Abstract
Background: No direct comparison has been made of the relationship between the expression of Wilms' tumor gene WT1 within tumor cells and angiogenesis in vivo. Materials and Methods: A series of 70 endometrial cancer patients who had undergone a curative resection was studied by immunohistochemistry to determine the correlation between WT1 expression, angiogenesis (proliferation of endothelial cell adhesion molecule-1, PECAM-1/CD31) and angiogenic growth factor (vascular endothelial growth factor, VEGF). Results: A strong association was found between WT1 expression score and mean vascular density (p<0.001, n=70, ϱ=0.568). Immunohistochemistry of serial sections revealed that WT1 and VEGF were co-expressed in the same area of endometrial cancer tissue. Conclusion: Tumor-produced WT1, which may regulate the expression of VEGF, is found to be associated with induction of angiogenesis in endometrial cancer.
Endometrial cancer is the most common gynecological malignancy in the United States. In Japan, it is the second most common gynecological cancer, but its frequency has dramatically increased in the last decade. Although there are well-established surgical and chemotherapeutic treatments, the need for molecular-target therapy has increased, especially for recurrent disease that has acquired radio- or chemoresistance. A better understanding of the molecular pathways of endometrial carcinogenesis is thus.
The Wilms' tumor gene WT1 has been isolated and identified as a gene responsible for a childhood renal neoplasm, Wilms' tumor (1-3). This gene encodes a zinc finger transcription factor and plays important roles in cell growth and differentiation (4, 5). Although WT1 was first categorized as a tumor-suppressing gene, it was recently demonstrated that the wild-type WT1 possessed an oncogenic rather than tumor-suppressing function in many kinds of malignancies (6). WT1 is highly expressed in hematological malignancies and solid tumors, including endometrial cancer (7, 8).
In addition, recent studies have reported correlations between WT1 and neovascularization in histogenetics, normal genitourinary development, cardiac malformation and tumor angiogenesis (9-11). Angiogenesis is an important step for tumor growth in the transition from a small cluster of malignant cells to a visible macroscopic tumor capable of spreading to other organs via the vasculature (12, 13). The seminal in vitro study by Cash et al. revealed that the DNA binding domain of WT1 within tumor cells plays an essential role in the transcriptional regulation of vascular epithelial growth factor (VEGF), which is an important factor in inducing tumor angiogenesis (14). Although the potential for angiogenesis associated with tumor-produced WT1 has been suggested, few reports are available on the effect of WT1 as an angiogenic inducer in the intratumoral microenvironment of human solid tumors.
To date, no direct comparison has been made of the relationship of WT1 expression within tumor cells and angiogenesis in terms of the mechanism of tumor progression and metastasis. To address these questions, our work aimed to investigate the role of WT1 within tumor cells in angiogenesis by assessing proliferation of endothelial cell adhesion molecule-1 (PECAM-1, CD31) in surgically-removed endometrial carcinomas.
Materials and Methods
Patients. This study included 70 primary endometrial carcinoma patients consecutively admitted, treated and followed-up by the Department of Obstetrics and Gynecology, Kanazawa University Hospital from January 1995 to December 2002. None of the patients had received any pre-surgical treatment and all had undergone a total abdominal or radical hysterectomy plus bilateral salphingo-oophorectomy. At the time of laparotomy, peritoneal fluid samples were obtained for cytological testing. Systemic pelvic lymphadenectomy was performed in 51 (73%) patients. Paraaortic lymph node sampling was performed in two patients because of visible or palpable enlarged lymph nodes. All patients were classified by the FIGO surgical staging system (1988). No patient had remaining macroscopic tumors or known distant metastasis immediately following surgery. High-risk patients (e.g. those with deep myometrial invasion, cervical involvement, special histology, or peritoneal cytology) underwent external radiotherapy and/or six cycles of chemotherapy (paclitaxel: 180 mg/m2, carboplatin: according to Chatelut's formula [area under the curve, AUC=5 mg min/ml]) as postoperative adjuvant therapy. All treatments and clinical research were conducted with written informed consent.
Immunohistochemistry. WT1, CD31 and VEGF were evaluated in serial sections stained with appropriate antibodies. Table I shows the primary antibodies, their sources, dilutions, incubation times and epitope retrieval. Formalin-fixed, paraffin-embedded slides (5 μm-thick) were deparaffinized and rehydrated in graded alcohols. Endogenous peroxidase activity was quenched by dipping in 3% hydrogen peroxide for 30 minutes. Staining was performed by avidin-biotin complex (ABC) technique, using SAB-PO kit (Nichirei Co.,Tokyo, Japan). Color development was carried out with the peroxidase substrate 3-amino-9-ethylcarbazole (AEC) against WT1, CD31 and VEGF. All slides were counterstained with Mayer's hematoxylin. Sections without primary antibodies, as well as those with non-immunized mouse serum, served as negative controls.
Evaluation of staining. For evaluation of WT1 expression, staining intensity was scored as 0 (negative), 1 (weak), 2 (medium), and 3 (strong). The extent of staining was scored as 0 (0%), 1 (1-25%), 2 (26-50%), 3 (51-75%) and 4 (76-100%) according to the percentage of positive staining area in relation to the whole carcinoma area. The sum of the intensity and extent score was used as the final staining score (0-7) for WT1. Tumors having a final staining score of ≥5 were considered to exhibit strong expression.
In assessment of tumor microvessels, the densest vascular areas were identified by scanning tumor sections at low magnification (×40). After identification of the densest vascularization, a vessel count was performed at ×400 magnification. The average vessel number in 5 fields was expressed as the microvessel density (MVD).
Evaluation and counting were conducted by two observers (S.D. and S.O.) who were unaware of any details regarding the patients' background.
Statistical analysis. Chi-square test for 2×2 tables was used to compare the categorical data. The difference in continuous variables between groups was compared using Mann-Whitney U-test. Relations between continuous variables were investigated by means of Spearman's rank correlation coefficient test. A p-value of <0.05 was considered to indicate statistical significance. All statistical analyses were performed using the statistical package StatView version 5.0 for Macintosh (Abacus Concepts, Berkeley, CA, USA).
Results
Characteristics of patients. The patients' average age at time of surgery was 57.3 years (range, 26-78, years). Patients with endometrial cancer included: 22 of premenopausal status, 4 of perimenopausal status and 44 of postmenopausal status. The patients' mean preoperative body mass index (BMI) was 24.0 (range, 16.9-32.9).
WT1 expression. WT1 expression was positive exclusively in cancer cells in 64 cases (91%). The expression of WT1 was strong (final staining score of 5-7) in 31 patients (44%) and weak (final staining score of 0-4) in 39 patients (56%). Typical WT1 expression in endometrial cancer cells is shown in Figure 1A. The majority of positive cases showed diffuse or granular staining in the cytoplasm. Staining of WT1 was heterogeneous in advanced tumors and WT1 was frequently located at the invasion front of the tumor. The association between WT1 expression and clinicopathological variables is shown in Table II.
WT1 overexpression was associated with advanced FIGO stage (p=0.0266), myometrial invasion (p=0.0477) and high-grade histological differentiation (p=0.0049), indicating up-regulation of WT1 expression with tumor progression in this study.
CD31 expression. CD31-positive endothelial cells lining microvessels within tumors were detected in 58 out of 70 patients (Figure 2). MVD varied from 0 to 66.8, with a median of 13.6 and mean of 20.0 (standard deviation, 20.1). MVD was significantly higher in tumors of advanced FIGO stage (p=0.0191), with myometrial invasion (p=0.0120) and of high-grade histological differentiation (p=0.0019) (Table III). The other clinicopathological characteristics were not associated with MVD.
Association between WT1 expression and CD31. CD31 in the strong-expression WT1 group was significantly higher than in the weak-expression WT1 group, by Mann-Whitney U-test (p<0.001) (data not shown). Moreover, considering WT1 expression scores as continuous variables, a strong association was found between WT1 expression and CD31 expression (p<0.001, n=70, ϱ=0.568) using Spearman's rank-correlation coefficient (Figure 3).
VEGF expression in WT1-positive cancer cells. Typical VEGF expression within tumor cells is shown in Figure 1B. Immunohistochemistry of serial sections revealed that VEGF and WT1 were co-expressed in the same area of endometrial cancer tissue.
Discussion
Recent studies showed that tumor-produced WT1 influenced tumor progression in various types of cancer. Yamamoto et al. found that WT1 protein might be an accelerator of the progression of ovarian serous adenocarcinoma (15). Sera et al. concluded that overexpressed WT1 was associated with tumor growth, and resulted in a worsening prognosis of hepatocellular carcinoma (16). Hylander et al. demonstrated that patients with WT1-positive tumors had a higher grade (p=0.006) and advanced stage (p=0.002) of epithelial ovarian cancer (17). Miyoshi et al. found that tumors >2 cm also showed a trend toward an increase (p=0.09) in WT1 mRNA levels as compared with tumors <2 cm in breast cancer (18). In the present study, we found that WT1 overexpression was associated with advanced FIGO stage, myometrial invasion and high-grade histological differentiation, indicating up-regulation of WT1 expression with tumor progression. Our results are congruent with previous reports of the other types of cancer.
Tumor development and progression are inherently dependent on the process of angiogenesis. Ozalp et al. found that microvessel density (MVD) as assessed by factor VIII antigen was correlated with high surgical stage (p<0.001), cervical involvement (p=0.01), adnexal involvement (p=0.04), lymphovascular space involvement (p=0.02), pelvic and paraaortic lymph node metastasis (p<0.001), and positive peritoneal cytology (p<0.001) in endometrial carcinoma (19). Salvesen et al. found that MVD as assessed by CD105/endoglin antigen was significantly correlated with MVD as assessed by factor VIII antigen (linear regression 0.32, p=0.001), and that CD105/endoglin-MVD is significantly associated with FIGO stage (p=0.03), tumor cell proliferation estimated by the expression of Ki-67 (p=0.007) in endometrial cancer (20). Ueda et al. demonstrated that intratumoral MVD (immunohistochemically using anti-CD34 antibody) was well correlated with histological type (p=0.0415), depth of myometrial invasion (p=0.0176), endometrial invasion (p=0.0354) and pelvic lymph node metastasis (p=0.0354) in uterine cervical cancer (21). Kamat et al. showed that high expression of MVD as assessed by CD31 expression was associated with high-stage and grade 3 tumors (p=0.03 and 0.04, respectively) in endometrial cancer (22). In the present study, we found that MVD as assessed by CD31 expression was associated with advanced FIGO stage, myometrial invasion and high-grade histological differentiation. Furthermore, a strong association was found between WT1 staining score and MVD using Spearman's rank correlation coefficient. These results suggest that WT1 may regulate tumor progression and angiogenesis in endometrial cancer.
As a key mediator of angiogenesis, VEGF is tightly regulated at both the transcriptional and post-transcriptional levels. VEGF regulation is complex, since it is up-regulated by hypoxia, growth factors, steroid hormones and transcription factors including WT1 (23). Cash et al. showed that WT1 had both transcriptional and post-transcriptional effects on VEGF mRNA levels in prostate cell lines (14). Hanson et al. found that methyltrienolamine (androgen analog, R1881) increased the transcriptional activation of the VEGF promoter by WT1 in LNCaP prostate cancer cells (24). Overall, these reports suggest that WT1 plays an essential role in the transcriptional regulation of VEGF in cancer cells. On the other hand, WT1 is essential for kidney development (25-27) and is co-expressed with VEGF in normal kidney cells and in some Wilms' tumors (27-30). Therefore, for both developmental and cancer studies, it is important to elucidate the mechanisms whereby WT1 regulates VEGF and thereby, angiogenesis. In the present study, we also found that WT1 and VEGF were co-expressed in the same area of endometrial cancer tissue. This result suggests that WT1 may regulate expression of VEGF.
These results imply that WT1 plays an important role in endometrial cancer-associated angiogenesis, probably via induction of angiogenesis by VEGF. To the best of our knowledge, this may be the first report to demonstrate the positive role of WT1 in endometrial cancer-associated angiogenesis and may prove of great benefit in finding a rational approach to endometrial cancer therapy.
Recently, anti-angiogenic therapy has begun to show promise as an effective treatment strategy for many types of solid tumor. WT1 is also a target for cancer immunotherapy, and this study suggests that a WT1 peptide vaccine therapy might be effective not only as cancer immunotherapy but also as anti-angiogenesis therapy.
In conclusion, tumor-produced WT1, which may regulate the expression of VEGF, is associated with the induction of angiogenesis in endometrial cancer.
Acknowledgements
We are grateful to the staff of the Pathology Section, Kanazawa University Hospital, for collecting the samples and providing paraffin-embedded tissues. Thanks are due also to Eric Stewart, Kanazawa University, for editing the English content.
- Received June 8, 2010.
- Revision received July 3, 2010.
- Accepted July 8, 2010.
- Copyright© 2010 International Institute of Anticancer Research (Dr. John G. Delinassios), All rights reserved