Nuclear G protein-coupled oestrogen receptor (GPR30) predicts poor survival in patients with ovarian cancer

Introduction

Ovarian epithelial carcinoma, which accounts for most ovarian cancer, is the commonest of all gynaecological malignancies.^1–3 Almost all patients are diagnosed at an advanced stage as there are few distinctive symptoms and no reliable screening tests: ⁴ this contributes to the high mortality rate of the disease. To date, only a few tumour biomarkers have been established for high grade ovarian cancer. ⁵ Serum cancer antigen (CA) 125, identified in the 1980s, is known to be an important marker.^5,6 However, it is more useful for guiding treatment rather than predicting the prognosis in patients with ovarian cancer. ⁷ The G protein-coupled oestrogen receptor (GPR30) which was identified in 2005, ⁷ has been found in numerous organs^8–11 and in primary carcinomas of these organs. ¹² Although the receptor’s promotion by oestrogen has been extensively studied^10,11, the potential signalling pathway of GPR30 is still unclear.

The purpose of this study was to determine the intracellular localization of GPR30 in tissue samples from women with ovarian cancer and elucidate its impact in the disease. To this end, nuclear and cytoplasmic GPR30 expressions were correlated with clinicopathological characteristics and survival outcomes in patients with ovarian cancer.

Methods

Tissue microarrays (TMAs) were created from patients with epithelial ovarian cancer who underwent surgery in the First Affiliated Hospital, Sun Yat-sen University, China between January 2005 and December 2010. Each sample was identified by the admission number of patient. The samples were fixed with formalin and embedded in paraffin. Clinicopathological data were collected before and after surgery and recorded in the patients’ medical records as were five year follow-up data. Data were extracted and recorded by two physicians (C.Z. and G.N.)

All TMAs were subjected to immunohistochemistry. Nuclear GPR30 was evaluated using rabbit polyclonal antibody SP4674P (Acris Antibodies GmbH, Germany) while cytoplasmic GPR30 was evaluated using antibody LS-A4290 (LifeSpan BioSciences, Germany). Positive controls were made using multiorganic arrays including breast tissue known to express GPR30 and negative controls consisted of GPR30-expressing ovarian cancer tissue incubated with a matched isotype antibody.

In brief, all specimens were de-paraffinized in ethanol and subsequently rehydrated in a descending graded series of alcohol concentrations. ¹³ Epitope retrieval was accomplished by pressure cooking the samples in a 0.01 M citric acid buffer (pH, 6.0). Endogenous immunoglobulins in the tissue were blocked by incubating in fresh 3% H₂O₂ for 20 minutes at room temperature. Following multiple washes, all TMAs were incubated with the GPR30-specific antibodies, LS-A4290 (3.3 g/mL) or SP4674P (4 g/mL) for 60 mins at room temperature. After scanning with the Nano Zoomer digital slide scanner (2.0-RS C10730-13, Hamamatsum, Japan), the immunohistochemical staining analysis was interpreted by two independent pathologists (H.S. and H.C.) who were blinded to the clinical data. Positive GPR30 expression was defined as a staining intensity of grade 2+ or more from a scale that ranged from 0 (negative), 1+ (weak), 2+ (moderate) and 3+ (strong).

Immunofluorescence was used to determine the intracellular localization of GPR30 in the ovarian cancer cell line, SKOV-3 (American Type Culture Collection, Rockville, MD). To block non-specific binding, viable SKOV-3 cells were pre-treated with phosphate buffered saline, 1% bovine serum albumin or 0.1% saponin. The GPR30-specific antibodies, LS-A4290 (10 g/mL), or SP4674P (5 g/mL), were applied and incubated with the cells for 30 min, while isotype control was incubated and diluted to the same final antibody protein concentration. ¹⁴

After blocking and washing, secondary antibodies, Alexa-488 (2 µg/ml) and 4', 6-diamidino-2-phenylindole (DAPI, 1 µg/ml), were applied. All cells were examined using a confocal laser scanning microscope (CLSM). Any blue fluorescence from the DAPI labelling suggested nuclear binding while green fluorescence from Alexa-488 labelling identified the GPR30 receptor itself. ¹⁵

Results

Tissue samples were available from 110 patients and their clinicopathological characteristics are listed in Table 1.

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Table 1.

Clinical characteristics of the ovarian cancer patients.

Characteristic
Patients, n	110
Age, years
<60	41 (37.3)
≥60	69 (62.7)
FIGO, grade
I/II	36 (32.7)
III/IV	74 (67.3)
Lymph node status
Negative	59 (53.6)
Positive	51 (46.4)
Nuclear grading
Low-grade	41 (37.3)
High-grade	69 (62.8)
Histology
Serous	76 (69.1)
Mucinous	10 (9.1)
Endometrioid	6 (5.5)
Clear cell	2 (1.8)
Others	16 (14.5)
Ascites (ml)
<500	33 (30.0)
≥500	36 (32.7)
None	38 (34.5)
No data	3 (2.7)
Recurrence
Yes	57 (51.8)
No	53 (48.2)

GPR30 expression

Nuclear GPR30 expression was observed in 69/110 (62.7%) of patients with ovarian cancer, while cytoplasmic GPR30 was observed in 71/110 (64.5%) of patients. (Table 2). In total, 51/76 (67.1%) of patients with serous adenocarcinoma and 4/10 (40%) of patients with mucinous adenocarcinoma expressed nuclear GPR30. Cytoplasmic GPR30 was detected in 50/76 (65.8%) patients with serous adenocarcinoma and in 4/10 (40.0%) patients with mucinous adenocarcinoma. There were no statistically significant differences in the types of adenocarcinoma (Table 2).

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Table 2.

Correlation between intracellular GPR30 expression and clinicopathological characteristics in patients with ovarian cancer (n = 110).

Variable	Nuclear PR30 positive 1	Nuclear GPR30 negative 2	Statistical significance	Cytoplasmic GPR30 positive 3	Cytoplasmic GPR30 negative 4	Statistical significance
FIGO
I/II	19	17	ns	17	19	P = 0.032
III/IV	50	24		54	20
Lymph node status
Negative	33	26	ns	31	28	ns
Positive	36	15		36	15
Nuclear grading
Low-grade	25	16	ns	22	19	ns
High-grade	44	25		45	24
Histology
Serous	51	25	ns	50	26	ns
Mucinous	4	6		4	6
Others	14	10		13	11
Ascites (ml)
<500	23	10	ns	22	11	ns
≥500	23	13		24	12
None	21	17		19	20
No data	2	1		3	0
Recurrence
Yes	42	15	P = 0.018	38	19	ns
No	27	26		29	24

Data presented as n

1

GPR30 staining positive (≥2+) with antibody SP4674P against GPR30 located in nucleus

2

GPR30 staining negative (<2+) with antibody SP4674P against GPR30 located in nucleus

3

GPR30 staining positive (≥2+) with antibody LS-A4290 against GPR30 located in cytoplasm

4

GPR30 staining negative (<2+) with antibody LS-A4290 against GPR30 located in cytoplasm

FIGO, International Federation of Gynaecology and Obstetrics staging system (I/II = low/moderate grade tumours, III/IV = high grade/undifferentiated)

Nuclear GPR30 was detected in 42/67 (62.7%) of patients with tumour recurrence and in 27/53 (50.9%) of patients without recurrence (P = 0.018). There were no other significant correlations between nuclear GPR30 expression and other clinicopathologic characteristics (Table 2).

Cytoplasmic GPR30 was observed more frequently in advanced ovarian cancer with 54/74 (73.0%) patients having International Federation of Gynaecology and Obstetrics (FIGO) grades III/IV and 17/36 (47.2%) of patients having grades I/II (P = 0.032). There were no other significant correlations between cytoplasmic GPR30 expression and other clinicopathologic features (Table 2).

Prognostic impact of GPR30 expression

In patients with ovarian cancer, nuclear GPR30 expression predicted both a poorer overall survival (Figure 2a; P = 0.046) and 5-year progression free survival (Figure 2b: P = 0.046). However, cytoplasmic GPR30 expression was only significantly associated with poorer overall survival (Figure 2c P = 0.049) and not 5-year progression free survival (Figure 2d). OPEN IN VIEWER

Figure 2.

Survival of ovarian-cancer patients by GPR30 status. (a) Overall survival by nuclear GPR30 status. (b) 5-year Progression-free survival by nuclear GPR30 status. (c) Overall survival by cytoplasmic GPR30 status. (d) 5-year Progression-free survival by cytoplasmicGPR30 status.

Uni- and multivariate analysis were performed, with adjustments made for age, FIGO stage and nuclear grading (Table 3). Nuclear GPR30 was an independently poor prognostic factor for overall survival in ovarian cancer patients (P = 0.035). Cytoplasmic GPR30 expression was not predictive of overall survival or 5-year progression free survival. Patient age predicted overall survival (P = 0.001) whereas FIGO stages were unfavourable prognostic factors for both overall survival (P = 0.01) and 5-year progression free survival (P = 0.001).

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Table 3.

Uni- and Multi-variate analysis of overall survival and 5-year progression free survival in patients with ovarian cancer (n = 110).

	Overall Survival			5-year Progression free survival
	Crude HR (95% CI)	Adjusted HR (95% CI)	Statistical significance	Crude HR (95% CI)	Adjusted HR (95% CI)	Statistical significance
FIGO stage (III/IV vs I/II)	2.52 (1.16–5.49)	2.63 (1.27–5.46)	P = 0.010	10.31 (2.30–40.31)	11.99 (2.75–52.20)	P = 0.001
Nuclear GPR30 (positive vs negative)	1.80 (1.06–3.06)	1.75 (1.04–2.93)	P = 0.035	1.83 (0.96–3.46)	–	ns
Cytoplasmic GPR30 (positive vs negative)	1.30 (0.95–6.99)	–	ns	0.97 (0.54–1.76)	–	ns
Nuclear grading (high vs low)	1.22 (0.69–2.17)	–	ns	1.26 (0.60–2.66)	–	ns
Age (≥60y vs <60y)	1.02 (1.02–1.04)	1.03 (1.01–1.05)	P = 0.001	1.01 (0.98–1.03)	–	ns

Hr, Hazard ratio; CI, confidence interval; FIGO, International Federation of Gynaecology and Obstetrics staging system (I/II = low/moderate grade tumours, III/IV = high grade/undifferentiated)

Discussion

To our knowledge, this is the first study to report that nuclear GPR30 expression is a significant, independent negative prognostic factor for overall survival in patients with ovarian cancer, although it does not predict 5-year progression free survival. The study also found that cytoplasmic GPR30 was not predictive of patient outcome in ovarian cancer. Similar results were found in the subgroup of patients with high grade ovarian cancer. Therefore, we hypothesise that GPR30 located in the nucleus, rather than in the cytoplasm, is involved in carcinogenesis. Interestingly, nuclear GPR30 expression was common in patients with recurrence even though it did not predict lower 5-year progression free survival which previously has been shown to be associated with recurrence. ¹⁴ GPR30 expression was not significantly correlated with any other clinicopathological characteristics which included FIGO stage, nuclear grade status, histology and the presence of ascites.

Previous studies have failed to define the role of GPR30 expression in ovarian cancer, although its expression was widely found in various cancer cell lines.^16–19 One study reported that GPR30 expression predicted poor outcome in advanced ovarian cancer, a finding which supports our observations. ²⁰ Another study found that there was no correlation between GPR30 mRNA and protein with patients’ clinical parameters. ²¹ In that study, only one-third of the patients had malignant ovarian cancer and the correlation between GPR30 and outcome was confirmed by univariate analysis which excluded several clinical characteristics. By contrast, in this present study, multivariate analysis was used to determine the impact of GPR30 on overall survival and 5-year progression free survival. Our data suggest that nuclear GPR30 is an independent prognostic factor, even after adjustment for other prognostic factors such as FIGO stage, histological grade, and patient age.

We found that GPR30 expression was not associated with 5-year progression free survival. By contrast, another study reported that GPR30 expression played a positive role in two-year progression free survival. ²² The authors of that report found that loss of GPR30 expression was observed in advanced ovarian cancer and predicted a worse outcome. Unlike the previous study which spanned two years, we followed our patients over five years, which may have accounted for the difference in results.

The intracellular localization of GPR30 is unclear, ²³ although GPR30 has been described as having a 7-membrane spanning domain. ¹² In the present study, GPR30 expression was observed in both the cytoplasm and nuclei of cells from ovarian cancer tissues. In vitro, GPR30 expression was not detected on the membrane of SKOV-3 ovarian cancer cells without pre-treatment but intracellular GPR30 was detected after cell pre-treatment with 0.1% saponin. Saponin form complexes with cholesterol to create pores in the cell membrane bilayers. In addition, the amphipathic nature of saponin provides it with surfactant activity which enhances the penetration of macromolecules through cell membranes. ²⁴ Our findings are supported by another study that also found both cytoplasmic and nuclear GPR30 staining in ovarian cancer cells. ²⁵

The study had limitations. For instance, only immunohistochemical staining was used and the population was confined to patients with epithelial ovarian cancer. Therefore, other studies are required to elucidate the function and role of GPR30 more fully in ovarian cancer. Two major questions remain unanswered: the mechanism by which GPR30 aggregates in the nucleus and the function of nuclear GPR30.

In conclusion, the study showed that GPR30 expression varied in different histological subtypes of ovarian cancer. In addition, nuclear GPR30 predicted poor overall survival and 5-year progression free survival in patients with ovarian cancer, whereas cytoplasmic GPR30 expression was not associated with outcome. The study also showed that nuclear GPR30 expression was an independent prognostic factor for overall survival but not 5-year progression free survival. Furthermore, nuclear GPR30 significantly predicted lower overall survival and 5-year progression free survival in patients with high grade ovarian cancer.