Novel antitumor effect of estradiol in athymic mice injected with a T47D breast cancer cell line overexpressing protein kinase Calpha.

PURPOSE: Resistance to tamoxifen (TAM) represents a significant challenge to the management of breast cancer. We previously reported that the estrogen receptor (ER)-negative hormone-independent T47D:C42 cell line has both elevated protein kinase Calpha (PKCalpha) protein expression and basal activator protein-1 activity compared with the parental ER+ (hormone-dependent) T47D:A18 cell line. Stable transfection of PKCalpha to the T47D:A18 breast cancer cell line results in increased basal activator protein-1 activity, reduced ER function, increased proliferation rate, and hormone-independent growth (Tonetti et al., Br. J. Cancer, 83: 782-791, 2000). In this report, we further characterize the role of PKCalpha overexpression in vivo to elucidate a possible molecular mechanism of tamoxifen resistance. EXPERIMENTAL DESIGN: To determine whether the T47D:A18/PKCalpha cell line would produce hormone-independent tumors in athymic mice, we injected T47D:A18, T47D:A18/neo, or the T47D:A18/PKCalpha20 cell clones bilaterally into the mammary fat pads of athymic mice. Tumor growth was evaluated following treatment with estradiol (E2), TAM, and the pure antiestrogen, ICI 182,780. RESULTS: Mice receiving either T47D:A18 or T47D:A18/neo cells produced tumors that grew in response to E2 treatment, whereas the untreated control and TAM-treated groups showed no tumor growth. Interestingly, mice receiving the T47D:A18/PKCalpha20 clone produced tumors in both the control and TAM groups, whereas tumor growth was inhibited in mice treated with E2. PKCalpha was also overexpressed in an MCF-7 tumor model that also exhibited TAM-stimulated and E2-induced regression. CONCLUSIONS: These results suggest that overexpression of PKCalpha in breast tumors results in hormone-independent tumor growth that cannot be inhibited by TAM treatment. Furthermore, the finding that E2 has an antitumor effect on breast tumors overexpressing PKCalpha is a novel observation that may have important therapeutic implications.

Stable transfection of protein kinase C alpha cDNA in hormone-dependent breast cancer cell lines.

An inverse relationship between protein kinase C (PKC) activity and oestrogen receptor (ER) expression in human breast cell lines and tumours has been firmly established over the past 10 years. To determine whether specific alterations in PKC expression accompany hormone-independence, we examined the expression of PKC isozymes in the hormone-independent human breast cancer cell clones MCF-7 5C and T47D:C42 compared with their hormone-dependent counterparts, MCF-7 A4, MCF-7 WS8 and T47D:A18 respectively. Both hormone-independent cell clones exhibit elevated PKC alpha expression and increased basal AP-1 activity compared with the hormone-dependent cell clones. To determine whether PKC alpha overexpression is sufficient to mediate the hormone-independent phenotype, we stably transfected an expression plasmid containing PKC alpha cDNA to the T47D:A18 and MCF-7 A4 cell lines. This is the first report of PKC alpha transfection in T47D cells. In contrast to MCF-7 cells, T47D has the propensity to lose the ER and more readily forms tamoxifen-stimulated tumours in athymic mice. We find that in T47D:A18/PKC alpha clones, there is concomitant up-regulation of PKC beta I and delta, whereas in the MCF-7 A4/PKC alpha transfectants PKC epsilon is up-regulated. In T47D:A18, but not in MCF-7 A4, PKC alpha stable transfection is accompanied by down-regulation of ER function whilst basal AP-1 activity is elevated. Our results suggest PKC alpha overexpression may play a role in growth signalling during the shift from hormone dependent to hormone-independent breast cancers.