Genomic analysis of circulating cell-free DNA infers breast cancer dormancy.

Biomarkers in breast cancer to monitor minimal residual disease have remained elusive. We hypothesized that genomic analysis of circulating free DNA (cfDNA) isolated from plasma may form the basis for a means of detecting and monitoring breast cancer. We profiled 251 genomes using Affymetrix SNP 6.0 arrays to determine copy number variations (CNVs) and loss of heterozygosity (LOH), comparing 138 cfDNA samples with matched primary tumor and normal leukocyte DNA in 65 breast cancer patients and eight healthy female controls. Concordance of SNP genotype calls in paired cfDNA and leukocyte DNA samples distinguished between breast cancer patients and healthy female controls (P < 0.0001) and between preoperative patients and patients on follow-up who had surgery and treatment (P = 0.0016). Principal component analyses of cfDNA SNP/copy number results also separated presurgical breast cancer patients from the healthy controls, suggesting specific CNVs in cfDNA have clinical significance. We identified focal high-level DNA amplification in paired tumor and cfDNA clustered in a number of chromosome arms, some of which harbor genes with oncogenic potential, including USP17L2 (DUB3), BRF1, MTA1, and JAG2. Remarkably, in 50 patients on follow-up, specific CNVs were detected in cfDNA, mirroring the primary tumor, up to 12 yr after diagnosis despite no other evidence of disease. These data demonstrate the potential of SNP/CNV analysis of cfDNA to distinguish between patients with breast cancer and healthy controls during routine follow-up. The genomic profiles of cfDNA infer dormancy/minimal residual disease in the majority of patients on follow-up.

Circulating tumor cells and plasma DNA analysis in patients with indeterminate early or metastatic breast cancer.

BACKGROUND: Circulating tumor cells (CTCs) and tumor-specific alterations in cell-free plasma DNA can both be used as markers of prognosis in breast cancer. To date, there have been no studies that have compared these as markers for subclinical metastases in the follow-up of early breast cancer. In this study, we measured CTCs and plasma DNA in a published group of patients with multiple pulmonary nodules and indeterminate metastatic disease. PATIENTS & METHODS: A single blood sample for CTC and plasma DNA measurement was taken approximately 1.5 years after surgery from 19 women with histologically confirmed primary breast cancer and small pulmonary nodules. The CellSearch system was used to enrich and enumerate CTCs from peripheral blood. DNA was isolated from plasma and was analyzed by quantitative real-time PCR for DNA concentration, integrity and evidence of HER2 amplification. RESULTS: Of the 19 individuals with 'indeterminate' early or metastatic breast cancer, 17 demonstrated no evidence of CTCs, one had one CTC and one had three CTCs. The mean plasma DNA concentration was low and within the range detected in healthy female controls, as were the values for DNA integrity. HER2 amplification was detected in the plasma DNA in four of the eight patients with HER2 immunohistochemistry 3+ tumors, but there was no overlap with the two CTC-positive patients. None of the patients have relapsed thus far (median follow-up: 3.5 years). CONCLUSION: Both CTC and plasma DNA analyses together suggested that these patients had little evidence of metastatic disease. Future studies will be designed to assess the utility of these biomarkers in the follow-up of a larger number of women with breast cancer.