James O. Aspinall

Progress toward understanding the biology of prostate cancer has been slow due to the few animal research models available to study the spectrum of this uniquely human disease. To develop an animal model for prostate cancer, several lines of transgenic mice were generated by using the prostate-specific rat probasin promoter to derive expression of the simian virus 40 large tumor antigen-coding region. Mice expressing high levels of the transgene display progressive forms of prostatic disease that histologically resemble human prostate cancer, ranging from mild intraepithelial hyperplasia to large multinodular malignant neoplasia. Prostate tumors have been detected specifically in the prostate as early as 10 weeks of age. Immunohistochemical analysis of tumor tissue has demonstrated that dorsolateral prostate-specific secretory proteins were confined to well-differentiated ductal epithelial cells adjacent to, or within, the poorly differentiated tumor mass. Prostate tumors in the mice also display elevated levels of nuclear p53 and a decreased heterogeneous pattern of androgen-receptor expression, as observed in advanced human prostate cancer. The establishment of breeding lines of transgenic mice that reproducibly develop prostate cancer provides an animal model system to study the molecular basis of transformation of normal prostatic cells and the factors influencing the progression to metastatic prostate cancer.

To determine whether multiple features of immunohistochemical staining of the androgen receptor (AR) in prostate cancer could reliably predict androgen dependence, tumor biopsy specimens from 30 patients (stages A-D2) were stained using anti-peptide antibodies to the amino- and carboxyl-terminal of the AR. Measurements were made of the mean area and total amount (i.e., integrated optical density) of AR staining in at least 20 fields per section using a color video image analysis system, and the mean intensity of AR staining per cell and the percentage of AR positive tumor cells were derived. Video image analysis measurement identified quantitative differences in AR staining between the two antibodies, suggesting that this approach may provide a means of identifying receptor variants in prostate tumors. The AR staining measurements were analyzed by discriminant function analysis to assign individual cases to good and poor clinical outcome groups. AR staining features measured with a single antibody (e.g., amino-terminal) were sufficient to predict outcome following hormonal therapy in stage D2 patients (predictive value, 1.0), whereas all features of AR staining measured with both antibodies were required for the entire patient group (predictive value, 0.97). The principal discriminant in both patient groups contributing to the correct assignment of outcome was the mean intensity of AR staining per cell. These findings suggest that AR staining features measured by video image analysis have the potential to predict outcome in prostate cancer.

PURPOSE: To investigate Apolipoprotein-D (Apo-D) and prostate specific antigen (PSA) immunohistochemical staining of nonmalignant and malignant human prostate tissues. MATERIALS AND METHODS: Apolipoprotein-D and PSA immunoreactivity were evaluated by video image analysis in nonmalignant prostates and in 30 stage D2 prostate cancers. RESULTS: Apolipoprotein-D was detected in all 30 tumors, and the level of staining was elevated in comparison to age-matched nonmalignant prostates (p < 0.05). In contrast, the level of PSA staining in tumors was less than that detected in nonmalignant prostates. CONCLUSIONS: Apolipoprotein-D is expressed in normal human prostate. Elevated Apo-D staining is associated with advanced prostate cancer.

The human uroplakin 1B (UPK1B) gene codes for a structural protein which is a terminal differentiation component of the asymmetric unit membrane on the apical surface of the mammalian bladder. UPK1B is a member of the tetraspan family of proteins, many of which have de-regulated patterns of expression in cancer. Using polymerase-chain-reaction techniques, we have cloned a partial human UPK1B cDNA which codes for the putative full open reading frame for the UPK1B protein. The deduced human UPK1B protein sequence has 92% and 93% amino-acid homology with bovine UPK1b and mink TI1 proteins respectively. Using Northern analysis, we show that the human UPK1B gene is highly expressed in normal human urothelium. However, expression of UPK1B mRNA was undetectable or markedly reduced in 11 out of 16 samples of transitional-cell-bladder-carcinoma tissue and in all 5 bladder-carcinoma cell lines when compared with normal urothelial tissue. The molecular mechanism of down-regulation of RNA expression does not appear to involve gross gene rearrangements or allelic loss.