Investigation of the miR16-1 (C > T) + 7 Substitution in Seven Different Types of Cancer from Three Ethnic Groups.

Background. MicroRNAs are a type of small noncoding RNA molecules that have been shown to control gene expression in eukaryotes. Aberrant expression and alteration of miRNAs may be responsible for human diseases including cancer. An miR16-1 (C > T) + 7 gene mutation has been previously found in familial chronic lymphocytic leukemia patients, one of which reported a family history of breast cancer. miR16-1 regulates the expression of bcl-2, which is important in retinoblastoma, and is located in a genomic region that is frequently lost in nasopharyngeal and hepatocellular carcinomas (HCCs). Therefore, miR16-1 may be potentially important in the etiology of several solid tumors. To understand the power of the miR16-1 (C > T) + 7 mutation as a prognostic and diagnostic risk factor, we investigated the mutation in patients with seven different types of cancer including 188 with breast, 102 with ovarian, and 22 nasopharyngeal carcinomas, 96 HCC, 872 chronic myeloid leukemia (CML), 39 chronic lymphocytic leukemia (CLL), and 46 retinoblastoma cases from three different ethnic groups and of hereditary and sporadic etiology. Methods. 5'Nuclease TaqMan SNP genotyping assay was used to detect the miR16-1 gene C > T substitution. Results. The miR16-1 (C > T) + 7 substitution was not detected in any of the groups studied. Conclusions. Considering the large scale of our study, the representation of different ethnicities and levels of hereditary risk, we conclude that the miR-16-1 (C > T) + 7 mutation is not a good diagnostic or prognostic indicator of risk for the cancers tested.

Effect of adjuvant chemotherapy on integrity of free serum DNA in patients with breast cancer.

It is not known how chemotherapy-induced cell death influences the size distribution of circulating free DNA (cf-DNA) in serum or plasma of cancer patients. In the present study, we investigated the integrity of cf-DNA during adjuvant systemic therapy in patients (n= 41) with invasive breast cancer. Sera taken at the beginning and the end of the adjuvant chemotherapy were comparatively analyzed for the integrity of cf-DNA. The assay was based on quantification of shorter and longer fragments representing apoptotic or non-apoptotic DNA from abundant genomic ALU repeats by quantitative real-time PCR. The ratio of longer to shorter fragments showed the integrity of free serum DNA. During chemotherapy, in half of the patients (51.2%), total DNA levels increased, but decreased in the other half. The distribution of the DNA integrity in the whole patient group after the systemic therapy (median 0.31) did not significantly differ from that at the beginning (median 0.29, P= 0.39). However, in the subgroups, the variation of the DNA integrity was related to the course of the total DNA level. In the subgroup with an increasing DNA level, the median DNA integrity was elevated from 0.27 to 0.39 (P= 0.005), whereas in the group with a decrease it declined from 0.34 to 0.28 (P= 0.044). Our results show that longer fragments released from non-apoptotic cells are the main contributors to increasing DNA levels during adjuvant systemic therapy. This information might be helpful in evaluating the response of patients to adjuvant systemic therapy.

Size distribution of circulating cell-free DNA in sera of breast cancer patients in the course of adjuvant chemotherapy.

BACKGROUND: The integrity of circulating cell-free DNA (cf-DNA) in serum or plasma appears to be of diagnostic and prognostic value in cancer. Here, we investigated the dynamics of serum DNA levels and the size distribution of cf-DNA during adjuvant chemotherapy of patients with breast cancer (n=73). METHODS: By evaluating sera taken at the beginning and the end of the adjuvant chemotherapy, variations of serum DNA levels and the size distribution were analyzed, based on quantification of shorter apoptotic and longer non-apoptotic fragments from abundant genomic ALU fragments amplified by quantitative real-time PCR. RESULTS: The mean DNA level did not change significantly during chemotherapy. However, individual cases revealed considerable variation in the amount of serum DNA. It increased in 43.8% of the patients, whereas it decreased in the remaining majority (56.2%). By calculating a "coefficient of variation" (both decrease and increase) in the level of total DNA and non-apoptotic DNA fragments, we compared the values at the beginning and the end of the therapy. For total DNA, the range was between 1.02- and 26-fold (mean 3.76-fold), whereas for non-apoptotic fragments it ranged from 1.01- to 73-fold (mean 6.9-fold) (p=0.033). In accordance with these findings, the integrity of serum DNA was higher in patients with increasing DNA levels and vice versa. CONCLUSIONS: Our findings suggest that non-apoptotic fragments contribute to a higher degree to the change of the DNA level during adjuvant chemotherapy.