGFBP1 is a P4-inducible secreted factor that modulates insulin-like growth factor (IGF) bioavailability and functions in concert with IGF proteins to regulate a variety of reproductive processes including menses, puberty, ovulation, decidualization, implantation, and fetal growth (Lane et al. 1994, Richards et al. 1995, Fowler et al. 2000). We observed negligible expression of IGFBP1 in all of the baseline endometrial samples followed by a 3000-fold increase in the median level of mRNA in post treatment endometrial samples indicating successful drug administration (Fig. 2c). Overall, survivin transcript expression decreased 4.6-fold following treatment compared to baseline levels (median pre=23.1, median post=4.1, n=21, P<0.0001; Fig. 2d). Fold change in survivin did not correlate with change in IGFBP1 (P=0.19). If we examine change per individual, the median change in survivin transcript levels following treatment for the good responders is −3.3-fold (n=19). With only two poor responders, there are insufficient data to draw conclusions regarding survivin in these women (mean fold change=+0.74, n=2).
Survivin levels are increased in response to estrogen treatment in the human endometrium
QPCR analysis of endometrial biopsies taken at baseline and after 6 months of treatment with estrogens showed a significant 4-fold up-regulation of survivin transcript (median pre=0.65, median post=3.23, n=10, P=0.013; Fig. 3a). Survivin expression was increased in seven of the ten patients with the remaining three patients showing no change or a small decrease in survivin expression (#2, #5, and #9; Fig. 3b). To confirm induction of estrogen-regulated genes in the endometrial tissue of the women after treatment, we measured the transcript levels of IGF1, a well known estrogen-inducible gene involved in estrogen-mediated endometrial proliferation (Rutanen 1998, Moyano & Rotwein 2004, McCampbell et al. 2006, Kashima et al. 2009), which we have previously shown to be induced by estrogen treatment in the endometrium of postmenopausal women (Westin et al. 2009). To confirm that the women responded to estrogen treatment, we measured transcript levels of nuclear antigen Ki67, a standard marker of proliferation (Hurskainen et al. 2000, Jaroslav et al. 2005, Strick et al. 2007). We determined that while all ten of the post treatment endometrial tissues exhibited estrogen induction of IGF1 (Fig. 3d), only nine of the ten patients responded with a proliferative phenotype indicated by increased Ki67 expression. Notably, patient # 9, who showed a decrease in Ki67 transcript, also showed a decrease in survivin transcript (Fig. 3f). The fold change in survivin induction significantly correlated with the fold change in Ki67 (P<0.0001, r2=0.98) but not with IGF1 fold change (P=0.76, r2=0.12), and IGF1 fold change also did not correlate with fold change in Ki67 (P=0.758, r2=0.11). The women's age (P=0.73), BMI (P=0.89), time since last menstrual period (P=0.94), baseline serum E2 (P=0.87), FSH (P=0.47), and prolactin (P=0.97) levels did not correlate with fold change in survivin expression.
Discussion
Survivin has been shown by our group and others to be overexpressed in several endometrial disease states including endometriosis, endometrial hyperplasia, and endometrial carcinomas. Information on the role of survivin in maintaining normal tissue homeostasis is lacking. The human endometrium is a classically hormone-responsive tissue; therefore, it is susceptible to endocrine-related pathologies as well as treatments. In this study, we show that survivin transcript expression is significantly increased in the E2-predominated proliferative phase, and is significantly decreased in the P4-predominated secretory phase of the normal endometrium. These data are in agreement with those published by Lehner et al. (2002) and suggest that survivin gene expression is hormonally regulated in the human endometrium.
It is enticing to speculate that survivin's anti-apoptotic and cell cycle regulatory functions may be involved in maintaining normal tissue homeostasis; however, it is important to note that our studies examined only survivin gene expression, not survivin protein. Konno et al. (2000) published work indicating that survivin transcript and protein were increased in the secretory phase rather than the proliferative phase of cycling endometrium. While our transcript data are contrary to the Konno et al. results, there are, to our knowledge, no published works that disagree with the Konno et al. protein results. It has been shown that survivin protein is increased by estrogens and decreased by progestins in endometrial cancer-derived cells in vitro; however, further studies will be required to determine whether survivin protein expression is similarly hormonally regulated in disease-free human endometrial tissue. We postulated that the survivin transcript may be functional in the endometrium as it is a natural antisense transcript to the effector cell protease receptor 1 (EPR1). EPR1 is the receptor for factor Xa and is involved in vascular inflammation and blood coagulation. Inverse expression of survivin and EPR1 has been observed in several systems and hematologic malignancies. However, QPCR analysis conducted in our laboratory with an EPR1-specific probe could not detect EPR1 transcript neither in normal proliferative human endometrial tissue nor in endometrial tumors (data not shown). We did not examine secretory tissue for EPR1 gene expression.
We are the first to report that survivin gene expression is changed in response to administration of E2 and P4 in the disease-free human endometrium. A 6-month treatment with E2 significantly increased the expression of a well-known E2-regulated gene, IGF1. In addition, survivin gene expression increased and was associated with increased proliferation indices as measured by Ki67 expression. These data suggest that while the IGF1 protein is functionally involved in mediating the proliferative response towards estradiol, the survivin transcript may be more useful than the IGF1 transcript as an indicator of hormone treatment efficacy, specifically as a marker of proliferation in response to E2. A larger study including more women will be necessary to validate this finding.
A 3-month treatment with DEPO resulted in a significant increase in a well-known P4-regulated gene, IGFBP1, and resulted in a significant decrease in the gene expression of survivin. A report published recently indicated that increased survivin protein levels predicted resistance to progestin therapy in patients with endometrial hyperplasia (Chen et al. 2009). In our dataset, upon histological examination, two women were determined to be non-responders to progestin treatment, and both patients also exhibited an aberrant survivin response (no change or increased gene expression) as measured by QPCR. A larger study including more non-responders will be necessary to assess the significance of this finding.
Herein, we report preliminary results suggesting that survivin transcript as a biomarker could be helpful to clinicians who prescribe hormone replacement therapies to postmenopausal women or to those who use hormone therapies as chemopreventive agents in high-risk populations. Larger studies will be needed to validate the utility of survivin transcript as a biomarker for hormone treatment efficacy and/or resistance in these populations.
Declaration of interest
D S Loose's work has been funded by the NIH and the John S Dunn foundation. He is a consultant for Wyeth Pharmaceuticals for which he receives compensation. The other authors have no conflicts of interest.
Funding
D S L, A S M and R R B are supported by the NIH SPORE in Endometrial Cancer 1P50CA098258-01; K H L and L-M C are supported by the NCI NO1-CN-05127; H T L is supported by NIH 1U01CA86389, and N H N is supported by the Rosalie B Hite Graduate Student Fellowship.
Acknowledgements
We thank Dr James Pickar (Wyeth Research, Philadelphia, Pennsylvania) for generously providing endometrial RNA samples from Premarin-treated women. We thank Dr Greg Shipley (Quantitative Genomics Core Laboratory, University of Texas Medical School, Houston, Texas) for designing the QPCR assays reported. We thank Dr Caimiao Wei for generously providing statistical advice and support.
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