The role of human prolactin and its antagonist, G129R, in mammary gland development and DMBA-initiated tumorigenesis in transgenic mice

Abstract

Human prolactin (hPRL) has been implicated to have a pathological role in breast cancer and play a critical role in mammary gland development. The hPRL antagonist, G129R, has been shown to induce breast cancer cell apoptosis. 9,10-Dimethyl-1,2-benzanthracene (DMBA), a potent mammary gland carcinogen, induces hormone responsive mammary tumor formation in rodents. To investigate the effects of hPRL and its counterpart, G129R, on mammary gland development and tumorigenesis, transgenic mice that express hPRL or G129R under the regulation of the metallothionein (Mt) promoter were generated. Mammary glands from virgin female transgenic mice at the ages of 12, 24, and 36 weeks were used to compare the effect of hPRL and G129R in various developmental stages. Mammary gland whole mount comparisons between transgenic mice and their littermates revealed a significant increase in ductal branching and lobular bud formation in hPRL transgenic mice; whereas a drastic decrease in ductal branching and lobular bud formation was observed in the mammary glands of G129R transgenic mice. In addition, total RNA isolated from the mammary glands of transgenic mice at the three different ages was analyzed on Affymetrix GeneChip Mouse Expression 430A chips (MOE430A). Microarray data revealed alteration to the gene expression levels, greatest at 12 and 36 weeks. Furthermore, hPRL and G129R transgenic mice, as well as their littermates, were treated with multiple doses of DMBA and the rate of mammary tumor formation and survival were compared. The tumor rates in the G129R transgenic mice were significantly reduced (18% at 28 weeks) as compared to that of either NTG (39%) or hPRL (40%). On the other hand, the tumor appearance is significantly earlier in the PRL transgenic group as compared to that of controls. Taken together, the data further confirmed the inhibitory effects of G129R in mammary gland development, which translates to a resistance to DMBA-initiated breast tumorigenesis.