Cyclin D1 overexpression enhances radiation-induced apoptosis and radiosensitivity in a breast tumor cell line.

Overexpression of cyclin D1, a G1 cell cycle regulator, is often found in many different tumor types, such as breast carcinoma and squamous cell carcinoma of the head and neck. The overexpression of this protein is, in several cases, associated with a poor prognosis. In this study, the effect of cyclin D1 on radiosensitivity was investigated in a breast tumor cell line, MCF7, containing a cyclin D1 gene construct under the control of a tetracycline-sensitive regulator. MCF7 cells cultured without tetracycline resulted in a 6-fold increase in the cyclin D1 protein. Cyclin D1-overexpressing MCF7 cells were more sensitive to ionizing radiation than the nonoverexpressing counterparts. The cyclin D1-overexpressing cells also exhibited a higher induction of apoptosis. Treatment with a dose of 5 Gy resulted in a rapid increase of p53 and p21 in the cyclin D1-overexpressing cells. Nonoverexpressing cells showed a more transient expression of these proteins after ionizing radiation. A pronounced G2-M block was observed in both cell lines. The cyclin D1-overexpressing cells were, however, released earlier from the block than the control cells. These data suggest that overexpression of cyclin D1 alters sensitivity toward ionizing radiation by modulating gamma-radiation-induced G2-M transition.

Cyclin A is a prognostic indicator in early stage breast cancer with and without tamoxifen treatment.

Overexpression of G1-S regulators cyclin D1 or cyclin A is frequently observed in breast cancer and is also to result in ligand-independent activation of oestrogen receptor in vitro. This might therefore, provide a mechanism for failure of tamoxifen treatment. We examined by immunohistochemical staining the effect of deregulation of these, and other cell cycle regulators on tamoxifen treatment in a group of 394 patients with early stage breast cancer. In univariate analysis, expression of cyclin A, Neu, Ki-67 index, and lack of OR expression were significantly associated with worse prognosis. When adjusted by the clinical model (for lymph node status, age, performance status, T-classification, grade, prior surgery, oestrogen receptor status and tamoxifen use), only overexpression of cyclin A and Neu were significantly associated with worse prognosis with hazard ratios of, respectively, 1.709 (P=0.0195) and 1.884 (P=0.0151). Overexpression of cyclin A was found in 86 out of the 201 OR-positive cases treated with tamoxifen, and was the only independent marker associated with worse prognosis (hazard ratio 2.024, P=0.0462). In conclusion, cyclin A is an independent predictor of recurrence of early stage breast cancer and is as such a marker for response in patients treated with tamoxifen.

Degradation of radioiodinated B cell monoclonal antibodies: inhibition via a FCgamma-receptor-II-mediated mechanism and by drugs.

Our aim is to treat patients with B cell malignancies with radioimmunotherapy using monoclonal antibodies (mAb) such as CD19, CD20 and CD22. In this study we investigated the rate of internalization and catabolism of these mAb. After 24 h at 37 degrees C, 20%-25% of initially cell-bound (125)I-CD19 mAb and (125)I-CD22 mAb was degraded in B cells, whereas almost no degredation occurred after binding of (125)I-CD20 mAb. For B cells expressing Fcgamma receptor II (FcgammaRII), isotype-dependent degradation was noted as the CD19 IgGl mAb showed an enhanced degradation rate compared to the switch variant IgG2a. The effect of various pharmaceutical agents that delay the internalization or subsequent degradation of mAb was evaluated. The degradation was inhibited most effectively by a combination of etoposide and vinblastine, resulting in accumulation of radioactivity in the target cell. Also the simultaneous application of CD20 or CD22 with (125)I-CD19 mAb or of CD20 with (125)I-CD22 mAb proved to be a potent inhibitor of the rapid degradation of these mAb, by inhibiting internalization via an FcgammaRII-mediated mechanism. Both methods of reducing the degradation of radioiodinated mAb are expected to prolong irradiation of malignant b cells and consequently result in an enhanced therapeutic effect in vivo.