Establishment of primary patient-derived xenografts of palliative TURP specimens to study castrate-resistant prostate cancer.

BACKGROUND: Fresh patient specimens of castrate-resistant prostate cancer (CRPC) are invaluable for studying tumor heterogeneity and responses to current treatments. They can be used for primary patient-derived xenografts (PDXs) or serially transplantable PDXs, but only a small proportion of samples grow successfully. To improve the efficiency and quality of PDXs, we investigated the factors that determine the initial engraftment of patient tissues derived from TURP specimens. METHODS: Fresh tissue was collected from castrate patients who required a TURP for urinary symptoms. Tissue was grafted under the renal capsule of immune-compromised mice for up to 14 weeks. The abundance of cancer in ungrafted and grafted specimens was compared using histopathology. Mice were castrated or implanted with testosterone pellets to determine the androgen-responsiveness of CRPC PDXs from TURP tissue. RESULTS: Primary PDXs were successfully established from 7 of 10 patients that underwent grafting. Of the 112 grafts generated from these 10 patients, 21% contained cancer at harvest. Grafts were most successful when the original patient specimens contained high amounts of viable cancer, defined as samples with (i) at least 50% cancer cells, (ii) no physical damage, and (iii) detectable Ki67 expression. PDX grafts survived in castrated hosts and proliferated in response to testosterone, confirming that they were castrate resistant but androgen-responsive. CONCLUSIONS: Primary PDXs of CRPC can be established from TURP specimens with modest success. The take rate can be increased if the original tissues contain sufficient numbers of actively proliferating cancer cells. Selecting specimens with abundant viable cancer will maximize the rate of engraftment and increase the efficiency of establishing PDXs that can be serially transplanted.

Primary culture and propagation of human prostate epithelial cells.

Basic and translational (or preclinical) prostate cancer research has traditionally been conducted with a limited repertoire of immortalized cell lines, which have homogeneous phenotypes and have adapted to long-term tissue culture. Primary cell culture provides a model system that allows a broader spectrum of cell types from a greater number of patients to be studied, in the absence of artificially induced genetic mutations. Nevertheless, primary prostate epithelial cell culture can be technically challenging, even for laboratories experienced in immortalized cell culture. Therefore, we provide methods to isolate and culture primary epithelial cells directly from human prostate tissue. Initially, we describe the isolation of bulk epithelial cells from benign or tumor tissues. These cells have a predominantly basal/intermediate phenotype and co-express cytokeratin 8/18 and high molecular weight cytokeratins. Since prostatic stem cells play a major role in disease progression and are considered to be a therapeutic target, we also describe a prospective approach to specifically isolate prostatic basal cells that include both stem and transit-amplifying basal populations, which can be studied independently or subsequently differentiated to supply luminal cells. This approach allows the study of stem cells for the development of new therapeutics for prostate cancer.

A preclinical xenograft model of prostate cancer using human tumors.

Most cases of prostate cancer are now diagnosed as moderate-grade localized disease. These tumor specimens are important tools in the discovery and translation of prostate cancer research; however, unlike more advanced tumors, they are notoriously difficult to grow in the laboratory. We developed a system for efficiently xenografting localized human prostate cancer tissue, and we adapted this protocol to study the interactions between the specific subsets of epithelial and stromal cells. Fresh prostate tissues or isolated epithelial cells are recombined with mouse seminal vesicle mesenchyme (SVM) and grafted under the renal capsule of immunodeficient mice for optimum growth and survival. Alternatively, mouse mesenchyme can be replaced with human prostate fibroblasts in order to determine their contribution to tumor progression. Grafts can be grown for several months to determine the effectiveness of novel therapeutic compounds when administered to host mice, thereby paving the way for personalizing the treatment of individual prostate cancers.