Enhancer of zeste homolog 2 (EZH2) expression is an independent prognostic factor in renal cell carcinoma

Clinical data of patients (n = 768) with RCC who underwent radical nephrectomy or nephron-sparing surgery at the Department of Urology, University of Heidelberg, between 1990 and 2005 and had no other malignant tumor before or within one month after surgery were entered into a prospective database. Tumor stage was classified according to the tumor node metastasis staging system of 2002, tumors were graded on the basis the Fuhrman four-tiered nuclear grading system. In patients with metastases, the Motzer criteria (haemoglobin, corrected calcium, and Karnofsky performance scale) [18] were evaluated and patients categorized to one of the following risk groups: low, intermediate or high risk. Patients were prospectively evaluated every 3 months for the first 2 years after surgery, every 6 months for the next 3 years, and yearly thereafter (chest x-ray or thoracic CT scan; abdominal sonography or CT scan or MRI; serum chemistry). No adjuvant therapy was administered after radical surgery. Patients with metastases, a Karnofsky severity rating ≥ 80, and with no medical contraindications received palliative Interferon-alpha- and Interleukin-2-based immunotherapy. No tyrosine kinase inhibitors have been given.

The work was covered by a votum of the ethical committee of the University of Heidelberg No. 206/2005. Informed and/or written consent was obtained from each patient.

Tissue samples of all 768 patients included in the prospective clinical database were obtained from the Tissue Bank of the National Center for Tumor Diseases (NCT) Heidelberg and included in a TMA, containing 768 primary tumor and corresponding normal tissue samples, as previously described [19]. Briefly, representative tissue blocks were selected as donor blocks for the TMA. Sections were cut from each donor block and stained with H&E. Then, a morphologically representative region was chosen from each of the RCC and normal renal tissue samples. Two cylindrical core tissue specimen per tumor block (diameter, 0.6 mm) were punched from these regions and arrayed into the recipient paraffin block using a semiautomatic system (Beecher Instruments, Silver Spring, Maryland, USA). In total, 16 tissue array blocks were generated, each containing up to 200 core tissue specimens, matching 50 patients per array.

The TMA slides were dewaxed and rehydrated using xylene and a series of graded alcohols, followed by heat induced antigen retrieval using a target retrieval solution (S2031, DakoCytomation, Glostrup, Denmark) in a pressure cooker for 10 min. Immunohistochemical staining was performed on an automated staining system (Techmate 500, DakoCytomation) with a mouse monoclonal anti-EZH2 antibody (1:25, BD Transduction Laboratories, Franklin Lakes, NJ, USA) for 45 min [15]. An avidin-biotin-complex peroxidase technique using aminoethylcarbazole for visualisation and hematoxylin for counterstaining was applied. In accordance with the manufacturers' instructions, the following solutions were used: ChemMate Detection Kit (K5003, DakoCytomation), ChemMate Buffer Kit (K5006, DakoCytomation), and, for reduction of non-specific avidin/biotin-related staining, the Avidin/Biotin Blocking Kit (SP-2001, Vector Laboratories, Burlingame, USA). Sections were thoroughly washed, glass covered, and analysed by light microscopy (Olympus Vanox-T, Hamburg, Germany), using a magnification of up to × 400. Specificity controls of the anti-EZH2 antibody included iliac lymph node metastases of prostate carcinoma [17] showing typical staining pattern. Moreover, reactive infiltrating lymphocytes, which express detectable amounts of EZH2 protein [20], served as additional internal positive controls. As a negative control for the immunohistochemical staining procedure, the primary antibody was omitted, with all other experimental conditions kept constant. For immunohistochemical assessment of EZH2 expression, frequency of nuclear staining was evaluated using a semiquantitative score: 0 = no expression; 1 = positivity in 1 to 5% = low expression; 2 = positivity in >5 to 25% = intermediate expression; 3 = positivity in >25 to 50% = high expression; and 4 = positivity in more than 50% = very high expression. The arrays were independently scored by two researcher blinded for patient outcomes. For the few instances of discrepant scoring, a consensus score was determined.

The study has been conducted on the REporting recommendations for tumour MARKer prognostic studies (REMARK) of the NCI-EORTC Working Group on Cancer Diagnostics [21]. A retrospective study design was chosen, based on a prospective clinical database. Data analysis commenced in June 2006. Median follow-up of patients still alive was 6.0 years (range 0-16.1 years).

Patients' CSS was calculated from the date of renal surgery. The survival endpoint was the date of last follow-up or death. Kaplan-Meier estimates were used to describe survival rates including pointwise asymptotic 95%-confidence intervals using Greenwood's formula for standard error. Patients with proven tumor independent death were censored. Furthermore, assuming independence of the occurrence of RCC and other primary tumors in the same patient, patient survival was censored at the time of the occurrence of a second malignoma.

The following clinical and pathological features were studied for their prognostic relevance on long term survival of RCC patients: Age (≥65 years vs. <65 years), sex (male vs. female), performance status (Karnofsky severity rating <80 vs. ≥80), tumor stage (Stage II, III, IV vs. I), Fuhrman's grade (grade 2, 3/4 vs. 1), histopathological subtype (clear cell RCC vs. other types), nuclear EZH2 expression (1-5%, >5-25%, >25-50%, >50% vs. 0%).

Association between important prognostic factors and EZH2 levels was evaluated by Fisher's exact test, in case of large contingency tables the Monte Carlo Simulation was used.

For the evaluation of prognostic factors the study population was divided into subgroups with and without metastatic disease.

No data driven combination of adjacent categories related to EZH2 expression was carried out to retain the confirmatory nature of the evaluation of EZH2.

Univariate and multivariate analyses of prognostic factors were carried out within the Cox proportional hazards model using complete cases analysis.

For each prognostic factor the hazard ratio in the univariate analysis and the adjusted hazard ratio in the multivariate analysis are given, including the 95% confidence interval. A p-value < 0.05 was considered significant. For further description of the predictive value of EZH2 the concordance probability [22] of the Cox models including EZH2 were calculated and compared to the models excluding EZH2 but retaining all other variables.

The statistical analysis system SAS, Version 9.2 for Windows (SAS Institute Inc., Cary, NC, USA), the R package, Version 2.8.0 (R Foundation for Statistical Computing, Vienna, Austria), and StatXact, Version 8.0.0 (Cytel Inc., Cambridge, CA, USA) were used for the analyses. For the calculation of the concordance probability, the CPE package offered by Mo, Goenen and Heller was used with the R programming language.