After we observed the augmentation of in vitro TAM sensitivity by CHO10 in HER2-overexpressing TAM-resistant breast cancer cells, the in vivo anti-tumor effects of CHO10 were examined. SK-BR-3 or BT474 cells were subcutaneously injected into nude
mice, but no tumor growth was observed. Therefore, we attempted to use two other HER2-positive cancer cell lines, which were the DLD-1 colorectal adenocarcinoma cell line ( Bunn et al., 2001) and the NCI-H460 large cell lung cancer cell line ( LaBonte et al., 2011) to test the anti-tumor effect of CHO10 on in vivo xenograft tumors. When the NCI-H460 or DLD-1 subcutaneously implanted xenograft tumors reached a minimum of 250 mm3 (10 days after cell injection), the mice were randomly Cilengitide grouped (three mice per group) and treated with either the vehicle alone (control) or 1 mg/kg of CHO10 five times every
2 days. As shown in Fig. 5, the tumor volumes for the subjects treated with CHO10 were Anti-cancer Compound Library research buy significantly reduced in comparison to the untreated controls for both NCI-H460 and DLD-1 cells. These results suggest that CHO10 exhibited excellent anti-tumor effects in the mouse xenograft model. HER2 overexpression is detected in the cells of many types of tumors but is mainly found in breast, gastric, ovarian and lung cancers (Carpenter and Cohen, 1990 and Scholl et al., 2001). This trait is a problem in anticancer therapeutics for the following reasons: (1) HER2 forms dimers with itself or with other HER family members without ligand-binding. HER2 overexpression is the determinant in the dimerization process (Tzahar et al., 1996). Homo- and Bumetanide hetero-dimers of HER2 trigger tyrosine autophosphorylation and then augment intracellular signaling cascades, leading to cell proliferation and tumorigenesis
(Wolf-Yadlin et al., 2006). (2) HER2 overexpression reduces wild type p53 expression, which causes cancer cells to become resistant to chemo- and radio-therapy (Zheng et al., 2004). (3) HER2 overexpression induces resistance against anticancer drugs including trastuzumab (HER2 extracellular domain-targeting monoclonal antibody (mAb)), lapatinib (EGFR/HER2 dual TKI) and TAM (estrogen receptor antagonist) (Benz et al., 1993, Chung et al., 2002 and Valabrega et al., 2007). Therefore, the down-regulation of HER2 expression can be a good strategy in combination regimens with HER2-targeting anticancer drugs or HER2-mediated resistance-inducing drugs. HER2 overexpression is achieved by an uncontrolled transcription rate when the ESX transcription factor binds to both the HER2 promoter and Sur2 (Chang et al., 1997 and Asada et al., 2002). Dithiiranylmethyloxy azaxanthone, CHO10, inhibited the ESX–Sur2 interaction in a dose-dependent manner with a potency that was similar to 3 μM canertinib (Fig. 1A and B), which leads to a reduction of HER2 gene amplification and protein expression.