Department of Thoracic, Endocrine Surgery and Oncology, Institute of Biomedical Sciences, Tokushima University Graduate School, Tokushima, Japan.
Department of Oncological Medical Services, Institute of Biomedical Sciences, Tokushima University Graduate School, Tokushima, Japan.
Mol Carcinog. 2020 Jan;59(1):24-31. doi: 10.1002/mc.23125. Epub 2019 Oct 3.
Hexavalent chromium is recognized as a human carcinogen. Our previous studies revealed that lung cancer (LC) in chromate-exposed workers (chromate LC) had molecular features of frequent microsatellite instability (MSI), repression of MLH1 level, and aberrant DNA methylation of several tumor-suppressor genes, including MLH1. In the present study, we quantitatively investigated MLH1-promoter methylation status using bisulfite pyrosequencing of paired tumorous/nontumorous tissues from chromate and nonchromate LCs to determine the effect of chromate exposure on MLH1-promoter methylation. The methylation level of MLH1 promoter was significantly higher in chromate LC tumors (P < .001) than nonchromate LC tumors and, among chromate LC, significantly higher in tumorous tissue than nontumorous tissue (P = .004). Moreover, the methylation level of MLH1 promoter in normal lung tissue tended to be higher in chromate LC than nonchromate LC (P = .062). In addition, LC with reduced levels of MLH1 showed significantly higher methylation levels of MLH1 promoter than LC exhibiting normal MLH1 levels (P = .019). Moreover, immunohistochemical analyses determined that levels of SUV39H1, an H3K9me2-related methyltransferase, were higher in chromate LC than nonchromate LC (P = .076). Furthermore, we evaluated three DNA double-strand break-repair genes (MRE11, RAD50, and DNA-PKcs) as possible targets of MSI by fragment-length polymorphism analysis, revealing the mutation frequency of RAD50 as significantly higher in chromate LC than nonchromate LC (P = .047). These results suggest that chromate exposure might induce MLH1 hypermethylation in LC as a mechanism of chromate-induced carcinogenesis.
六价铬被认为是一种人类致癌物质。我们之前的研究表明,接触铬酸盐的工人的肺癌(LC)(铬酸盐 LC)具有频繁的微卫星不稳定性(MSI)、MLH1 水平受抑制和几个肿瘤抑制基因(包括 MLH1)的异常 DNA 甲基化等分子特征。在本研究中,我们使用焦磷酸测序法定量检测配对的肿瘤/非肿瘤组织中 MLH1 启动子的甲基化状态,以确定铬酸盐暴露对 MLH1 启动子甲基化的影响。铬酸盐 LC 肿瘤中 MLH1 启动子的甲基化水平显著高于非铬酸盐 LC 肿瘤(P<.001),且在铬酸盐 LC 中,肿瘤组织显著高于非肿瘤组织(P=.004)。此外,铬酸盐 LC 中的正常肺组织中 MLH1 启动子的甲基化水平也倾向于高于非铬酸盐 LC(P=.062)。此外,MLH1 水平降低的 LC 中 MLH1 启动子的甲基化水平显著高于 MLH1 水平正常的 LC(P=.019)。此外,免疫组化分析确定,铬酸盐 LC 中 SUV39H1(一种与 H3K9me2 相关的甲基转移酶)的水平高于非铬酸盐 LC(P=.076)。此外,我们通过片段长度多态性分析评估了三个 DNA 双链断裂修复基因(MRE11、RAD50 和 DNA-PKcs)作为 MSI 的可能靶点,发现 RAD50 的突变频率在铬酸盐 LC 中显著高于非铬酸盐 LC(P=.047)。这些结果表明,铬酸盐暴露可能会导致 LC 中 MLH1 过度甲基化,作为铬酸盐诱导致癌作用的机制。
