Tumor-expressed adrenomedullin accelerates breast cancer bone metastasis.

INTRODUCTION: Adrenomedullin (AM) is secreted by breast cancer cells and increased by hypoxia. It is a multifunctional peptide that stimulates angiogenesis and proliferation. The peptide is also a potent paracrine stimulator of osteoblasts and bone formation, suggesting a role in skeletal metastases-a major site of treatment-refractory tumor growth in patients with advanced disease. METHODS: The role of adrenomedullin in bone metastases was tested by stable overexpression in MDA-MB-231 breast cancer cells, which cause osteolytic bone metastases in a standard animal model. Cells with fivefold increased expression of AM were characterized in vitro, inoculated into immunodeficient mice and compared for their ability to form bone metastases versus control subclones. Bone destruction was monitored by X-ray, and tumor burden and osteoclast numbers were determined by quantitative histomorphometry. The effects of AM overexpression on tumor growth and angiogenesis in the mammary fat pad were determined. The effects of AM peptide on osteoclast-like multinucleated cell formation were tested in vitro. A small-molecule AM antagonist was tested for its effects on AM-stimulated ex vivo bone cell cultures and co-cultures with tumor cells, where responses of tumor and bone were distinguished by species-specific real-time PCR. RESULTS: Overexpression of AM mRNA did not alter cell proliferation in vitro, expression of tumor-secreted factors or cell cycle progression. AM-overexpressing cells caused osteolytic bone metastases to develop more rapidly, which was accompanied by decreased survival. In the mammary fat pad, tumors grew more rapidly with unchanged blood vessel formation. Tumor growth in the bone was also more rapid, and osteoclasts were increased. AM peptide potently stimulated bone cultures ex vivo; responses that were blocked by small-molecule adrenomedullin antagonists in the absence of cellular toxicity. Antagonist treatment dramatically suppressed tumor growth in bone and decreased markers of osteoclast activity. CONCLUSIONS: The results identify AM as a target for therapeutic intervention against bone metastases. Adrenomedullin potentiates osteolytic responses in bone to metastatic breast cancer cells. Small-molecule antagonists can effectively block bone-mediated responses to tumor-secreted adrenomedullin, and such agents warrant development for testing in vivo.

The human Cyr61 gene is a transcriptional target of transforming growth factor beta in cancer cells.

Cyr61 is a multifunctional protein that can stimulate angiogenesis and tumor growth. Its expression by many cancers and breast cancers increases with tumor grade. Cyr61 is closely related to connective tissue growth factor, CTGF. Both proteins regulate skeletal development, suggesting that they could contribute to breast cancer metastases to bone, a process regulated by TGFbeta. We show that Cyr61 transcription is activated by TGFbeta and that the human Cyr61 promoter contains consensus sequences that bind Smad proteins. TGFbeta in the tumor microenvironment may stimulate cancer metastases to sites such as bone by increasing Cyr61 expression and secretion.

Tumor-derived interleukin-8 stimulates osteolysis independent of the receptor activator of nuclear factor-kappaB ligand pathway.

Bone is a common site of cancer metastasis. Breast, prostate, and lung cancers show a predilection to metastasize to bone. Recently, we reported that the chemokine interleukin 8 (IL-8) stimulates both human osteoclast formation and bone resorption. IL-8 mRNA expression was surveyed in a panel of human breast cancer lines MDA-MET, MDA-MB-231, MDA-MB-435, MCF-7, T47D, and ZR-75, and the human lung adenocarcinoma cell line A549. IL-8 mRNA expression was higher in cell lines with higher osteolytic potential in vivo. Human osteoclast formation was increased by MDA-MET or A549 cell-conditioned medium, but not by MDA-MB-231. Pharmacologic doses of receptor activator of nuclear factor-kappaB (RANK)-Fc or osteoprotogerin had no effect on the pro-osteoclastogenic activity of the conditioned medium; however, osteoclast formation stimulated by conditioned medium was inhibited 60% by an IL-8-specific neutralizing antibody. The data support a model in which tumor cells cause osteolytic bone destruction independently of the RANK ligand (RANKL) pathway. Tumor-produced IL-8 is a major contributor to this process. The role of secreted IL-8 isoforms was examined by surface-enhanced laser desorption/ionization time-of-flight mass spectrometry, which detected distinct IL-8 isoforms secreted by MDA-MET and MDA-231 cells, suggesting different pro-osteoclastogenic activities of the two IL-8-derived peptides. These data indicate that (a) osteoclast formation induced by MDA-MET breast cancer cells and A549 adenocarcinoma cells is primarily mediated by IL-8, (b) cell-specific isoforms of IL-8 with distinct osteoclastogenic activities are produced by tumor cells, and (c) tumor cells that support osteoclast formation independent of RANKL secrete other pro-osteoclastogenic factors in addition to IL-8.