Abstract
Background: Methylation of the O6-methylguanine-DNA methyltransferase (MGMT) gene promoter is a well-established predictor of response to the DNA-alkylating agent temozolomide in patients with glioblastoma. Materials and Methods: Pyrosequencing analysis was used to determine the MGMT promoter methylation status in 61 meningiomas, to clarify whether it might have a predictive role. Results: Only two tumors (3%) had a mean methylation frequency higher than the cut-off value of 10% for the four CpG sites examined. Conclusion: The methylation of the MGMT promoter is uncommon, or occurs at a low frequency in meningiomas. There is no convincing rationale to test such tumors for their MGMT methylation status in a clinical setting.
O6-Methylguanine-DNA methyltransferase (MGMT; DNA-O6-methylguanine:protein-L-cysteine S-methyltransferase, EC 2.1.1.63) is an enzyme which repairs the O6-methylguanine residues of DNA by removing a methyl group (1). The protein is encoded by a single gene (MGMT) located on chromosome band 10q26 (2). The promoter of MGMT lacks TATA and CAAT boxes but contains a CpG island with multiple CpG dinucleotides (3). Many studies have shown that methylation of cytosine to 5-methylcytosine in CpG dinucleotides in the promoter region of MGMT reduces expression of the gene (4-9).
Methylation of the MGMT gene promoter regulates transcription and is a well-established predictor of response to the DNA-alkylating agent temozolomide in patients with glioblastoma (1). Meta-analyses of MGMT promoter methylation in glioblastomas have shown that patients with methylated promoter in their tumor cells have better overall survival than those with unmethylated promoter when they were treated with temozolomide in addition to radiotherapy (10-12). The pattern of CpG site methylation varies among tumors. It is believed that methylation of CpG sites located in the first non-coding exon and enhancer is critical for loss of MGMT expression (1, 7, 13, 14). Thus, in a clinical setting, most assays for detection of MGMT methylation are designed to investigate these regions (1, 7, 13, 14).
The three most commonly used methods for detection of MGMT methylation are methylation-specific polymerase chain reaction (MSP), quantitative real-time polymerase chain reaction (PCR) or the similar MethyLight methylation-specific quantitative real-time PCR (MethyLight qMSP), and pyrosequencing (14-20). All the above-mentioned assays are based on the treatment of single-stranded DNA with sodium bisulfite, which results in conversion of unmethylated cytosine residues into uracil, whereas methylated cytosines are left unchanged (21, 22) (Figure 1). This treatment gives rise to different DNA sequences for methylated and unmethylated DNA (Figure 1), sequences which can be used as templates for the detection of unmethylated/methylated cytosine residues. In subsequent PCR amplification and sequencing, the uracil residues of the unmethylated DNA are recognized as thymine, whereas methylated cytosines are amplified as cytosine (21, 22). MSP is a qualitative method yielding a yes/no answer, whereas quantitative real-time PCR, MethyLight qMSP, and pyrosequencing provide the frequency of methylation for the examined CpG sites (14-20, 23).
Meningiomas are most often benign, intracranial neoplasms that can be cured by surgery alone (24). However, some of these tumors are more aggressive, such as high-grade meningioma, or may be inoperable because of their location, or may recur even in the absence of histological signs of atypia (25). Histopathological grading of these neoplasms, along with the presence or absence of postoperative residual tumor, is used to estimate the risk of recurrence and, hence, the need for further tumor management (24, 26-28). The decision whether or not to irradiate the neoplastic lesion is of particular interest as radiotherapy carries the risk of side-effects. Therefore, refinement of stratification criteria is warranted (24, 26-28).
In 2004, Chamberlain et al. (29) reported a prospective phase II study of temozolomide which was conducted on 16 patients with refractory meningioma. None of the patients showed complete or partial neuroradiographic response. In the same year, using MSP methodology, Bello et al. studied the promoter-methylation status of 10 tumor-related genes, among them MGMT, in a series of 98 meningiomas. The promoter of MGMT was found to be methylated in 16 out of the 98 examined meningiomas (30).
To date, the methylation status of the promoter region of MGMT in meningiomas has been examined in eight published studies (30-37). Table I summarizes their results and the methodology used in these studies. In six of them, only few meningiomas (up to 6%) had methylated MGMT promoter. However, in two studies, methylated MGMT promoter was found in 16% (30) and 34% of meningiomas (36). In six of the published works, MSP methodology was used (30-34, 36). In the seventh study, a methylation-specific and SYBR-green-based quantitative PCR technique was used (36), whereas in the eighth, targeted bisulfite sequencing was performed to detect MGMT promoter methylation (37). For the MSP methodology, the primers described by Esteller et al. (7) were used in five of the published works (30-32, 34, 36), whereas the primers described by Beier et al. (38) were used in the sixth study (33) (Figure 1).
In the present study, pyrosequencing was used to determine the MGMT gene promoter methylation frequencies in 61 meningiomas. Pyrosequencing is regarded as a very robust technique for analysis of MGMT promoter methylation and its clinical utility has been validated in several independent studies (15-18, 20, 39, 40). Pyrosequencing provides the frequency of methylated alleles of each CpG site analyzed whereupon the mean of the different sites is used to classify tumors as ‘methylated’ or ‘unmethylated’ (40, 41). The Therascreen MGMT Pyro Kit (Qiagen, Hilden, Germany) which was used in the present study, has been tested and validated; it has shown a strong analytical performance (40, 41). The kit is used for quantitative measurement of methylation at four CpG sites in exon 1 of the human MGMT gene CGACGCCCGCAGGTCCTCG [genomic sequence on chromosome 10 from 131265519-131265537 on Human Feb. 2009 (GRCh37/hg19) assembly, and sequence from 72 to 90 on the MGMT mRNA sequence with accession number NM_002412.4] (Figure 1).
Materials and Methods
Patients and samples. Tumor samples from 61 patients who underwent surgery at the Department of Neurosurgery, Oslo University Hospital between January 2014 and December 2016 were included in this study. Information about the patients' gender and age, diagnosis, and tumor subtype is given in Table II. The study was approved by the Regional Committee for Medical and Health Research Ethics South-East Norway (S-06046) and written informed consent to publication of the case details was obtained from all patients. The Ethics Committee's approval included a review of the consent procedure. All patient information has been de-identified.
DNA isolation and bisulfite conversion. Genomic DNA was extracted from tumor samples using the Maxwell 16 Instrument System and the Maxwell 16 Tissue DNA Purification Kit (Promega, Madison, WI, USA). The concentration and purity of DNA were measured using a NanoVue Plus Spectrophotometer (GE Healthcare Life Sciences, Oslo, Norway).
Unmethylated cytosine residues were converted to uracil by bisulfite treatment of 500 ng DNA using the EpiTect Bisulfite Kit (Qiagen, Hilden, Germany) and the QiaCube automated purification system (Qiagen) according to the manufacturer's recommendations.
Pyrosequencing analysis. The Therascreen MGMT Pyro Kit and the PyroMark Q24 system (both from Qiagen) were used to assess the methylation status of the MGMT gene promoter. In brief, bisulfite-converted genomic DNA was amplified by PCR, the amplicons were immobilized on streptavidin beads, and single-stranded DNA was prepared, sequenced, and finally analyzed on the PyroMark Q24 system. Detailed information about the procedure can be found in the following links: https://www.qiagen.com/no/resources/resourcedetail?id=29031fd2-6d22-4152-b544-288665bc5abc&lang=en, https://www.qiagen.com/no/resources/resourcedetail?id=59f0275d-e60f-4517-b786-b0e0ca13952e&lang=en, https://www.qiagen.com/no/resources/resourcedetail?id=a06f1196-2bd0-40af-87d5-45c80c285b48&lang=en. According to the company's information, the limit of blank values represent methylation frequencies obtained from healthy blood donor samples with a probability of 95%: 1.5, 1.8, 3.2, and 3.4 for CpG sites 1, 2, 3, and 4, respectively (mean for CpG sites 1 to 4=2.5). In our assays, the cut-off frequency for accepting methylation as positive for all four CpG sites was set to 10%.
Results
The methylation frequencies of the four analyzed CpG sites in exon 1 of MGMT in the 61 meningiomas are presented in Table II. In only two tumors was the mean methylation frequency of the four CpG sites higher than 10%. In case 18, which was an atypical meningioma, the mean methylation frequency was 33% and it was higher than 30% for all four CpG sites. In case 37, which was a grade I meningioma, the mean methylation frequency was 17%, but with marked differences among the four CpG sites: CpG site 1 had the highest methylation frequency (43%), followed by site 2 (13%), site 4 (8.5%), and site 3 (6.0%). The other meningiomas with histomorphological signs of aggressiveness, including six atypical and one anaplastic meningioma, had a methylation frequency of below 10.0%, similarly to the other 52 grade I meningiomas.
Discussion
Our results suggest that the methylation frequency of the MGMT gene promoter in general is low in meningiomas, with 59 tumors (97%) having a mean methylation frequency at the four examined CpG sites of below 7%. These data are in line with previous studies that described no MGMT promoter methylation or a low frequency using MSP or targeted bisulfite sequencing methodologies (31-33, 35, 37).
The two cases with methylated MGMT promoter, i.e., for which the mean methylation frequency of the four CpG sites was higher than 10%, had different methylation patterns for the four CpG sites. In the atypical meningioma (case 18, grade II tumor), the methylation frequency was higher than 30% for all four CpG sites. In the grade I meningioma (case 37), the methylation frequencies among the four CpG sites showed marked differences: CpG site 1 had the highest methylation frequency (43%), followed by site 2 (13%), site 4 (8.5%), and site 3 (6.0%). Bujko and Kober (37), using targeted bisulfite sequencing, reported a high methylation frequency (of over 75%) for single CpGs within the MGMT promoter region in five tumor samples. However, the average methylation level for the entire region was very low in those samples.
Bello et al. (30), Aydemir et al. (34), and Larijani et al. (36) found that the MGMT promoter was methylated in 16%, 11%, and 34% of the examined meningiomas, respectively. In these three studies, the same principal methodology was used, namely MSP with primers published by Esteller et al. (7). In contrast, and using the same method as above, Liu et al. (31) and de Robles et al. (32) showed that the promoter of MGMT was methylated in 6% and 0% of their examined meningiomas. Jabini et al. (35) used quantitative MSP, but again with the primers used by Esteller et al. (7), finding that none of 230 examined meningiomas had methylated MGMT promoter. The reason behind the reported differences in the frequency of methylated menigiomas, measured using the same MSP methodology, is unknown. MSP does produce false-positive as well as false-negative results under some circumstances, especially when performed on DNA of low quality or quantity, including DNA extracted from formalin-fixed and paraffin-embedded tissue (15, 42-44). In addition, mosaic methylation patterns and incomplete bisulfite conversion may lead to mispriming and lower sensitivity and specificity (15, 42-47).
Based on the results of our study and taking into consideration the already published data, amounting to 643 meningiomas altogether, we conclude that the methylation frequency of the MGMT promoter in meningioma is low (6%). Consequently, there is no convincing rationale for testing such tumors for their MGMT methylation status in a clinical setting.
Acknowledgements
This work was supported by grants from the Radiumhospitalets Legater and Larvik kreftforening.
Footnotes
This article is freely accessible online.
Conflicts of Interest
The Authors declare that they have no conflice of interests in regard to this study.
- Received June 11, 2018.
- Revision received June 28, 2018.
- Accepted July 8, 2018.
- Copyright© 2018, International Institute of Anticancer Research (Dr. George J. Delinasios), All rights reserved