Intra-tibial injection of human prostate cancer cell line CWR22 elicits osteoblastic response in immunodeficient rats

We investigated the utility of CWR22 human prostate cancer cells for modeling human metastatic prostate cancer, specifically their ability to induce bone formation following intra-tibial injections in the nude rat. Prostate cancer is unique in regard to its tropism for bone and ability to induce new bone formation. In contrast to humans, other mammalian species rarely develop prostatic cancer spontaneously upon aging and do not have the propensity for bone metastasis that is the hallmark of cancer malignancy in men. We chose human prostate cancer cell line CWR22 based on its properties, which closely resemble all of the features that characterize the early stages of prostatic cancer in human patients including slow growth rate, hormone dependence/independence and secretion of prostate-specific antigen. When CWR22 cells were injected directly into the proximal tibia of immunodeficient male rats, both osteoblastic and osteolytic features became evident after 4 to 6 weeks, with elevated levels of serum prostate-specific antigen. However, osteosclerosis dominates the skeletal response to tumor burden. Radiological and histological evidence revealed osteosclerotic lesions with trabeculae of newly formed bone lined by active osteoblasts and surrounded by tumor cells. Toward the end of the 7-week study, osteolytic bone lesions become more evident on X-rays. Paraffin and immunohistochemical evaluations revealed mature bone matrix resorption as evidenced by the presence of many tartrate resistant acid phosphatase positive multinucleated osteoclasts. We conclude that the CWR22 human prostate cell line used in an intra-tibial nude rat model provides a useful system to study mechanisms involved in osteoblastic and osteolytic bony metastases. This type of in vivo model that closely mimics all major features of metastatic disease in humans may provide a critical tool for drug development efforts focused on developing integrated systemic therapy targeting the tumor in its specific primary or/and metastatic microenvironments. In addition to targeting bone marrow stroma, this strategy will help to overcome classical drug resistance seen at the sites of prostate cancer metastasis to bones.