Effect of ARID1A/BAF250a expression on carcinogenesis and clinicopathological factors in pure-type clear cell adenocarcinoma of the ovary
- Authors:
- Published online on: August 2, 2016 https://doi.org/10.3892/mco.2016.973
- Pages: 395-401
Abstract
Introduction
Ovarian clear-cell adenocarcinoma (CCA) has been recognized as a distinct entity among epithelial ovarian carcinomas (EOCs) with respect to its chemoresistant nature and frequent concurrence of endometriosis and clear-cell adenofibroma (CCAF). In Western populations, CCAs account for ~5–13% of all EOCs, whereas in Japan, its prevalence rises to 15–25% of all EOCs (1–3). Approximately two thirds of CCAs were diagnosed at early-stage disease; however, CCA has a relatively resistant phenotype to platinum-based chemotherapy, resulting in extremely poor prognosis, irrespective of surgical stages (4). Therefore, it is essential to elucidate a novel therapeutic target for CCA and to develop novel therapeutic strategies.
High-grade serous ovarian cancer, which is a major subtype of all histological subtypes, is characterized by TP53 mutations and frequent mutations or defects in BRCA1/2 pathway. By contrast, CCA appears to harbor a different molecular profile, including activating mutations in PIK3CA, and loss of PTEN and ARID1A (5–9). ARID1A mutation, in particular, is frequently observed in endometriosis-associated ovarian clear-cell and endometrioid adenocarcinoma, and it has been suggested that the mutation is as an early molecular event in the development of endometriosis-related CCA (8,9,10). These distinct molecular features of CCA serve emphasis on the requirement to develop subtype-specific therapeutic approachs in the management of EOC.
Additionally, previous reports have suggested that CCAs are classified into two distinct molecular subtypes and that these subtypes have different clinical outcome (11). It was demonstrated that endometriosis-related CCA and CCAF-related CCA had different carcinogenic pathways (12,13). Certain previous reports suggested that ARID1A somatic mutation and subsequent BAF250a protein loss in CCA was correlated with response to chemotherapy and poor prognosis (14); however, other previous reports revealed no significance (10,15–17). To date, the impact of BAF250a protein expression in response to primary chemotherapy and the prognoses of CCAs has remains to be determined.
The aim of the present study was to clarify whether loss of BAF250a expression correlated with early tumorigenesis of CCA, and to evaluate the significance of BAF250a-deficient expression on clinicopathological variables in CCAs in a large series of patients treated at a single institution.
Materials and methods
Patients
A total of 97 cases of CCA treated between 1984 and 2007 at the National Defense Medical College Hospital, (Tokorozawa, Japan) were enrolled in the present study. Of the 97 CCAs, a consecutive series of 38 CCAs synchronous with endometriosis (EM-related CCAs) and 21 CCAs adjacent to CCAF component (CCAF-related CCAs) were identified, according to the histopathological criteria described previously (18). Of those, 31 non-atypical endometrioses, 38 atypical endometrioses, 20 benign CCAFs and 21 borderline CCAFs were identified. A total of 18 cases with solitary endometriosis that had no CCA were used as controls. All patients provided written informed consent for the present study.
Immunohistochemical (IHC) staining
Two core specimens, 1.5 mm in diameter, for each case were obtained from cancer tissue blocks and transferred to recipient blocks using a Tissue Microarrayer (Beecher Instrument, Silver Spring, MD, USA). All specimens were cut into 4-µm-thick slices to make tissue sections for IHC staining. The tissue sections were deparaffinized and boiled in an autoclave at 121°C for 15 min in 0.01 mol/l citrate buffer (pH 6.0) and were then allowed to cool at room temperature. Endogenous peroxidase activity was blocked using methanol added to 0.3% hydrogen peroxidase. The slides were incubated at 4°C overnight with mouse monoclonal primary antibody against BAF250a (cat. no. sc-32761; dilution, 1:100; Santa Cruz Biotechnology, Inc., Santa Cruz, CA, USA). Following incubation, the samples were reacted with dextran polymer reagent combined with secondary antibodies and peroxidase (cat. no. Z0420; 1:200; Dako A/S, Glostrup, Denmark) for 1 h at room temperature. Specific antigen-antibody reactions were visualized with 0.2% diaminobenzidine tetrahydrochrolide and hydrogen peroxidase, and counterstaining was performed using Mayer's hematoxylin. Non-neoplastic cells, including fibroblasts and lymphocytes, served as positive internal controls. As negative controls, tissue sections without the primary antibody were used.
For BAF250a detection, the presence of nuclear immunoreaction was taken into account for assignment of immuno-positivity. The lesions were considered to be positive for BAF250a if 50% or more of tumor cells in the area of interest showed equal to or more strong immunoreactive intensity compared with the positive controls (BAF250a-retained cases). If no detectable nuclear staining of tumor cells or <50% of tumor cells in the area of interest showed less immunoreactive intensity compared with the positive controls, they were defined as having a loss of BAF250a expression (BAF250a-deficient cases). The lesions were assessed independently by two observers (Masafumi Kato and Morikazu Miyamoto) in a blinded manner and any discrepancies between the two observers were resolved by conferring over a multi-viewer microscope.
Patient characteristics
Patient background, including age, concurrence of endometriosis, co-existence of CCAF, international federation of gynecology and obstetrics (FIGO) stage, residual tumor in primary surgery and chemotherapy regimen were compared, according to the BAF250a expression status. In addition, frequencies of loss of BAF250a expression in EM-related CCAs and CCAF-related CCAs were examined, as well as precursors (non-atypical endometrioses, atypical endometrioses, benign CCAFs and borderline CCAFs). Tumor response to adjuvant chemotherapy in evaluable cases, progression-free survival and overall survival were analyzed according to BAF250a expression status. Multivariate analyses for overall survival and progression-free survival were performed.
Statistical analysis
Statistical analyses were performed using Stat Mate IV software (ATMS, Tokyo, Japan) and Statview version 5 software (SAS Institute Japan, Ltd., Tokyo, Japan). Student's t-test and χ2 test were used to compare patient characteristics of two groups. For survival analyses, Kaplan-Meier curves and the log rank test were used. Prognostic significance was analyzed using the Cox proportional hazard model using variables as follows: Age (continuous variable), concurrence of endometriosis (yes vs. no), FIGO stage (I/II vs. III/IV), residual tumor (≤1 cm vs. >1 cm) and BAF250a status (BAF250a-deficient vs. BAF250a-retained). P<0.05 was considered to indicate a statistically significant difference.
Results
Association between patient characteristics and expression of BAF250a
The characteristics of the patients were assessed according to the BAF250a expression status, and this is shown in Table I. BAF250a-deficient expression was observed in 30% (29/97) of all cases. No differences were observed in age, FIGO stage, residual tumor in primary surgery and chemotherapy regimen between the two groups. Concurrence of endometriosis was observed more frequently in BAF250a-deficient cases compared with in BAF250a-retained cases (P<0.05). By contrast, co-existence of CCAF was significantly more frequent in BAF250a-retained cases compared with that in BAF250a-deficient cases (P=0.04).
Frequency of BAF250a expression
The frequencies of BAF250a-deficient expression were 19% (6/31) in non-atypical endometriosis, 26% (10/38) in atypical endometriosis, 5% (1/20) in benign CCAF, 5% (1/21) in borderline CCAF, 39% (15/38) in EM-related CCA and 10% (2/21) in CCAF-related CCA (Fig. 1). In solitary endometriosis, loss of BAF250a expression was detected in 6% (1/18) of cases. In comparison with the frequency of BAF250a-deficient expression between EM-related CCAs and CCAF-related CCAs, a significant difference was observed between the two groups (P=0.02).
Response rate of chemotherapy
The response rate of chemotherapy in evaluable cases is shown in Table II. No significant difference was observed in response rate of primary chemotherapy between the two groups. A total of 50% (13/26) in BAF250a-retained cases and 30% (3/10) in BAF250a-deficient cases (P=0.48) was observed.
 | Table II.Tumor response of primary chemotherapy in evaluable cases with ovarian clear cell adenocarcinoma. |
Overall and progression-free survival of the patients
Kaplan-Meier survival curves of all patients are shown in Fig. 2. BAF250a-deficient expression status was not significantly correlated with progression-free and overall survival of CCA in all enrolled cases. The 5-year progression-free survival rates were 68% in BAF250a-retained cases and 59% in BAF250a-deficient cases (P=0.24). Additionally, the 5-year overall survival rates were 67% in retained expression cases and 49% in deficient cases (P=0.43).
Kaplan-Meier survival curves of stage I/II patients (Fig. 3A and B) and stage III/IV patients (Fig. 3C and D), according to BAF250a expression, were also shown. Additionally, no significant differences were observed in the progression-free and overall survival in patients with stage I/II cases. The 5-year progression-free survival was 86% in BAF250a-retained cases and 91% in BAF250a-deficient cases (P=0.82). The 5-year overall survival rate was 85% in BAF250a-retained cases and 78% in BAF250a-deficient cases (P=0.38). In cases with stage III/IV disease, no differences were observed between the two groups. The 5-year progression-free survival was 23% in BAF250a-retained cases and 13% in BAF250a-deficient cases (P=0.23). The 5-year overall survival rate was 25% in BAF250a-retained cases and 16% in BAF250a-deficient cases (P=0.21).
BAF250a expression status is not an independent prognostic factor
In the multivariate analysis for progression-free survival, BAF250a expression status was not identified as an independent prognostic factor (P=0.47; Table III). Residual tumor diameter was identified as an independent factor for progression-free survival. In the multivariate analysis for overall survival, age (P=0.01), FIGO stage (P<0.01) and residual tumor diameter (P=0.02) were prognostic factors; however, the BAF250a expression status was not identified as an independent prognostic factor (P=0.56) in the present cases.
Discussion
Frequencies of BAF250a-deficient expression in the present study were 6% in solitary endometriosis, 19% in non-atypical endometriosis, 26% in atypical endometriosis, 5% in benign CCAF, 5% in borderline CCAF and 30% in CCA. Previous reports have documented that frequencies of BAF250a-deficient expression in solitary endometriosis, atypical endometriosis and CCA were 0–15, 38.5 and 15–66%, respectively (10,14,19–21). When compared with solitary endometriosis and non-atypical endometriosis synchronous with CCA, BAF250a-deficient expression was more frequent in non-atypical endometriosis (6 vs. 19%), suggesting this alteration was an early molecular alteration in the development of CCA. In addition, BAF250a-deficient expression in EM-related CCA and its precursor were more frequent compared with that in CCAF-related CCA and its precursor. These findings suggested that EM-related CCA may have different carcinogenic pathway from CCAF-related CCA.
Systematic review of BAF250a in response to the primary chemotherapy and prognosis in CCA was shown in Table IV. It remains controversial whether BAF250a status is correlated with the chemoresistance of CCA. A report demonstrated that loss of BAF250a expression was associated with chemoresistance of CCA (14); however, the others did not show any significant differences (10,15–17). This discrepancy may be simply explained by a sample size or different patient characteristics. In the present study, BAF250a expression status was not significantly correlated with response rate for chemotherapy of CCA in accordance with the results of several reports (10,15,16).
| Table IV.Review of the impact of BAF250a on the response to primary chemotherapy and prognoses in ovarian clear cell adenocarcinoma. |
In the present study, BAF250a-deficient cases exhibited a relatively lower chemotherapy response and a worse prognosis; however, BAF250a expression status was not significantly associated with response rate or prognoses in CCA. Additionally, multivariate analyses revealed that BAF250a status was not an independent prognostic factor for progression-free survival and overall survival. More important factors, including age, FIGO stage and residual tumor diameter, were identified as prognostic factors for overall survival in CCAs.
In conclusion, BAF250a expression status was not identified as an independent prognostic factor for progression-free survival or overall survival in patients with CCA. However, BAF250a-deficient expression was closely correlated with early tumorigenesis of endometriosis-related CCA. BAF250a expression was closely associated with an early neoplastic process of endometriosis and it may be a potential biomarker for detecting early malignant transformation of endometriosis. Additionally, it is necessary to investigate the method to detect the alteration of BAF250a expression in the follow-up of the patients with endometriosis. Further biomarker analyses, including BAF250a expression, are required to improve the prognoses of CCAs.
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