Background
Glioblastoma (GBM), the most common primary brain tumor in adults, is a rapidly progressive and fatal disease with a low median overall survival[
1]. The treatment of these tumors with temozolomide (TMZ) introduces alkyl groups into DNA preventing its replication.This structural modification induces cell death. However, DNA-repair proteins, such as O
6-alkylguanine DNA alkyltransferase (AGT), are able to remove alkyl adducts from the O
6 position of guanine. Which is especially harmful, and the O
4 position of thymine, restoring these DNA bases and preventing TMZ-induced cell death[
2]. The DNA-repair protein AGT is encoded by the gene O
6-Methlyguanine-DNA-methyltransferase (MGMT). Determination of promoter methylation of the MGMT gene is being included as a relevant factor of the patient molecular profile[
3]. Although epigenetic silencing of the MGMT gene promoter has been associated with prolonged survival in glioblastoma patients[
4], there is much controversy about its use as a prognostic marker for the response of patients with newly diagnosed glioblastoma to temozolomide[
5,
6]. Moreover, whether any correlation exists between MGMT protein expression and promoter hypermethylation and patient outcomes has not been elucidated. Therefore, various studies using different assessments have reported different results[
7‐
11]. These inconsistencies may be caused by intratumoral heterogeneity, different evaluation methods, and different cut-off values.
The cancer stem cell (CSC) theory postulates that tumors arise from a subpopulation of cells that are characterized by self-renewal, infinite proliferative potential, multipotency, and their ability to initiate new tumors in vivo[
12]. Interestingly, CSC cells are postulated to be mediators of radio- and chemo-resistance. Tumor cells with stem-like features have been identified in glioblastoma[
13]. These cells express the transmembrane glycoprotein prominin-1 (CD133) (a cell-surface marker expressed on normal human neuronal stem cell) and have the ability to initiate a tumor in vivo after xenotransplantation in mice. Few data are available on the actual prognostic impact of CD133 expression in malignant gliomas. Glioblastoma stem cells are highly resistant to conventional chemotherapy and radiotherapy[
14,
15] and the chemo-radioresistance of these cells may be responsible for the poor clinical outcome of these patients.
The aim of our study is to determine the prognostic significance of MGMT by analyzing both MGMT gene promoter methylation and protein expression in a homogenous series of GBM patients treated with radiotherapy and temozolomide. In addition, we evaluated the immunohistochemical expression of CD133 investigating its association with MGMT and clinical outcomes.
Methods
Tissue samples
Samples were obtained from the Anatomopathological Service of Hospital Virgen de las Nieves from Granada (Spain) and the University Hospital of Sassari (Italy), from 2001 to 2009. The Ethics Committees of both Hospitals approved the collection and use of human brain tumor tissue samples. We obtained tumor tissue samples from 78 patients with newly diagnosed GBM which was histologically confirmed and Karnofsky performance score (KPS) ≥ 60. Patients were selected regardless of extent of surgery. All patients had been treated with concurrent chemo-radiotherapy (2 Gy per fraction, once a day, five days a week, 60 Gy total dose) with concomitant TMZ (75 mg per square meter of body surface area per day for seven days a week from the first to the last day of radiotherapy) followed by adjuvant TMZ (200 mg per square meter of body surface area on days 1 to 5 given at four-weekly intervals). The patient characteristics are summarized in Table
1.
Table 1
Patient characteristics (n = 78)
Gender | Male | 42 (53.8%) |
| Female | 36 (46.1%) |
Tumor location | Frontal | 20 (25.6%) |
| Parietal | 13 (16.6%) |
| Temporal | 13 (16.6%) |
| Occipital | 11 (14.1%) |
| More than one lobe | 21 (26.9%) |
Duration of symptoms prior to diagnosis | < 3 months | 60 (76.9%) |
| ≥ 3 months | 18 (23.1%) |
Karnofsky performance score | ≥ 60 | 78 (100%) |
Patients age 70 years or older with newly diagnosed GBM and postoperative Karnofsky performance score (KPS) greater than 60 were eligible for this nonrandomized phase II trial
DNA was extracted according to standard protocols. Methylation patterns in the CpG island of MGMT were determined by chemical modification of unmethylated, but not methylated, cytosine to uracil. Methylation-specific PCR (MSP) was performed with primers specific for either modified-methylated or unmethylated DNA, as described previously[
16]. DNA (2 μg) was denatured with sodium hydroxide and modified with sodium bisulfite. DNA samples were then purified (EpiTect Bisulfite Conversion). Primer sequences for the unmethylated reaction were 5
′-TTTGTGTTTTGATGTTTGTAGGTTTTTGT-3
′ (forward primer) and 5
′-AACTCCACACTCTTCCAAAAACAAAACA-3
′ (reverse primer), and for the methylated reaction, they were 5
′-TTTCGACGTTCTAGGTTTTCGC-3
′ (forward primer) and 5
′-GCACTCTTCCGAAAACGAAACG-3
′ (reverse primer). Amplified products of PCR were electrophoresed on 3% agarose gels, were visualized by staining with ethidium bromide, and were examined under UV illumination.
Immunohistochemistry
Antibodies for MGMT (1:50; Santa Cruz Biotechnology, Inc.) and CD133 (1:50, Abcam, Cambridge, UK) were used for immunohistochemical analysis. Immunostaining was performed using the Bond Polymer Refine Detection system (Leica Microsistemas S.L.U, Barcelona, Spain). Briefly, representative paraffin blocks were cut consecutively at a thickness of 4 mm, and immunohistochemical staining was carried out using the Microprobe Immuno/DNA stainer (Fisher Scientific, Tustin, CA, USA). Sections were deparaffinized in xylene and treated with 0.3% hydrogen peroxide in methanol for 20 min to block endogenous peroxidase activity. The sections were washed in phosphate-buffered saline and then incubated with primary antibodies for 60 min. The samples were then incubated in secondary antibody for 8 min. The substrate chromogen, 3.3′-diaminobenzidine (DAB), enabled visualization of the complex via a brown precipitate. Hematoxylin (blue) counterstaining enabled the visualization of the cell nuclei. Omission of primary antibody served as a negative control. Readings were taken automatically with the ACIS III DAKO system for quantification immunohistochemistry and were verified by two experienced pathologist. The percentage of stained tumor cells was scored as +/− (<10%), 1+ (10% to 25%), 2+ (25% to 50%), 3+ (>50%). For statistical analysis, scores of +/− and 1+ were defined as low-expression group and scores of 2+ and 3+ were defined as high-expression.
Statistical analysis
Overall survival (OS) was calculated from the date of the diagnosis. The progression-free survival (PFS) was calculated from the date of the progression, according of MacDonald criteria[
17]; size and volume ≥ 25% of initial measurements, or appearance of a new lesion, or if the patient’s neurologic condition worsened and required an increased dose of steroids. The PFS and OS curves were estimated by the Kaplan-Meier method and compared using the two-sided log-rank test. A multivariable analysis was done using the Cox proportional hazards regression to determine the prognostic effect of variables. Contingency tables were analyzed by
X2 and Fisher’s exact test. The McNemar test was applied to compare variables before and after treatment. All calculations were made using the statistical software SPSS, version 15.0. Statistical significance was set at the level of P < 0.05.
Discussion
Clinical trials have demonstrated a significantly prolonged median survival of GBM patients treated with TMZ associated to radiotherapy after surgical resection[
18‐
20]. In addition, a strong correlation between the MGMT gene promoter methylation status and the TMZ treatment effect and outcome was shown by Hegi et al.[
4], confirming previous results which correlated MGMT inactivation and clinical response to alkylating agents[
16,
21]. Criniere et al.[
22] showed that while the MGMT promoter methylation status had no impact on the OS of GBM patients treated with alkylating agents, it did have an impact on those treated with chemo-radiotherapy, suggesting that the prognostic impact of this methylation is dependent on therapeutic modalities. In fact, Weller et al.[
23] analyzed patients with GBM treated with radiotherapy, with chemotherapy and with both radiotherapy and chemotherapy and showed that the methylation status was a significant prognostic factor for OS and PFS only in the subgroup of patients treated with radiotherapy and concurrent TMZ. These results have been recently confirmed by Cao et al.[
8], Minniti et al.[
24] and Kim et al.[
25]. Recently, the methylation status was analyzed in elderly patients with GBM and was found to be strictly correlated with the pattern of, and time until, GBM recurrence[
26], but not with its evolution after recurrence[
27]. Rivera et al.[
28] demonstrated that MGMT promoter methylation was a predictor of survival in GBM treated exclusively with radiotherapy. In addition, a randomized phase III trial comparing standard adjuvant TMZ with a dose-dense schedule in newly diagnosed GBM confirmed the prognostic significance of MGMT methylation in GBM[
29]. However, previous studies considered promoter methylation of the MGMT gene not to be a reliable prognostic factor of responsiveness to alkylating agents in glioblastomas[
30]. Recent studies have also questioned the role of promoter methylation status of MGMT in GBM. Yachi et al.[
31] failed to establish this correlation in a larger number of patients and showed that neither MSP-MGMT methylation nor immunohistochemical MGMT expression had prognostic implications in GBM patients. Similarly, Tang et al.[
32] did not find a correlation between progression-free survival and MGMT promoter methylation in chinese patients. In this context, we conducted a retrospective study in a homogeneous series of patients diagnosed with GBM treated with radiotherapy and concurrent temozolomide using MSP, which has been proposed as the most convenient technique in clinical routine diagnostics[
33]. We found that the percentage of methylation of the MGMT promoter to be higher than that reported by Hegi et al.[
4] but similar to those reported by other authors[
22,
34]. The MGMT methylation status was clearly confirmed as an independent prognostic factor of GBM PFS and OS. In addition, patients with a methylated MGMT promoter status had higher response rates to TMZ and radiation therapy compared to those with a non-methylated status, so that MGMT methylation was a predictive factor for radiologic response
On the other hand, the association between MGMT protein expression and promoter methylation in vivo has been widely discussed. Several studies have reported a significant association of high MGMT expression and poor prognosis of patients[
7‐
10,
35‐
38]. We analyzed the expression of MGMT by immunochemistry using a digital quantitative method to avoid observer variability[
39]. Our study clearly showed no correlation between MGMT expression and MGMT promoter methylation, supporting the finding observed by Rodriguez et al.[
40] and Uno et al.[
41], or overall survival or radiological response coinciding with those findings of Preusser et al.[
11]. The regulation of the MGMT gene is a complex phenomenon in which promoter hypermethylation is one of the factors that influence the final expression of the protein. In this context, the recent demonstration that there is discordance between MGMT promoter methylation and levels of MGMT mRNA expression suggests that other mechanisms may regulate the expression of this enzyme[
42]. It also possibly suggests that promoter methylation and expression alone are not sufficient to provide information on the expected clinical course in patients with malignant glioma who receive chemotherapy with alkylating agents. In fact, a comprehensive study undertaken by sequencing the MGMT gene promoter has shown a strong correlation between the methylation site and treatment response[
43].
CD133, a five-transmembrane cell surface protein found in human stem cells from various sources including the central nervous system[
44], has been proposed to detect GBM CSCs. Considering the inherent resistance of CSCs to chemotherapy and radiotherapy[
14,
15], it has been hypothesized that the clinical outcome will be inversely related to the presence of CSC-marker-positive cells. However, the impact of the presence of CSC in the clinical progression of tumors is unknown. Few studies exploring the prognostic value of CD133 expression as a marker of CSC in GBM have been undertaken; most were heterogeneous and used different methods (QRT-PCR, immunohistochemistry, FACS) so that comparisons are difficult. Intense CD133 expression was detected in high-grade oligodendroglial tumors[
45] and in grade II-IV gliomas[
46], both with poor prognoses. Similar results were founded in grade IV gliomas where CD133 expression was related to OS and PFS[
47]. Murat et al.[
48] provided evidences that the glioblastoma stem cell phenotype (including CD133 expression) correlated with chemoradiotherapy resistance and patient survival. In a study with very homogeneous samples of GBM, high expression of CD133 was found to be an unfavorable prognostic factor[
49]. In addition, an in vitro study using CSC obtained from 44 GBM patients to evaluate CD133/Ki67 expression by immunohistochemical analysis, concluded that CD133+ was correlated to survival[
50]. However, the same authors demonstrated that high expression of CD133 was associated with a better prognosis when detected by FASCcan[
51]. Similar results were previously found by Joo et al.[
52] who described CD133 as a favourable prognostic factor for GBM. In this context, our study clearly demonstrates that CD133 has no implication in the prognoses of GBM patients supporting similar results of Kim et al.[
53]. Finally, the prognostic impacts of variations of MGMT promoter methylation or MGMT and CD133 protein expression after treatment, are not known. A previous study determined that MGMT methylation status has no prognostic value after GBM recurrence[
27]. Our preliminary study in samples obtained before and after treatment from only ten patients with recurrent GBM suggested that there are no differences between the analyzed variables although the low number of patients does not allow to obtain statistically significant conclusions.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
CM, JP and AA participated in the project design, coordination the experiments, and manuscript preparation. RO, JAO and FRS carried out bisulfite treatment and methylation-specific PCR. AC, PJA and RL carried out immunohistochemical analysis. BG and RM participated in the collected and analyzed the clinical data. All authors read and approved the final manuscript.