T-blocker: a simple and robust probe-free quantitative PCR assay to detect somatic mutations down to 0.1% frequency.

We have developed a simple and robust probe-free quantitative PCR (qPCR) assay method that can detect minor mutant alleles with a frequency as low as 0.1% in a heterogeneous sample by introducing a novel T-blocker concept to the allele-specific PCR method. Four new KRAS and BRAF mutation detection assays were developed and their performance was demonstrated by testing a large number of replicates, utilizing a customized PCR protocol. Highly efficient and specific mutant amplification in conjunction with selective wild-type suppression by the T-blocker concept enabled 0.1% detection sensitivity using the intercalating dye-based qPCR chemistry instead of more complex target-specific dye-labeled probes. Excellent consistency in sensitivity and specificity of the T-blocker assay concept was demonstrated.

Aberrant methylation of multiple genes in the upper aerodigestive tract epithelium of heavy smokers.

An important method for silencing tumor suppressor genes in cancers is by aberrant methylation (referred to as methylation) of CpG islands in gene promoter regions. In lung cancer, methylation of the genes retinoic acid receptor beta-2 (RARbeta-2), CDH13 (H-cadherin), p16(INK4a) (p16), RASSF1A (RAS association domain family I) is frequent. Thus, we investigated methylation of these genes in 4 different types of specimens (oropharyngeal brushes, sputum samples, bronchial brushes and bronchioloalveolar lavage [BAL] samples) of the upper aerodigestive tract epithelium from heavy smokers without evidence of cancer but with morphometric evidence of sputum atypia and compared the frequencies of methylation in the different types of specimens. In addition, we also analyzed sputum samples from 30 never smokers for methylation of these genes. Our major findings are: (i) At least one gene was methylated in one or more specimens from 48% of the smokers. However, methylation was statistically significant less frequently in never smokers compared to smokers. (ii) In general, methylation occurred more frequently in samples from the central airways (sputum, bronchial brushes) compared to the peripheral airways (BAL) and only occasionally in the oropharynx. (iii) RARbeta-2 was the most frequently methylated gene, whereas the frequency of methylation for the other genes was lower. (iv) Data from sputum samples and bronchial brushes were comparable. Our findings suggest that detection of methylation should be investigated as an intermediate marker for lung cancer risk assessment and response to chemopreventive regimens.

Aberrant methylation of the HIC1 promoter is a frequent event in specific pediatric neoplasms.

PURPOSE: To determine the role of methylation of HIC1, a candidate tumor suppressor gene on 17p13.3, in various types of pediatric tumors. EXPERIMENTAL DESIGN: We examined the methylation status of the HIC1 promoter by methylation specific PCR in 157 pediatric tumors and 27 nonmalignant tissues. We correlated methylation with mRNA expression by reverse transcription-PCR in eight tumor-derived cell lines. RESULTS: HIC1 methylation was frequent in medulloblastomas (80%, 12 of 15), retinoblastomas (67%, 6 of 9), rhabdomyosarcomas (59%, 13 of 22), germ cell tumors (55%, 6 of 11), and neurouroblastic tumors (36%, 14 of 39); neuroblastomas (43%, 12 of 28); ganglioneuromas (17%, 1 of 6); and ganglioneuroblastomas (20%, 1 of 5). In contrast, a low incidence of methylation was observed in osteosarcomas (17%, 2 of 12), Ewing's tumors (9%, 1 of 11), Wilms' tumors (3%, 1 of 31), and hepatoblastomas (0%, 0 of 7). HIC1 methylation was more frequent in the aggressive alveolar subtype of rhabdomyosarcomas (100%, 8 of 8) than the embryonal subtype (33%, 4 of 12; P < 0.005) and was rare in the nonmalignant tissues examined. Methylation was also demonstrated by sequencing in nine randomly selected tumor samples. Seven of eight pediatric tumor cell lines examined were methylated and showed loss or reduced HIC1 mRNA. Expression was strongly induced in all cell lines by treatment with the demethylating agent 5-aza 2'deoxycytidine. CONCLUSIONS: Our data suggest that aberrant methylation of HIC1 may play a role in the pathogenesis of specific pediatric tumors.

Frequent hypermethylation of the 5' CpG island of the mitotic stress checkpoint gene Chfr in colorectal and non-small cell lung cancer.

Chfr, a mitotic stress checkpoint gene, regulates a prophase delay in cells exposed to agents that disrupt microtubules, such as nocodazole and taxol. In the present study, we report that Chfr is frequently methylated in cell lines derived from tumors of the colon (80%), brain (100%) and bone (100%). In addition, Chfr was methylated in 37% of primary colon adenocarcinomas and in 10% of primary non-small cell lung carcinomas. In normal colon tissue, but not lung, there was evidence for age-related methylation of Chfr, suggesting that in some cases the tumor may have arisen from a methylated clonal precursor. Methylation was associated with loss of Chfr mRNA and protein expression in cancer cell lines. In cells with methylated Chfr, treatment with the demethylating agent 5-aza-2'-deoxycytidine resulted in re-expression of Chfr, and partial restoration of the prophase checkpoint. These results suggest that epigenetic inactivation of Chfr may be responsible for many of the checkpoint defects observed in human cancers.

Smoke exposure, histologic type and geography-related differences in the methylation profiles of non-small cell lung cancer.

Aberrant methylation of several known or putative tumor suppressor genes occurs frequently during the pathogenesis of lung cancers. There are major smoke exposure, histology, geography and gender-related changes in non-small cell lung cancer (NSCLC). We investigated smoking-related, histologic, geographic and gender differences in the methylation profiles of resected NSCLCs. We examined 514 cases of NSCLC and 84 corresponding nonmalignant lung tissues from 4 countries (USA, Australia, Japan and Taiwan) for the methylation status of 7 genes known to be frequently methylated in lung cancers [p16, RASSF1A (RAS association domain family 1), APC, RARbeta, CDH13, MGMT and GSTP1]. Multivariate analyses were used for data analysis. Adenocarcinoma was the major histologic type in women and never smokers; analyses that involved smoke exposure and gender were limited to this histology. Our major findings are a) methylation status of any single gene was largely independent of methylation status of other genes; b) the rates of methylation of p16 and APC and the mean Methylation Index (MI), a reflection of the overall methylation status, were significantly higher in ever smokers than in never smokers; c) the mean MI of tumors arising in former smokers was significantly lower than the mean of current smokers; d) the methylation rates of APC, CDH13 and RARbeta were significantly higher in adenocarcinomas than in squamous cell carcinomas; e) methylation rates of MGMT and GSTP1 were significantly higher in the USA and Australian cases than in those from Japan and Taiwan; and (f) no significant gender-related differences in methylation patterns were noted. Our findings demonstrate important smoke exposure, histologic type and geography-related differences in the methylation profiles of NSCLC tumors.

Methylation profiles of sporadic ovarian tumors and nonmalignant ovaries from high-risk women.

PURPOSE: The purpose of this research was to examine the DNA methylation profiles of primary sporadic ovarian cancers and ovarian tissues from high-risk women. EXPERIMENTAL DESIGN: We analyzed the DNA methylation status of nine cancer-related genes in 49 primary ovarian tumors, 39 nonmalignant ovarian tissues obtained from 16 women with no known risk and from 23 high-risk women with a strong family history of breast and/or ovarian cancer or BRCA1 germ-line mutations, and 11 ovarian cancer cell lines, by methylation-specific PCR. RESULTS: Our findings are as follows: (a) methylation rates of four of nine genes, RASSF1A (41%), HIC1 (35%), E-cadherin (29%), and APC (18%) were significantly higher in tumors compared with controls. At least one of the four genes was methylated in 76% of the tumors; (b) a low frequency of methylation was present in nonmalignant tissues; (c) no significant differences in methylation frequencies were seen between the nonmalignant ovarian tissues from women at high-risk and those with no known risk of developing ovarian cancer; (d) methylation of the BRCA1 gene was found in 10% of sporadic tumors but in none of the samples from women with a germ-line BRCA1 mutation; and (e) ovarian cancer cell lines showed a similar frequency of methylation to ovarian tumors except for the HIC1 gene. CONCLUSIONS: Our results suggest that aberrant methylation of specific genes, including two not described previously, may be important in ovarian cancer pathogenesis but not in ovaries at risk for cancer development.

Hierarchical clustering of lung cancer cell lines using DNA methylation markers.

Recent analyses of global and gene-specific methylation patterns in cancer cells have suggested that cancers from different organs demonstrate distinct patterns of CpG island hypermethylation. Although certain CpG islands are frequently methylated in many different kinds of cancer, others are methylated only in specific tumor types. Because distinct patterns of CpG island hypermethylation can be seen in tumors from different organs, it seems likely that histological subtypes of cancer within a given organ may exhibit distinct methylation patterns as well. The goal of our study was to determine whether the patterns of CpG island hypermethylation could be used to distinguish between different histological subtypes of lung cancer. We analyzed the methylation status of 23 loci in 91 lung cancer cell lines using the quantitative real-time PCR method MethyLight. Genes PTGS2 (COX2), CALCA, MTHFR, ESR1, MGMT, MYOD1, and APC showed statistically significant differences in the level of CpG island methylation between small cell lung cancer (SCLC) and non-small cell lung cancer cell lines (NSCLC). Hierarchical clustering using a panel consisting of these seven loci yielded two major groups, one of which contained 78% of the SCLC lines. Within this group, a large cluster consisted almost exclusively of SCLC cell lines. Our results show that DNA methylation patterns differ between NSCLC and SCLC cell lines and suggest that these patterns could be developed into a powerful molecular marker to achieve accurate diagnosis of lung cancer.

Aberrant promoter methylation profile of prostate cancers and its relationship to clinicopathological features.

PURPOSE: We investigated the aberrant methylation profile of prostate cancers and correlated the data with clinical findings. EXPERIMENTAL DESIGN: Gene promoter methylation was analyzed in 101 prostate cancer samples. In addition, we analyzed 32 nonmalignant prostate tissue samples, which included 25 with benign disease, benign prostatic hypertrophy, or prostatitis, and 7 normal tissues adjacent to cancer. The methylation status of 10 genes was determined. The methylation index (MI) was calculated as a reflection of the methylated fraction of the genes examined. RESULTS: Methylation percentages of the genes tested in prostate cancers were: RARbeta, 53%; RASSF1A, 53%; GSTP1, 36%; CDH13, 31%; APC, 27%; CDH1, 27%; FHIT, 15%; p16(INK4A), 3%; DAPK, 1%; and MGMT, 0%. Methylation percentages in nonmalignant tissues were much lower. For clinicopathological correlations, we divided the cancer cases into low (6 or less) or high (7 or more) Gleason score (GS) groups, and into low (8 ng/ml or less) or high (greater than 8 ng/ml) preoperative serum prostate-specific antigen (PSA) groups. Methylation of RASSF1A, GSTP1, RARbeta, and CDH13 genes was significantly more frequent in the high GS group than in the low GS group. Methylation of RASSF1A, CDH1, and GSTP1 genes was significantly more frequent in the high PSA group than in the low PSA group. The median MIs were significantly higher in the high GS and the high PSA groups. According to the Spearman rank-correlation test, there was significant correlation between MI and GS (coefficient = 0.43, P < 0.0001) and the preoperative serum PSA (coefficient = 0.37, P = 0.0003). CONCLUSIONS: Our results indicate that the methylation profile of prostate cancers correlates with clinicopathological features of poor prognosis.