The potential of BORIS detected in the leukocytes of breast cancer patients as an early marker of tumorigenesis.

PURPOSE: Brother of the regulator of imprinted sites (BORIS) is a novel member of the cancer-testis antigen gene family. These genes are normally expressed only in spermatocytes but abnormally activated in different malignancies, including breast cancer. The aim of this study was to investigate the expression of BORIS in the leukocytes of breast cancer patients and the correlation between BORIS levels and clinical/pathologic variables. EXPERIMENTAL DESIGN: Leukocytes were obtained from whole blood of 87 breast cancer patients and 52 donors not diagnosed with cancer. BORIS protein was detected in leukocytes by immunohistochemical staining; the immunoreactivity score (IRS) of each sample was determined. Additionally, BORIS expression was assessed by Western blot analysis and real-time reverse transcription-PCR. RESULTS: We describe significantly high levels of BORIS (IRS = 4.25 +/- 0.034) in a subpopulation of leukocytes, the neutrophil polymorphonuclear granulocytes, in 88.5% of breast cancer patients. Increased IRS for BORIS in these patients correlated with increased tumor size. In comparison, 19.2% samples from the control group were BORIS positive with only very low levels of BORIS (IRS = 0.25 +/- 0.009). CONCLUSION: We report here the novel finding of BORIS expression in polymorphonuclear granulocytes of breast cancer patients. This tumor-related occurrence is a phenomenon not observed in donors with injuries and immune and inflammatory diseases. Detection of BORIS in a high proportion of patients with various types of breast tumors indicates that BORIS can be a valuable early blood marker of breast cancer. We conclude that BORIS represents a new class of cancer biomarkers different from those currently used in medical practice.

Heightened expression of CTCF in breast cancer cells is associated with resistance to apoptosis.

CTCF is a candidate tumor suppressor gene encoding a multifunctional transcription factor. Surprisingly for a tumor suppressor, the levels of CTCF in breast cancer cell lines and tumors were found elevated compared with breast cell lines with finite life span and normal breast tissues. In this study, we aimed to investigate the possible cause for this increase in CTCF content and in particular to test the hypothesis that up-regulation of CTCF may be linked to resistance of breast cancer cells to apoptosis. For this purpose, apoptotic cell death was monitored following alterations of CTCF levels induced by transient transfection and conditional knockdown of CTCF in various cell lines. We observed apoptotic cell death in all breast cancer cell lines examined following CTCF down-regulation. In addition, overexpression of CTCF partially protected cells from apoptosis induced by overexpression of Bax or treatment with sodium butyrate. To elucidate possible mechanisms of this phenomenon, we used a proteomics approach and observed that levels of the proapoptotic protein, Bax, were increased following CTCF down-regulation in MCF7 cells. Taken together, these results suggest that in some cellular contexts CTCF shows antiapoptotic characteristics, most likely exerting its functions through regulation of apoptotic genes. We hypothesize that CTCF overexpression may have evolved as a compensatory mechanism to protect breast cancer cells from apoptosis, thus providing selective survival advantages to these cells. The observations reported in this study may lead to development of therapies based on selective reduction of CTCF in breast cancer cells.

CTCF regulates growth and erythroid differentiation of human myeloid leukemia cells.

CTCF is a transcription factor and a candidate tumor suppressor that contains a DNA-binding domain composed of 11 zinc fingers. We reported previously that CTCF is differentially regulated during differentiation of human myeloid leukemia cells. In this study we aimed to investigate the role of CTCF in myeloid cell differentiation. A human cell line, K562, that can be chemically induced to differentiate into various hematopoietic lineages was chosen as a model system for this study. Several K562 cell lines with constitutive and conditional expression of CTCF have been generated. By using these model systems we demonstrated that: (i) ectopic expression of CTCF in K562 cells led to growth retardation and promotion of differentiation into the erythroid lineage; (ii) CTCF knock-down significantly inhibited differentiation of K562 cells into erythroid lineage; (iii) differentiation of K562 into the megakaryocytic lineage was not significantly affected; and (iv) down-regulation of MYC has been identified as one of the mechanisms by which CTCF promotes erythroid differentiation. Taken together our results demonstrate that CTCF is involved in the control of myeloid cell growth and differentiation.