Transgenic IGF-IR overexpression induces mammary tumors with basal-like characteristics, whereas IGF-IR-independent mammary tumors express a claudin-low gene signature.

Molecular profiling has allowed a more precise classification of human cancers. With respect to breast cancer, this approach has been used to identify five subtypes; luminal A, luminal B, HER2-enriched, basal-like and claudin-low. In addition, this approach can be used to determine the type of tumor represented by particular cell lines or transgenic animal models. Therefore, this approach was utilized to classify the mammary tumors that develop in MTB-IGFIR transgenic mice. It was determined that the primary mammary tumors, which develop due to elevated expression of the type I insulin-like growth factor receptor (IGF-IR) in mammary epithelial cells, most closely resemble murine tumors with basal-like or mixed gene expression profiles and with human basal-like breast cancers. Downregulation of IGF-IR transgene in MTB-IGFIR tumor-bearing mice leads to the regression of most of the tumors, followed by tumor reappearance in some of the mice. These tumors that reappear following IGF-IR transgene downregulation do not express the IGF-IR transgene and cluster with murine mammary tumors that express a mesenchymal gene expression profile and with human claudin-low breast cancers. Therefore, IGF-IR overexpression in murine mammary epithelial cells induces mammary tumors with primarily basal-like characteristics, whereas tumors that develop following IGF-IR downregulation express a gene signature that most closely resembles human claudin-low breast tumors.

Reversibility and recurrence of IGF-IR-induced mammary tumors.

The type-I insulin-like growth factor receptor (IGF-IR) is frequently overexpressed in breast cancer and therapeutic agents targeting IGF-IR are currently in development. The ultimate success of anti-IGF-IR therapies will depend on the extent to which established tumors remain dependent upon IGF-IR signaling for sustained growth. To investigate the potential benefits and pitfalls of targeting IGF-IR, we used a doxycycline inducible mouse model of IGF-IR initiated breast cancer. We found that downregulation of IGF-IR results in tumor-size-dependent regression to an undetectable state. Partially regressed tumors almost always resumed growth in the absence of doxycycline and a proportion of tumors that regressed to an undetectable state ultimately recurred. This re-emergence of tumor growth in the absence of doxycycline was facilitated by IGF-IR-dependent and IGF-IR-independent mechanisms. Tumor escape from IGF-IR dependence was associated with an epithelial to mesenchymal transition and upregulation of transcriptional repressors of E-cadherin. These results suggest that tumors initiated by IGF-IR have the ability to become independent of this initiating oncogene, and IGF-IR independence is associated with characteristics consistent with an epithelial to mesenchymal transition.

Transgenic overexpression of IGF-IR disrupts mammary ductal morphogenesis and induces tumor formation.

Overexpression and hyperactivation of the type I insulin-like growth factor receptor (IGF-IR) has been observed in human breast tumor biopsies. In addition, in vitro studies indicate that overexpression of IGF-IR is sufficient to transform cells such as mouse embryo fibroblasts and this receptor promotes proliferation and survival in breast cancer cell lines. To fully understand the function of the IGF-IR in tumor initiation and progression, transgenic mice containing human IGF-IR under a doxycycline-inducible MMTV promoter system were generated. Administration of 2 mg/ml doxycycline in the animals' water supply beginning at 21 days of age resulted in elevated levels of IGF-IR in mammary epithelial cells as detected by Western blotting and immunohistochemistry. Whole mount analysis of 55-day-old mouse mammary glands revealed that IGF-IR overexpression significantly impaired ductal elongation. Moreover, histological analyses revealed multiple hyperplasic lesions in the mammary glands of these 55-day-old mice. The formation of palpable mammary tumors was evident at approximately 2 months of age and was associated with increased levels of IGF-IR signaling molecules including phosphorylated Akt, Erk1/Erk2 and STAT3. Therefore, these transgenic mice provide evidence that IGF-IR overexpression is sufficient to induce mammary epithelial hyperplasia and tumor formation in vivo and provide a model to further understand the function of IGF-IR in mammary epithelial transformation.