The retinoblastoma tumor suppressor modifies the therapeutic response of breast cancer
Emily E. Bosco, Ying Wang, Huan Xu, Jack T. Zilfou, Karen E. Knudsen, Bruce J. Aronow, Scott W. Lowe, Erik S. Knudsen
Emily E. Bosco, Ying Wang, Huan Xu, Jack T. Zilfou, Karen E. Knudsen, Bruce J. Aronow, Scott W. Lowe, Erik S. Knudsen
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Research Article Oncology

The retinoblastoma tumor suppressor modifies the therapeutic response of breast cancer

Abstract

The retinoblastoma tumor suppressor (RB) protein is functionally inactivated in the majority of human cancers and is aberrant in one-third of all breast cancers. RB regulates G1/S-phase cell-cycle progression and is a critical mediator of antiproliferative signaling. Here the specific impact of RB deficiency on E2F-regulated gene expression, tumorigenic proliferation, and the response to 2 distinct lines of therapy was investigated in breast cancer cells. RB knockdown resulted in RB/E2F target gene deregulation and accelerated tumorigenic proliferation, thereby demonstrating that even in the context of a complex tumor cell genome, RB status exerts significant control over proliferation. Furthermore, the RB deficiency compromised the short-term cell-cycle inhibition following cisplatin, ionizing radiation, and antiestrogen therapy. In the context of DNA-damaging agents, this bypass resulted in increased sensitivity to these agents in cell culture and xenograft models. In contrast, the bypass of antiestrogen signaling resulted in continued proliferation and xenograft tumor growth in the presence of tamoxifen. These effects of aberrations in RB function were recapitulated by ectopic E2F expression, indicating that control of downstream target genes was an important determinant of the observed responses. Specific analyses of an RB gene expression signature in 60 human patients indicated that deregulation of this pathway was associated with early recurrence following tamoxifen monotherapy. Thus, because the RB pathway is a critical determinant of tumorigenic proliferation and differential therapeutic response, it may represent a critical basis for directing therapy in the treatment of breast cancer.

Authors

Emily E. Bosco, Ying Wang, Huan Xu, Jack T. Zilfou, Karen E. Knudsen, Bruce J. Aronow, Scott W. Lowe, Erik S. Knudsen

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Figure 4

RB is necessary for sensitivity to antiestrogen therapy and long-term growth arrest.

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RB is necessary for sensitivity to antiestrogen therapy and long-term gr...
(A) Lysates from wild-type MCF7, T47D, and Zr-75-1 cells were immunoblotted for the expression levels of RB, RB phospho-Ser780, cyclin D1, and p16INK4a. Lamin B served as a loading control, while lysates from U2OS and SaOS2 cells were included as controls for RB and p16INK4a expression, respectively. (B) MCF7 donor 1 and siRb28 clones were cultured in media containing FBS, CDT, CDT/Tam, or CDT/ICI for 3 days and were BrdU labeled for the final 10 hours of culture. Cells were then fixed, and BrdU immunofluorescence was performed and scored. A 2-tailed Student’s t test assuming unequal variances was utilized to determine significance. (C) T47D (left) and Zr-75-1 (right) donor and siRb88 cells were cultured, BrdU labeled, and scored as described for B. Statistical tests were performed as described for B. (D) MCF7 donor 1 or siRb28 cells were seeded at 3 × 105, and cell growth assays were performed for 9 days while cells were cultured in CDT/Tam and counted every 3 days. (E) T47D (left) and Zr-75-1 (right) donor and siRb88 cells were seeded at 3 × 105, and cell growth assays were performed as described for D. (F) When xenograft tumors (as in Figure 3E) reached 100–120 mm3, mice were treated with Tam (E2 pellet was removed and Tam pellet was added). Tumor size of the Tam-treated animals was monitored by calipers. (G) Final tumor weights of all tumors represented in F upon excision.