The role of DNA methylation in the development of colorectal neoplasia

Wong, Justin Jong Leong, Medical Sciences, Faculty of Medicine, UNSW

January 2008

DNA methylation is increasingly recognised as a significant epigenetic event that may initiate and drive the process of neoplasia in humans. In the colon, DNA methylation of key genes is common in a subset of colorectal cancers. The extent to which DNA methylation at various genes contributes to initiation of colorectal neoplasms is less clear. This study sought to clarify the biological and clinicopathological significance of methylation of various genes in the development of sporadic and familial colorectal neoplasia. Quantitative methylation-specific PCR (qMSP) assays (capable of detecting down to a measureable proportion of 0.1% of the total input DNA) were developed to determine the presence of CpG methylation at a given gene. Methylation of MLH1-C was found in the apparently normal mucosa samples from seven of 104 (7%) of individuals with sporadic colorectal cancer (CRC) showing microsatellite instability (MSI). No methylation of MLH1-C was found in the biological samples of individuals with microsatellite stable (MSS) counterparts (n=131). MLH1-C methylation may be a field defect that predisposes to the development of sporadic colorectal neoplasia, particularly those demonstrating MSI. Methylation of three of five genes within the 3p22 region including AB002340, MLH1, ITGA9, PLCD1 and DLEC1 (regional 3p22 methylation) was found in 83% of sporadic MSI (n=86) and 12% of MSS cancers demonstrating BRAF V600E mutation (n=42). Regional 3p22 correlated strongly with CpG island methylator phenotype (CIMP), and other clinicopathological characteristics typical of CIMP. Thus, regional 3p22 methylation and CIMP may be overlapping phenomena. Regional 3p22 methylation and the BRAF V600E mutation were found in normal colonic mucosa of four individuals with sporadic MSI CRC, and these cases also had multiple synchronous serrated polyps. These molecular aberrancies may predispose some individuals to the development of metachronous serrated neoplasia. Germline epimutations of APC do not contribute towards the development of FAP, AFAP, or hyperplastic polyposis syndromes. However, APC methylation in normal colonic mucosa of these individuals may represent a field defect in the development of futher neoplasms. In conclusion, different patterns of DNA methylation in normal colonic mucosa may represent a field defect important in the development of different subtypes of colorectal neoplasia.

Field defect.

DNA methylation.

Colorectal neoplasia.

The role of DNA methylation in the development of colorectal neoplasia

Wong, Justin Jong Leong, Medical Sciences, Faculty of Medicine, UNSW

January 2008

DNA methylation is increasingly recognised as a significant epigenetic event that may initiate and drive the process of neoplasia in humans. In the colon, DNA methylation of key genes is common in a subset of colorectal cancers. The extent to which DNA methylation at various genes contributes to initiation of colorectal neoplasms is less clear. This study sought to clarify the biological and clinicopathological significance of methylation of various genes in the development of sporadic and familial colorectal neoplasia. Quantitative methylation-specific PCR (qMSP) assays (capable of detecting down to a measureable proportion of 0.1% of the total input DNA) were developed to determine the presence of CpG methylation at a given gene. Methylation of MLH1-C was found in the apparently normal mucosa samples from seven of 104 (7%) of individuals with sporadic colorectal cancer (CRC) showing microsatellite instability (MSI). No methylation of MLH1-C was found in the biological samples of individuals with microsatellite stable (MSS) counterparts (n=131). MLH1-C methylation may be a field defect that predisposes to the development of sporadic colorectal neoplasia, particularly those demonstrating MSI. Methylation of three of five genes within the 3p22 region including AB002340, MLH1, ITGA9, PLCD1 and DLEC1 (regional 3p22 methylation) was found in 83% of sporadic MSI (n=86) and 12% of MSS cancers demonstrating BRAF V600E mutation (n=42). Regional 3p22 correlated strongly with CpG island methylator phenotype (CIMP), and other clinicopathological characteristics typical of CIMP. Thus, regional 3p22 methylation and CIMP may be overlapping phenomena. Regional 3p22 methylation and the BRAF V600E mutation were found in normal colonic mucosa of four individuals with sporadic MSI CRC, and these cases also had multiple synchronous serrated polyps. These molecular aberrancies may predispose some individuals to the development of metachronous serrated neoplasia. Germline epimutations of APC do not contribute towards the development of FAP, AFAP, or hyperplastic polyposis syndromes. However, APC methylation in normal colonic mucosa of these individuals may represent a field defect in the development of futher neoplasms. In conclusion, different patterns of DNA methylation in normal colonic mucosa may represent a field defect important in the development of different subtypes of colorectal neoplasia.

Field defect.

DNA methylation.

Colorectal neoplasia.

Deficient expression of DNA repair enzymes in early progression to sporadic colon cancer

Facista, Alexander, Nguyen, Huy, Lewis, Cristy, Prasad, Anil, Ramsey, Lois, Zaitlin, Beryl, Nfonsam, Valentine, Krouse, Robert, Bernstein, Harris, Payne, Claire, Stern, Stephen, Oatman, Nicole, Banerjee, Bhaskar, Bernstein, Carol

January 2012

BACKGROUND:Cancers often arise within an area of cells (e.g. an epithelial patch) that is predisposed to the development of cancer, i.e. a "field of cancerization" or "field defect." Sporadic colon cancer is characterized by an elevated mutation rate and genomic instability. If a field defect were deficient in DNA repair, DNA damages would tend to escape repair and give rise to carcinogenic mutations.PURPOSE:To determine whether reduced expression of DNA repair proteins Pms2, Ercc1 and Xpf (pairing partner of Ercc1) are early steps in progression to colon cancer.RESULTS:Tissue biopsies were taken during colonoscopies of 77 patients at 4 different risk levels for colon cancer, including 19 patients who had never had colonic neoplasia (who served as controls). In addition, 158 tissue samples were taken from tissues near or within colon cancers removed by resection and 16 tissue samples were taken near tubulovillous adenomas (TVAs) removed by resection. 568 triplicate tissue sections (a total of 1,704 tissue sections) from these tissue samples were evaluated by immunohistochemistry for 4 DNA repair proteins. Substantially reduced protein expression of Pms2, Ercc1 and Xpf occurred in field defects of up to 10 cm longitudinally distant from colon cancers or TVAs and within colon cancers. Expression of another DNA repair protein, Ku86, was infrequently reduced in these areas. When Pms2, Ercc1 or Xpf were reduced in protein expression, then either one or both of the other two proteins most often had reduced protein expression as well. The mean inner colon circumferences, from 32 resections, of the ascending, transverse and descending/sigmoid areas were measured as 6.6 cm, 5.8 cm and 6.3 cm, respectively. When combined with other measurements in the literature, this indicates the approximate mean number of colonic crypts in humans is 10 million.CONCLUSIONS:The substantial deficiencies in protein expression of DNA repair proteins Pms2, Ercc1 and Xpf in about 1 million crypts near cancers and TVAs suggests that the tumors arose in field defects that were deficient in DNA repair and that deficiencies in Pms2, Ercc1 and Xpf are early steps, often occurring together, in progression to colon cancer.

"Colon cancer"

"DNA repair"

Pms2

Ercc1

Xpf

Ku86

"Genomic instability"

Cancerization

"Field defect"

Mutation