The oxidative DNA damage caused by oxygen free radicals is one of the most important mechanisms responsible for the initial steps of colorectal carcinogenesis. The oxidative stress can cause errors in the pairing of nitrogenous bases that form the DNA, allowing mutations in controlling genes of the cell cycle. The cells have a defense system represented by the DNA mismatch repair genes that correct the errors of matching prevent the development of DNA mutations. Few studies have evaluated the relationship between oxidative DNA damage and the tissue expression of mismatch repair genes.
AIM: The aim of the present study was evaluate the levels of oxidative DNA and the tissue expression of MLH1 mismatch repair gene in the cells of normal and neoplastic colonic mucosa of patients with colorectal cancer.
MATERIAL AND METHODS: Were studied 44 patients with diagnosis of colorectal adenocarcinoma. Were excluded patients with hereditary colorectal cancer, with colorectal cancer associate with inflammatory bowel diseases and those undergoing neoadjuvant radioquimiotherapy. To evaluate the levels of oxidative DNA damage was used the single cell gel electrophoresis (comet assay) evaluating 100 cells obtained from normal and neoplastic tissues. For the evaluation of the tissue expression of MLH1 gene was employed the technique of polymerase chain reaction in real time (RT-PCR) with primer specifically designed for MLH1 gene. The comparison among the levels of DNA oxidative stress and expression of MLH1 mismatch repair gene in normal and neoplastic tissues was done by Student t test adopting a significance level of 5% (p< 0.05).
RESULTS: The levels of oxidative DNA damage in tumor tissue were significantly higher when compared to the level of the normal tissue (p = 0.0001). The tissue expression of MLH1 mismatch repair gene in tumor tissue was significantly lower when compared to normal tissue (p=0.02).
CONCLUSION: The mismatch repair gene MLH1 are less expressed in tumor tissue and inversely related to levels of oxidative DNA damage.