The poor prognosis of glioblastoma (GBM) routinely treated with ionizing radiation (IR) has been attributed to the relative radioresistance of glioma initiating cells (GIC). Other studies suggest that GIC are sensitive but the response is mediated by undefined factors in the microenvironment. GBM produce abundant transforming growth factor-β (TGFβ), a pleotropic cytokine that promotes effective DNA damage response. Consistent with this, radiation sensitivity, as measured by clonogenic assay, of cultured murine (GL261) and human (U251, U87MG) glioma cell lines, increased approximately 25% when treated with LY364947, a small molecule inhibitor of TGFβ type I receptor kinase, prior to irradiation. Mice bearing GL261 flank tumors treated with 1D11, a pan-isoform TGFβ neutralizing antibody, exhibited significantly increased tumor growth delay following IR. GL261 neurosphere cultures were used to evaluate GIC. LY364947 had no effect on primary or secondary neurosphere-forming capacity. IR decreased primary neurosphere formation by 28%, but did not reduce secondary neurosphere formation. In contrast, LY364947 prior to IR decreased primary neurosphere formation by 75% and secondary neurosphere formation by 68%. Notably, GL261 neurospheres produced 3.7-fold more TGFβ per cell compared to traditional culture, suggesting that TGFβ production by GIC promotes the DNA damage response and self-renewal and creates microenvironment mediated resistance. Consistent with this, LY364947 treatment in irradiated GL261 neurosphere-derived cells decreased DNA damage responses, H2AX and p53 phosphorylation, and induction of self-renewal signals, Notch1 and CXCR4. These data motivate the use of TGFβ inhibitors with radiation to improve therapeutic response in GBM patients.
ARC (Apoptosis Repressor with Caspase recruitment domain) inhibits both death receptor- and mitochondrial/ER-mediated pathways of apoptosis. While expressed mainly in terminally differentiated cells, ARC is markedly upregulated in a variety of human cancers, where its potential contributions have not yet been defined. In this study, we provide evidence of multiple critical pathophysiological functions for ARC in breast carcinogenesis. In the polyoma middle T-antigen (PyMT) transgenic mouse model of breast cancer, where endogenous ARC is strongly upregulated, deletion of the ARC-encoding gene nol3 decreased primary tumor burden without affecting tumor onset or multiplicity. More notably, ARC deficiency also limited tumor cell invasion and the number of circulating cancer cells, markedly reducing the number of lung metastases. Conversely, ectopic overexpression of ARC in a PyMT-derived metastatic breast cancer cell line increased invasion in vitro and lung metastasis in vivo. We confirmed these results in a humanized orthotopic model based on MDA-MB-231-derived LM2 metastatic breast cancer cells, in which RNAi-mediated knockdown of ARC levels was demonstrated to reduce tumor volume, local invasion, and lung metastases. Lastly, we found that endogenous levels of ARC conferred chemoresistance in primary tumors as well as invading cell populations. Our results establish that ARC promotes breast carcinogenesis by driving primary tumor growth, invasion and metastasis as well as by promoting chemoresistance in invasive cells.
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