PURPOSE: Adipocytes represent one of the most abundant constituents of the mammary gland. They are essential for mammary tumor growth and survival. Metabolically, one of the more important fat-derived factors ("adipokines") is adiponectin (APN). Serum concentrations of APN negatively correlate with body mass index and insulin resistance. To explore the association of APN with breast cancer and tumor angiogenesis, we took an in vivo approach aiming to study its role in the mouse mammary tumor virus (MMTV)-polyoma middle T antigen (PyMT) mammary tumor model. EXPERIMENTAL DESIGN: We compared the rates of tumor growth in MMTV-PyMT mice in wild-type and APN-null backgrounds. RESULTS: Histology and micro-positron emission tomography imaging show that the rate of tumor growth is significantly reduced in the absence of APN at early stages. PyMT/APN knockout mice exhibit a reduction in their angiogenic profile resulting in nutrient deprivation of the tumors and tumor-associated cell death. Surprisingly, in more advanced malignant stages of the disease, tumor growth develops more aggressively in mice lacking APN, giving rise to a larger tumor burden, an increase in the mobilization of circulating endothelial progenitor cells, and a gene expression fingerprint indicative of more aggressive tumor cells. CONCLUSIONS: These observations highlight a novel important contribution of APN in mammary tumor development and angiogenesis, indicating that APN has potent angio-mimetic properties in tumor vascularization. However, in tumors deprived of APN, this antiangiogenic stress results in an adaptive response that fuels tumor growth through mobilization of circulating endothelial progenitor cells and the development of mechanisms enabling massive cell proliferation despite a chronically hypoxic microenvironment.
PURPOSE: Adipocytes represent one of the most abundant constituents of the mammary gland. They are essential for mammary tumor growth and survival. Metabolically, one of the more important fat-derived factors ("adipokines") is adiponectin (APN). Serum concentrations of APN negatively correlate with body mass index and insulin resistance. To explore the association of APN with breast cancer and tumor angiogenesis, we took an in vivo approach aiming to study its role in the mouse mammary tumor virus (MMTV)-polyoma middle T antigen (PyMT) mammary tumor model. EXPERIMENTAL DESIGN: We compared the rates of tumor growth in MMTV-PyMT mice in wild-type and APN-null backgrounds. RESULTS: Histology and micro-positron emission tomography imaging show that the rate of tumor growth is significantly reduced in the absence of APN at early stages. PyMT/APN knockout mice exhibit a reduction in their angiogenic profile resulting in nutrient deprivation of the tumors and tumor-associated cell death. Surprisingly, in more advanced malignant stages of the disease, tumor growth develops more aggressively in mice lacking APN, giving rise to a larger tumor burden, an increase in the mobilization of circulating endothelial progenitor cells, and a gene expression fingerprint indicative of more aggressive tumor cells. CONCLUSIONS: These observations highlight a novel important contribution of APN in mammary tumor development and angiogenesis, indicating that APN has potent angio-mimetic properties in tumor vascularization. However, in tumors deprived of APN, this antiangiogenic stress results in an adaptive response that fuels tumor growth through mobilization of circulating endothelial progenitor cells and the development of mechanisms enabling massive cell proliferation despite a chronically hypoxic microenvironment.
Authors: Puneeth Iyengar; Terry P Combs; Shalin J Shah; Valérie Gouon-Evans; Jeffrey W Pollard; Chris Albanese; Louise Flanagan; Martin P Tenniswood; Chandan Guha; Michael P Lisanti; Richard G Pestell; Philipp E Scherer Journal: Oncogene Date: 2003-09-25 Impact factor: 9.867
Authors: Hashmat Sikder; David L Huso; Hong Zhang; Binghe Wang; Byungwoo Ryu; Sam T Hwang; Jonathan D Powell; Rhoda M Alani Journal: Cancer Cell Date: 2003-10 Impact factor: 31.743
Authors: Marianna B Ruzinova; Rebecca A Schoer; William Gerald; James E Egan; Pier Paolo Pandolfi; Shahin Rafii; Katia Manova; Vivek Mittal; Robert Benezra Journal: Cancer Cell Date: 2003-10 Impact factor: 31.743
Authors: Dai Fukumura; Akira Ushiyama; Dan G Duda; Lei Xu; Joshua Tam; V Krishna; K Chatterjee; Igor Garkavtsev; Rakesh K Jain Journal: Circ Res Date: 2003-10-02 Impact factor: 17.367
Authors: Rosa Anna DeFilippis; Hang Chang; Nancy Dumont; Joseph T Rabban; Yunn-Yi Chen; Gerald V Fontenay; Hal K Berman; Mona L Gauthier; Jianxin Zhao; Donglei Hu; James J Marx; Judy A Tjoe; Elad Ziv; Maria Febbraio; Karla Kerlikowske; Bahram Parvin; Thea D Tlsty Journal: Cancer Discov Date: 2012-07-09 Impact factor: 39.397
Authors: Stephen D Hursting; John Digiovanni; Andrew J Dannenberg; Maria Azrad; Derek Leroith; Wendy Demark-Wahnefried; Madhuri Kakarala; Angela Brodie; Nathan A Berger Journal: Cancer Prev Res (Phila) Date: 2012-10-03