ErbB-2 induces the cyclin D1 gene in prostate epithelial cells in vitro and in vivo.

The receptor tyrosine kinase ErbB-2 plays an important role in the regulation of growth factor-induced signal transduction cascades in the epithelium, and ErbB-2 is frequently overexpressed in epithelial tumors. Our previous studies on clinical prostate cancer specimens indicated that ErbB-2 expression was increased in patients undergoing hormone ablation therapy. We had also shown that the critical cell cycle regulatory gene cyclin D1 and its promoter were targets of proliferative signaling in prostate cancer cell lines, and that cyclin D1 was required for ErbB-2-induced mammary tumorigenesis. In the current studies, we found that increased ErbB-2 membrane expression correlated with increased nuclear cyclin D1 staining in clinical prostate cancer specimens, and that expression of ErbB-2 was capable of inducing cell cycle progression in human prostate cancer cell lines. We further showed that ErbB-2 induced the cyclin D1 promoter in DU145 cells, and that small interfering RNA knockdown of cyclin D1 protein levels blocked a significant proportion of the heregulin-induced cell cycle progression in LNCaP cells. Probasin promoter-targeted expression of an activated ErbB-2 isoform induced cyclin D1 expression in the mouse prostate, commensurate with prostate intraepithelial neoplasia. Together, these in vitro and in vivo studies identify cyclin D1 as a critical downstream target of ErbB-2 in the prostate epithelium, both of which are possible therapeutic targets for cancer intervention. Furthermore, our novel mouse model provides a useful platform for ongoing in vivo investigations of ErbB-2 signaling in the prostate epithelium.

Characterization of a plasma membrane-resident albumin-binding protein associated with the proliferation of estrogen-target, serum-sensitive cells.

Estrogens control the proliferation of their target cells through a receptor-mediated pathway. Recently presented evidence suggests that estradiol cancels the proliferative inhibition exerted by human albumin (HA) and recombinant human albumin (rHA) on estrogen-target serum-sensitive cells (indirect-negative hypothesis). We postulate that this mechanism requires the presence of a plasma membrane estrogen receptor (mER) and a plasma membrane albumin-binding protein (mABP). Direct evidence confirming the presence of mERalpha in MCF7 cells has recently been presented. Herein, we now show that Western blot analysis of purified T47D membrane proteins with the C542 ERalpha specific monoclonal antibody also revealed specific, multiple M(r) mERs (67, 110, and 130k M(r)). In addition, Western blot analysis with an ABP antiserum revealed a potential 60k M(r) ABP in both MCF7 and T47D plasma membrane extracts. No such evidence was observed in similar extracts from ER-negative, serum-insensitive MDA-MB231 cells. Ligand blot analysis of similar plasma membrane extracts with bovine serum albumin confirmed the presence of a 60k M(r) ABP in MCF7 and T47D cells; again, no such evidence was observed in comparable extracts from MDA-MB231 cells. Fluorescence and confocal microscopy of MCF7 cells fixed in 2.0% paraformaldehyde/0.1% glutaraldehyde identified specific membrane ABP antigenic sites by immunocytochemistry. Serum-insensitive MDA-MB231 cells fixed and labeled similarly did not exhibit this mABP. These results suggest that the proposed mABP is expressed only in serum-sensitive estrogen-target cells and is not expressed in cells insensitive to the proliferative inhibition of HA and rHA. Also, the present data suggest that the proposed mABP may be the recognition mechanism by which both HA and rHA inhibit MCF7 and T47D cell proliferation.