Aberrant methylation of the cyclin D2 promoter in primary small cell, nonsmall cell lung and breast cancers.

DNA methylation alteration of several genes contributes to human tumorigenesis. Cyclin D2, a member of the D-type cyclins, is implicated in cell cycle regulation and malignant transformation. In our study, we examined the methylation status of the cyclin D2 promoter in small cell lung cancer (SCLC), nonsmall cell lung cancer (NSCLC), breast tumors and tumor cell lines. We observed that aberrant methylation of cyclin D2 was present in 32 of 56 (57%) SCLC cell lines, 7 of 32 (22%) SCLC tumor tissues; 25 of 61 (47%) NSCLC cell lines, 19 of 48 (40%) NSCLC tumor tissues; 18 of 30 (60%) breast tumor cell lines and 19 of 63 (30%) breast tumor tissues. Methylation was more frequent in the tumor cell lines compared to the primary breast and SCLC tumors (p = 0.007 and p = 0.001, respectively). Methylation was rare in the control tissue samples; 0 of 12 peripheral blood lymphocytes; 0 of 12 buccal epithelial cells; 0 of 18 nonmalignant lung tissues and 3 of 28 (11%) nonmalignant breast tissues. Promoter methylation correlated with loss of transcript by reverse transcription PCR (RT-PCR) in 9 of 11 (6 lung, 5 breast) tumor cell lines tested. Two cell lines that were not methylated also lacked expression, suggesting that other mechanisms of inactivation may be involved. Expression was restored by treatment with the demethylating agent, 5 aza 2' deoxycytidine, in all 9 methylated cell lines. Our results confirm earlier reports in breast cancer and indicate that aberrant methylation of cyclin D2 may contribute to the pathogenesis of the 2 major types of lung cancers.

Loss of heterozygosity in benign breast epithelium in relation to breast cancer risk.

The multistage model of breast carcinogenesis suggests that errors in DNA replication and repair generate diversity in the breast epithelium (the mutator phenotype), resulting in selection and expansion of premalignant clones with an acquired survival advantage. We measured loss of heterozygosity (LOH) in breast epithelial cells obtained by random fine-needle aspiration (FNA) biopsy from 30 asymptomatic women whose risk of breast cancer had been defined by the Gail model. Polymorphic microsatellite markers were selected on the basis of their relevance to breast cancer. Breast epithelium of 11 (37%) of 30 women had normal cytology, and that of 19 (63%) had proliferative cytology (eight with atypia and 11 without atypia). LOH was detected in two women with normal cytology and in 14 women (seven with atypia and seven without atypia) with proliferative cytology (P =.007). The frequency of LOH was associated with the cytological diagnosis, as well. The mean proportion (range) of informative markers demonstrating LOH was 0.02 (0-0.20) for the 11 women with normal cytology, as compared with 0.15 (0-0.50) for the 19 women with proliferative cytology (P =.02). Mean lifetime risk for developing breast cancer, as calculated by the Gail model, was 16.7% for women with no LOH compared with 22.9% for women with any LOH (P =.05). These observations support a multistage model of breast carcinogenesis where the initiating events are those that result in genomic instability. Accurate individualized breast cancer risk assessment may be possible based on molecular analysis of breast epithelial cells obtained by random FNA.