Abstract
Epigenetic silencing of cancer-related genes by promoter methylation is a frequent event in sporadic colorectal cancer. The CpG island methylator phenotype (CIMP+), in which discrete genes throughout the genome are simultaneously methylated, and long-range epigenetic silencing, whereby multiple genes within contiguous chromosomal regions are methylated, have been described in subsets of colorectal cancer. We previously reported the concurrent methylation of the mismatch repair gene MLH1 with a cluster of flanking genes in chromosome region 3p22 in sporadic colorectal carcinoma exhibiting microsatellite instability and the BRAF V600E mutation. Herein, we aimed to determine whether methylation of MLH1 and neighbouring 3p22 genes, singly or concomitantly, correlate with the germline c.-93G>A SNP within the MLH1 promoter, CIMP+ and other clinicopathological and molecular features of the tumours. By studying a cohort of 946 sporadic colorectal cancer cases, we show a strong association between concordant methylation of ≥3 of five 3p22 genes with CIMP+ and the BRAF V600E mutation (P<0.001). These associations were independent of microsatellite instability, as concomitant methylation of 3p22 genes other than MLH1 was found in microsatellite stable cancers. These findings show that long-range epigenetic silencing across 3p22 occurs in the context of CIMP+ and the BRAF V600E mutation, and only gives rise to microsatellite instability when this process encompasses MLH1. Furthermore, the strong relationship between long-range epigenetic silencing of 3p22 and CIMP+ provides further evidence that these two purportedly distinct epigenetic phenotypes represent a single entity with a common aetiology. Low-level methylation of MLH1 and flanking 3p22 genes, as well as the BRAF V600E mutation, were detected in the apparently normal colonic mucosa of a small number of cases whose tumours showed a similar molecular profile, suggesting that these concurring genetic and epigenetic events can occur as a field defect in neoplastic development.
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Main
Epigenetic silencing of various tumour-suppressor and DNA repair genes by cytosine methylation of promoter-associated CpG islands is a frequent event in sporadic colorectal cancer.1 A classic example of this is the biallelic promoter methylation of the mismatch repair gene, MLH1, which accounts for ∼70% of sporadic colorectal cancers that exhibit microsatellite instability as a direct consequence of impaired mismatch repair activity.2, 3, 4, 5 MLH1 methylation occurs in close association with the presence of the oncogenic BRAF V600E mutation in sporadic colorectal cancer.6 The c.-93G>A SNP (rs1800734) within the MLH1 promoter has been associated with an increased risk of microsatellite instability or MLH1 methylation in some colorectal and endometrial cancer populations, but not in others.7, 8, 9, 10 However, these associations have been disputed on the basis that linkage disequilibrium with pathogenic mutations could not be ruled out in populations with a high incidence of familial cancer.11 Recently, promoter reporter assays showed that the A allele of this SNP conferred reduced transcriptional activity compared with the G allele, consistent with the notion that this allele might predispose to promoter methylation.12 The potential role for genetic-based variants in conferring susceptibility of MLH1 to epigenetic silencing thus remains in question.
In recent years, there has been increasing evidence that aberrant methylation in sporadic colorectal cancer tends to occur in consistent patterns, which are associated with particular clinicopathological and molecular features. The CpG island methylator phenotype (CIMP) has been proposed to describe the simultaneous methylation of multiple but discrete CpG islands at distinct loci throughout the genome in the development of a subset of colorectal cancers, now referred to as CIMP+.13, 14, 15 Interestingly, the CIMP+ phenotype also correlates closely with the presence of the BRAF V600E mutation, MLH1 methylation and microsatellite instability,13, 14, 15, 16 although the basis for the inter-relationship between these genetic and epigenetic phenomena remains unknown. More recently, long-range epigenetic silencing, in which concordant CpG island methylation and chromatin modification across large genomic regions induces silencing of multiple contiguous genes, has also been demonstrated for specific chromosomal regions in a proportion of sporadic colorectal cancers.17, 18 Long-range epigenetic silencing was initially demonstrated for chromosome region 2q14.2, exerting an effect equivalent to an acquired genetic deletion of this large chromosomal region.17 In a previous study by our group, we demonstrated that methylation of MLH1 in sporadic microsatellite unstable colorectal cancer is also not typically confined to this gene.18 Consistent with long-range epigenetic silencing, we found that MLH1 and flanking genes AB002340, ITGA9, PLCD1 and DLEC1 spanning a 1.1-Mb region of chromosome 3p22 were differentially methylated and transcriptionally inactivated in sporadic microsatellite unstable cancers, but not in microsatellite stable cancers. The methylated 3p22 genes were interspersed with other genes that escaped CpG methylation, but were nevertheless also downregulated (summarized in Figure 1a).18 This regional pattern of dense 3p22 methylation was cancer specific, as it was not found in the paired normal colorectal mucosa of the colorectal cancer cases using combined bisulphite restriction analysis. Several of these 3p22 genes, including ITGA9, PLCD1 and the putative tumour-suppressor gene DLEC1, are commonly inactivated through methylation or deletion in various types of human cancers,14, 19, 20, 21, 22, 23 suggesting that their loss of activity has a contributory role in cancer development or progression. Long-range epigenetic silencing across the 3p22 region was strongly associated with the presence of the activating BRAF V600E mutation, consistent with previous findings for MLH1 alone.18 In light of the strong association between the BRAF V600E mutation and the CIMP phenotype, as well as the independent association between this oncogenic mutation and 3p22 methylation, we hypothesized that methylation of five 3p22 genes (AB002340, MLH1, ITGA9, PLCD1 and DLEC1), individually and concomitantly, occurs in the context of CIMP+. Supporting this notion, a recent study found a strong association between CIMP+ and long-range epigenetic silencing of the 2q14.2 chromosomal region in colorectal cancer, suggesting that these two epigenetic profiles may represent a unified epigenetic phenotype induced by a common mechanism, rather than distinct entities.24
In the present study, we analysed a cohort of 946 sporadic colorectal cancer cases to determine whether MLH1 methylation is associated with the germline c.-93G>A SNP genotype or methylation of the 3p22 region, and furthermore, if methylation of the 3p22 gene cluster correlates with the CIMP+ phenotype. As it is now well established that a small subset of tumours exist that are microsatellite stable, BRAF V600E mutant and CIMP+,14, 15, 16, 25 we also sought evidence that this subtype of microsatellite stable cancers is concomitantly methylated at gene promoters within the 3p22 chromosomal region other than MLH1. Finally, to determine whether methylation of MLH1 and flanking genes, as well as the BRAF V600E mutation, might predispose to cancer development, we sought these changes in the apparently normal colorectal mucosa from a subset of the colorectal cancer cases and controls without neoplasia.
Materials and methods
Patients and Samples
A total of 946 colorectal cancer samples procured from a consecutive series of 946 individuals (mean age 69±12 years; range 24–99 years) who had undergone curative surgical resection of colorectal adenocarcinoma at St Vincent's Hospital, Sydney, between January 1993 and November 2006 were included in this study. Individuals with a clinical diagnosis of familial adenomatous polyposis, hereditary non-polyposis colorectal cancer or inflammatory bowel disease at the time of operation were excluded. Known carriers of germline mutations of APC, MYH and the mismatch repair genes were also excluded from the study. The clinical characteristics of individuals in this study cohort and the pathological characteristics of their cancers were obtained from medical and histopathological reports. Right-sided cancers were defined as those located proximal to the splenic flexure, and the remainder were defined as left-sided. Based on the information of the histopathological report, carcinomas were staged by the AJCC/UICC TNM system according to the sixth edition of the AJCC staging manual.26
The paired normal colorectal mucosa from 235 of the colorectal cancer cases (mean age 74±9 years; range 51–99 years) were assessed for methylation status at MLH1. These normal colorectal mucosa samples were derived from 104 cases with a microsatellite unstable cancer, matched by gender and age (±5 years) to 131 cases with a microsatellite stable cancer. Those found positive for MLH1 methylation were further analysed for the presence of methylation at 3p22 flanking genes, as was their peripheral blood. For each of these cases, normal colorectal mucosa samples that had no detectable MLH1 methylation were selected from cases with microsatellite stable cancers matched for sex and age (within ±5 years). The normal colorectal mucosa from a further 13 cases (mean age 76±9; range 63–92 years) selected at random from those whose colorectal cancers were V600E mutant and had concomitant methylation of ≥3 of the five 3p22 genes were subsequently studied for low-level methylation of the 3p22 genes. These were matched by sex and age (±5 years) to the normal colorectal mucosa from cases whose tumours were BRAF wild type and did not have regional 3p22 methylation (mean age, 75±10; range 58–90 years). As controls, biopsy samples of normal colonic or rectal mucosa were collected from 21 individuals without a history of colorectal cancer who had either undergone colorectal surgery or colonoscopy for a non-neoplastic disorder (mean age, 58±18; range, 33–82 years). Genomic DNA was extracted from fresh-frozen colorectal cancer and normal colorectal mucosa specimens and peripheral blood by standard phenol–chloroform extraction. This study was approved by the human research ethics committee of St Vincent's Hospital (approval numbers H02/022 and H07/002), and informed consent was obtained from all participating individuals.
Genotyping of the c.-93G>A SNP (rs1800734)
Germline DNA extracted from normal colorectal mucosa or peripheral blood was used to genotype the c.-93G>A SNP within the MLH1 promoter in 320 colorectal cancer cases, comprising 108 microsatellite unstable cases for case comparison with 212 randomly selected microsatellite stable cases, and 399 de-identified healthy controls from the Red Cross Bank. Genotyping was performed by PCR amplification of the promoter using primers (5′–3′) AAACGAACCAATAGGAAGAGC and ACTCCCTCCGTACCAGTTCT with annealing at 56.5 °C, followed by direct sequencing using the same primers.
Methylation Analyses
Bisulphite modification was performed on 0.5–1 μg of genomic DNA using the EZ DNA methylation kit™ (Zymo Research, Orange, CA, USA) according to the manufacturer's instructions. The promoter methylation status of five 3p22 genes, namely AB002340, MLH1 (Deng-C region),27 ITGA9, PLCD1 and DLEC1, was assessed by real-time quantitative methylation-specific PCR assays, which have an analytical sensitivity of 0.1 methylated alleles (Table 1 ). Reactions were performed in 20 μl volumes containing 2 μl (50–100 ng) of bisulphite-converted DNA, 1 × IQ SybrGreen supermix (Bio-Rad, Hercules, CA, USA) and 0.3 μM of the respective forward and reverse primers, listed in Supplementary Table 2. All real-time methylation-specific PCR reactions were performed using a MyIQ™ Single-Colour Real-Time PCR machine (Bio-Rad). Cycling conditions were: 95 °C for 6 min, followed by 40 cycles at 94 °C for 30 s, the respective annealing temperature for 30 s (Table 1), and extension at 72 °C for 30 s. The fluorescence output signal was measured in the fourth step of each cycle (>72 °C) held for 30 s to exclude potential signals from primer dimerization. Reactions that amplify a control template MyoD irrespective of its methylation status were used to normalize for DNA input. For a given sample, the starting copy number of the methylated 3p22 genes and MyoD genes was determined in triplicate by interpolation against the respective standard curves consisting of serial dilutions of plasmids of known copy number harbouring the target sequences. The copy numbers were used to determine the percentage of methylation reference (PMR) values with reference to completely methylated in vitro human DNA (Chemicon, Temecula, CA, USA), as previously described.28 Cancers were considered methylated when PMR values were >4.0, as this threshold has previously been shown to correlate with loss of gene expression in a study that correlated the distribution of PMR to protein expression by immunohistochemistry.29 For normal colorectal mucosa samples, PMR values were analysed as continuous variables given that DNA methylation is likely to occur at lower levels within an apparently normal field of colorectal crypts. An analysis of CIMP status in colorectal cancer samples was performed using MethyLight on a set of five CIMP markers as previously described.14 Cancers were considered CIMP+ when ≥3/5 (60) markers showed intensities of methylation at PMR >4.0.16
Microsatellite Instability, BRAF and KRAS Mutation Status
Microsatellite stability status was determined using two mononucleotide markers BAT25 and BAT26 as well as three dinucleotide markers D5S346, D2S123 and D17S250, as previously described.30 A carcinoma sample was classified as having microsatellite instability when two or more markers demonstrated instability in the tumour DNA compared with the corresponding constitutional DNA. Presence of the common BRAF V600E and KRAS codon 12 and 13 mutations in colorectal cancer samples were detected by pyrosequencing, as previously described.31 For normal colorectal mucosa samples, BRAF V600E mutation status was determined by the highly sensitive allele-specific real-time PCR as previously described.32 A sample was called positive for BRAF V600E mutation only when the cycle difference between the wild-type and mutant reactions (ΔCt) was <11 (Supplementary Figure 2), as previously validated.31
Statistical Analyses
Categorical variables were compared using the χ2 test or Fisher's exact test. The Mann–Whitney U test was used to compare continuous variables that were not normally distributed. Multivariate analysis was performed using multivariate logistic regression analysis. Samples with one or more missing data points were excluded from the multivariate analysis. Associations were considered significant when P≤0.05 (two sided). These analyses were performed using the SPSS statistical package, version 18.0 (SPSS, Chicago, IL, USA). Multiple hypotheses testing using the Holm's test was performed to correct for false-positive results where applicable. Hierarchical clustering analysis was performed using the Hierarchical Clustering Explorer version 3.5 (University of Maryland), available online at http://www.cs.umd.edu/hcil/hce. An average linkage method using Manhattan distance was used.
Results
Lack of Association between MLH1 Methylation and the c.-93G>A Promoter SNP
Within a consecutive series of 946 sporadically arising colorectal carcinoma, methylation of the ‘Deng-C region’ of the MLH1 promoter was identified in 10.1% of colorectal cancers, including 68.1% of microsatellite unstable tumours, and correlated closely with microsatellite instability, the CIMP+ phenotype, presence of the BRAF V600E mutation, right-sided location, mucinous histology, higher tumour grade, early stage, increased age and female gender (Table 2 ), consistent with previous findings.14, 15, 33 Genotyping of the c.-93G>A SNP (rs1800734) within the MLH1 promoter in 320 colorectal cancer cases and 399 healthy controls showed that the genotypes were in Hardy–Weinberg equilibrium for both populations and demonstrated similar allele frequencies (‘A’ allele frequency: 29.4% in cases and 25.7% in healthy controls). No association was found between the G>A SNP genotype and a diagnosis of cancer when compared with the healthy control population (Table 3 ). We found no association between MLH1 methylation or microsatellite instability in a case-by-case comparison, when the AA and GA genotypes were combined into one category and compared with the homozygous G genotype (Table 3). Similarly, there was no association with the A allele when the three genotypes were separated (AA, GA and GG, data not shown). Finally, there was no correlation between the G>A SNP genotype (with AA and AG combined) and MLH1 methylation within the microsatellite instability or CIMP+ groups, either (Table 3), arguing against an underlying role for this SNP genotype in inducing methylation of MLH1 in this sporadic colorectal cancer cohort.
Concomitant Methylation of a Cluster of 3p22 Genes in a Subset of Sporadic Colorectal Cancers
To determine whether our previous finding of concomitant methylation of a cluster of 3p22 genes in sporadic colorectal cancer was consistent in this large cohort, the methylation status of four genes flanking MLH1 previously found to be subject to CpG island methylation was determined (Figure 1a). The most frequently methylated gene was AB002340, followed by DLEC1, ITGA9, MLH1 and finally, PLCD1 (Table 2 and Figure 1b). A significant association was found between methylation of each 3p22 gene individually and that of the four other genes (P<0.0001; Table 4 ), confirming that methylation typically occurred in a cluster in the 3p22 region. Hierarchical clustering showed that methylation of MLH1 concurred most frequently with the nearby ITGA9 gene (Figure 1b), although these two genes are separated by two genes (LRRFIP2 and GOLGA4) that are not prone to methylation in colorectal cancer (Figure 1a).
Simultaneous Methylation of ≥3 3p22 Genes Correlates Closely with the Presence of the BRAF V600E Mutation, Microsatellite Instability and CIMP+
The proportion of sporadic colorectal cancers showing different numbers of methylated 3p22 genes stratified by BRAF V600E mutation, microsatellite stability status and CIMP status is shown in Figures 2, 3 and 4, respectively. The majority of cancers showed heavy methylation at multiple loci (≥3) in cancers also demonstrating BRAF V600E mutation (Figure 2), microsatellite instability (Figure 3) and the CIMP+ phenotype (Figure 4), whereas the percentage of BRAF wild-type, microsatellite stable and CIMP− cancers decreased consistently with increasing number of methylated 3p22 genes. Consistent with these findings, colorectal cancers were dichotomized into those with methylation at 3–5 of the five 3p22 (10.8%) genes, designated positive for regional 3p22 methylation, and those with methylation at 0–2 (89.2%), designated negative for regional methylation. On this basis, regional 3p22 methylation was found predominantly in colorectal cancers with BRAF V600E mutation (Figure 5). Among BRAF mutant cancers, regional 3p22 methylation was most frequently found in those that demonstrated concomitant CIMP+ and microsatellite instability. Regional 3p22 methylation was found in a small number of BRAF mutant cancers that showed either CIMP+/microsatellite stable or CIMP–/microsatellite instability phenotypes, and was entirely absent in cancers that were both CIMP– and microsatellite stable. Although regional 3p22 methylation was found predominantly in microsatellite unstable tumours, 15 (1.6%) colorectal cancers methylated at ≥3 3p22 loci excluding MLH1 were microsatellite stable, suggesting that regional 3p22 methylation is not specific to microsatellite instability (Figure 5).
Association between Methylation of Individual 3p22 Genes, Regional 3p22 Methylation and Clinicopathological and Molecular Features
The association between promoter methylation of 3p22 genes individually or as a cluster of ≥3/5 loci and other clinicopathological and molecular features of colorectal cancer is summarized in Table 2. On an individual basis, significant correlations were observed between methylation at each of the four 3p22 genes flanking MLH1 and female gender, right sidedness of tumours, mucinous histology, low tumour grade, wild-type KRAS, BRAF V600E mutant, microsatellite instability and CIMP+ phenotype (all P<0.05), consistent with findings for MLH1 methylation alone (Table 2). The presence of methylation of the 3p22 genes was also associated with older age, with the exception of DLEC1 methylation (P=1.00). When categorized by regional 3p22 methylation (methylation at ≥3/5 loci), significant correlations were observed between cancers demonstrating clustered 3p22 methylation and older age, female gender, right sidedness of cancers, mucinous histology, high tumour grade, wild-type KRAS, BRAF V600E mutation, microsatellite instability and CIMP+ (all P<0.01). Multivariate analysis of clinicopathological and molecular associations found BRAF V600E mutation, CIMP+ and mucinous histology to be independent predictors of regional 3p22 methylation (Table 5 ).
Detection of Low-Level Methylation of MLH1 and Other 3p22 Genes and BRAF V600E Mutation in the Normal Colorectal Mucosa of a Small Number of Colorectal Cancer Cases
Using sensitive real-time quantitative methylation specific PCR capable of detecting low levels of methylation (0.01), normal colorectal mucosa samples from 104 cases with microsatellite unstable carcinoma, 131 cases with microsatellite stable cancer and 21 individuals without neoplasia were screened for the presence of MLH1 methylation. No methylation was detected in normal colorectal mucosa from individuals with sporadic microsatellite stable colorectal cancer or those without neoplasia (PMR=0; Figure 6). Interestingly, however, low-density MLH1 methylation (median PMR=0.54; range 0.17–3.7) was detected in the normal colorectal mucosa samples of seven (≤7%) cases with sporadic microsatellite unstable carcinoma (Figures 6a and 7). Higher levels of MLH1 methylation were found in the corresponding cancers of each of these individuals (median PMR=58.94; range 24.33–93.13; Figures 6 and 7a). The presence of allelic methylation was confirmed in all seven normal colorectal mucosa samples by cloning and sequencing of individual amplicons from the methylation specific PCR products, with some alleles showing partial methylation and others showing complete methylation (Figure 7b). No methylation was detected in their peripheral blood lymphocytes (data not shown), suggesting that methylation was somatically acquired and localized, as opposed to constitutional, such as that found in carriers of MLH1 epimutations.34, 35, 36, 37 In the tumours of each of these seven cases, at least one additional gene within 3p22 was concomitantly methylated with MLH1 (Figure 6). In five cases, the tumours were BRAF V600E mutant and in four the tumours were CIMP+ (Table 6 ). Therefore, to determine if additional genes within 3p22 were also methylated in the normal colonic mucosa of these microsatellite unstable cases, and if the BRAF V600E mutation might have preceded this epigenetic event, real-time methylation-specific PCR of the other four 3p22 loci and sensitive real-time allele-specific PCR of BRAF were performed. Indeed, low levels of methylation of additional 3p22 genes were found in the normal colonic mucosa of five of the seven cases (Figure 6). The finding of dense methylation affecting a small number of alleles was confirmed by clonal sequencing of the real-time methylation-specific PCR products (Figure 8). Furthermore, the presence of the BRAF V600E mutation was detected in the normal colonic mucosa of four of the latter five cases (Figure 6 and Supplementary Figure 2), each with correspondingly BRAF mutant, CIMP+ tumours (Table 6). In contrast, no methylation or BRAF mutation was detected in the normal colonic mucosa of seven microsatellite stable cases matched by gender and age (±5 years) whose tumours were BRAF wild type and devoid of 3p22 methylation (Figure 6). These data show that low-level methylation of 3p22 genes and the BRAF V600E mutation were more common in the normal colorectal mucosa samples of individuals who had cancers showing the same molecular profile. Interestingly, although none of the seven microsatellite unstable colorectal cancer cases with MLH1 methylation in their normal colonic mucosa had a synchronous colorectal cancer, the four cases with combined methylation of additional 3p22 genes and the BRAF V600E mutation in their normal colorectal mucosa did have a clinical history of hyperplastic polyps, and three of these additionally presented with serrated and/or conventional polyps (Table 6).
We extended our study of methylation of 3p22 genes flanking MLH1 and the presence of the BRAF V600E mutation in normal colorectal mucosa to determine the frequency of this event in colorectal cancer cases and to elucidate the chronology between these genetic and epigenetic events. To this end, the normal colorectal mucosa samples from 13 additional individuals who had cancers with dense regional 3p22 methylation and concomitant BRAF V600E mutation were screened. Methylation was detected in just three of these normal colonic mucosa samples, and this was confined to the ITGA9 and/or PLCD1 promoters, but no evidence for the BRAF V600E mutation was found (Figure 6). Similarly, low-level methylation was rare and confined to ITGA9 or PLCD1, and the BRAF mutation was absent among 13 age- and gender-matched cases whose colorectal cancers did not have regional 3p22 methylation and were BRAF wild type, as well as the 21 individuals without neoplasia (Figure 6). Thus, low levels of regional 3p22 methylation and BRAF V600E mutation appear to be infrequent in the normally appearing colonic mucosa, even when that mucosa is adjacent to a cancer showing high levels of these molecular features. These findings provided no evidence to suggest that either regional 3p22 methylation or BRAF mutation was precedent.
Discussion
This study of a large Australian cohort of sporadic colorectal cancers has confirmed that methylation of MLH1 occurs in a confined subset (10.1%) of colorectal neoplasia and correlates closely with the clinicopathological characteristics typically associated with microsatellite unstable cancers, including older age, female gender, proximal location, lower tumour stage, mucinous histology and high grade, as well as the key molecular features of BRAF V600E mutation and CIMP+.5, 33, 38, 39, 40, 41, 42 We found no evidence for an association between the MLH1 promoter germline SNP c.-93G>A genotype and an increased risk of MLH1 methylation or microsatellite instability in a case–control study of this cohort, arguing against a cis-acting role for this SNP in conferring susceptibility to methylation. In previous studies in which a positive association was found between the G>A genotype and microsatellite instability, either familial cases were retained in the cohort or the study group comprised early-onset cases,8, 9, 10, 11 suggesting that the genotype may be linked to founder mutations that give rise to familial or early-onset cancer phenotypes in these populations. Although in one study of a large colorectal cancer cohort, the c.-93G>A genotype was shown to be associated with MLH1 methylation, the BRAF V600E mutation as well as CIMP+ among sporadic microsatellite unstable cancers, nevertheless a stronger association between the G>A genotype was demonstrated among the microsatellite unstable cases with a positive family history.10 In our study cohort, cases with a significant family history and known carriers of germline mutations that confer a hereditary colorectal cancer syndrome were omitted, suggesting that the G>A SNP is not associated with an increased risk of MLH1 methylation or microsatellite instability among sporadic cases. Nevertheless, in sporadic endometrial and colorectal cancer populations in which an association with this SNP variant has been reported, these have been weak, with modest odds ratios.7 Thus, a minor elevation in the risk of MLH1 methylation or microsatellite instability observed in some cancer populations may not be replicated in others. This is in contrast to the c.-56C>T SNP (rs16906252) of the DNA repair gene MGMT, which correlates strongly with the presence of MGMT promoter methylation in both colorectal carcinoma and non-neoplastic tissues, illustrating that cis-acting elements can have an instrumental role in gene methylation.43, 44, 45 The lack of any association between MLH1 methylation and the c.-93G>A genetic variant in our cohort is consistent with the finding, instead, of a strong correlation between methylation of MLH1 and neighbouring genes within the contiguous 3p22 chromosomal region, arguing for a fundamental epigenetic basis to MLH1 inactivation in sporadic microsatellite unstable tumours.
We have extended our previous findings from a pilot study of colorectal cancers to this large cohort and confirmed that methylation of MLH1 and each of four nearby genes was strongly associated with methylation of each of the other genes within this region (Table 4). Furthermore, methylation of other 3p22 genes, AB002340, ITGA9, PLCD1 and DLEC1, individually or as a group of ≥3 of 5 genes, also correlated with most clinicopathological and molecular features that were strongly associated with MLH1-methylated colorectal carcinoma (Table 2), reinforcing the notion that methylation of 3p22 genes occurs concomitantly with MLH1 in a considerable subset of sporadic microsatellite unstable colorectal cancers. This allowed the colorectal cancers in the cohort to be dichotomized into two groups; positive and negative for regional 3p22 methylation, defined as methylation of 3–5 and 0–2 genes, respectively. This dichotomy is consistent with the criteria used by others for categorizing tumours, as exemplified by CIMP status,13, 14 facilitating analyses between regional 3p22 methylation and other clinicopathological or molecular features that are reported in a categorical manner. However, the present study now shows that regional 3p22 methylation was more frequent in BRAF V600E mutant colorectal cancers regardless of microsatellite stability status, such that methylation of multiple 3p22 genes is not restricted to microsatellite unstable cancers, as we previously reported.18 A small proportion of BRAF V600E mutant microsatellite stable cancers demonstrated concurrent methylation of 3p22 genes other than MLH1. Thus, it appears that methylation may spread stochastically across the 3p22 chromosomal domain, only giving rise to the microsatellite instability phenotype when methylation encompasses MLH1.
The molecular mechanism by which methylation of genes within this cluster occurs remains unknown. We have previously shown that the LRRFIP and GOLGA2 promoters are not prone to methylation in colorectal cancer.18 Thus, a simplistic linear model fails to explain the close association between methylation of the 3p22 gene cluster, suggesting that a higher degree of complexity is involved in epigenetic silencing, perhaps involving the three-dimensional structure of DNA. Nevertheless, long-range epigenetic silencing may provide some explanation for genes subject to methylation being refractory to reactivation by drugs that target repressive epigenetic modifications. It has previously been shown that the upregulation of MLH1 achieved in colorectal carcinoma cell lines by treatment with methyltransferase and deacetylase inhibitors is transient, with a gradual reversal to the silenced state following drug withdrawal,46 possibly because of heterochromatinization on a regional basis.
A novel finding in this study was the close correlation between methylation of the 3p22 genes, both individually and as a cluster of 3–5 together, and the CIMP+ phenotype. Regional 3p22 methylation markers may thus serve as an alternative set of markers to characterize CIMP status, providing further support for the previous recommendation that MLH1 should be included as one of the markers in the panel for the characterization of CIMP+.16 It was notable that CIMP+ and the BRAF V600E mutation were all independent predictors of regional 3p22 methylation in multivariate analysis, despite their strong associations with one another. This suggests that heterogeneity in genetic and epigenetic events may still underlie the development of a given subset of colorectal cancers with strong molecular and clinicopathological similarity. The fact that mucinous histology was also a significant predictor of 3p22 methylation is not entirely surprising, given that BRAF V600E mutation, CIMP+ and microsatellite instability were concordantly more frequent in mucinous colorectal cancers.40 Previous observations between the BRAF V600E mutation and methylation of multiple genes at distinct loci in conjunction with CIMP+ have been reported.14, 16, 47, 48 One other study has also reported the close association between long-range epigenetic silencing of the 2q14 region and CIMP+ in sporadic colorectal cancer.24 Taken together, the independent findings of long-range epigenetic silencing of both the 3p22 and 2q14 regions in the context of CIMP+ provide further support for a common mechanism governing epigenetic dysregulation that presents with the overlapping features of long-range epigenetic silencing and CIMP in the development of sporadic colorectal cancer. Our findings provide further evidence to suggest that these two epigenetic events are not independent, but represent a singular phenotype. The CIMP+ phenotype may thus be more appropriately conceptualized as the presence of areas of long-range methylation affecting several chromosomal regions, rather than the simultaneous methylation of discrete loci. However, this remains to be tested definitively in regions surrounding current diagnostic markers of CIMP+.
Finally, we show that methylation of the critical Deng-C region of MLH1 occurs infrequently in the apparently normal colonic mucosa of individuals with microsatellite unstable cancers, although at low levels. Furthermore, we show for the first time that methylation of flanking 3p22 genes can also occur at low levels in the normal colorectal mucosa of colorectal cancer cases. We consider it unlikely that these findings occurred as a consequence of contamination of the normal tissue with tumour cells, given that the normal colorectal mucosa samples were taken as far as possible (>10 cm) from the cancer tissue and the 3p22 methylation profile in some normal colorectal mucosa samples were different from the paired carcinomas. Previous studies have similarly shown that a given gene methylated within the normal mucosa is usually methylated at lower levels than that seen in an adjacent cancer.17, 49 Although these colorectal mucosa samples were macroscopically normal, it is conceivable that they contained aberrant cryptic foci. Indeed, the presence of the BRAF V600E mutation,50, 51 as well as methylation of numerous genes including MLH1,52, 53, 54 have previously been identified in these benign lesions. Nevertheless, the occurrence of these molecular event may represent a ‘field defect’ that underlies the development of metachronous colorectal neoplasia in some patients.55 Mechanistically, it has been suggested that the low level and mosaic patterns of methylation can provide a nidus of methylation, around which subsequent methylation can spread through stimulation of de novo methyltransferase activity.56 An interesting observation was that four individuals in whom concomitant 3p22 methylation occurred in conjunction with the BRAF V600E mutation in their apparently normal colonic mucosa had each developed hyperplastic polyps, and in some cases additional adenomas. Although these individuals did not present with an additional colorectal carcinoma, the finding of pre-neoplastic lesions is consistent with a common molecular mechanism underlying their phenotype. Unfortunately, no tissue was available from these polyps to determine if they demonstrated a similar molecular profile to support this notion. However, other groups have demonstrated extensive methylation of multiple genes in conjunction with the BRAF V600E mutation in the serrated polyps of colorectal cancer cases,47, 57 as well as in the normal colonic mucosa of individuals with hyperplastic polyposis or colorectal cancer, suggesting that in rare cases these molecular defects may serve as a field defect in colorectal neoplasia.57, 58
In summary, our findings show that concomitant methylation of the 3p22 region is a consistent finding in CIMP+ colorectal cancers, and occurs predominantly, but not exclusively in microsatellite unstable tumours. Furthermore, we demonstrate that low-level methylation of MLH1 and other 3p22 genes, with the concurrent BRAF V600E mutation, can occur in the normal colonic mucosa of colorectal cancer cases, although rarely, and that this may predispose to the development of neoplasia of the serrated pathway, including hyperplastic polyps, serrated adenomas and sporadic microsatellite unstable/CIMP+ colorectal carcinoma.
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Acknowledgements
We thank Deborah Packham, Chau-To Kwok, Su Ku, Vita Ap Lin, Robert Rapkins and Luke Hesson for technical assistance. This research was supported by the Cancer Council NSW and the Cancer Institute NSW. JJW was the recipient of an Australian Endeavour International Postgraduate Research Scholarship (EIPRS).
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Wong, JL., Hawkins, N., Ward, R. et al. Methylation of the 3p22 region encompassing MLH1 is representative of the CpG island methylator phenotype in colorectal cancer. Mod Pathol 24, 396–411 (2011). https://doi.org/10.1038/modpathol.2010.212
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DOI: https://doi.org/10.1038/modpathol.2010.212
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