Conditional repression of STAT5 expression during lactation reveals its exclusive roles in mammary gland morphology, milk-protein gene expression, and neonate growth

The role of Stat5 in maintaining adequate lactation was studied in Stat5a(-/-) mice expressing a conditionally suppressed transgenic STAT5 in their mammary glands. This system enables distinguishing STAT5's effects on lactation from its contribution to mammary development during gestation. Females were allowed to express STAT5 during their first pregnancy. After delivery, STAT5 levels were manipulated by doxycycline administration and withdrawal. In two lines of genetically modified mice, the absence of STAT5 expression during the first 10 days of lactation resulted in a decrease of 29% or 41% in newborn weight gain. The STAT5-dependent decrease in growth was recoverable, but not completely reversible, particularly when STAT5 expression was omitted for the first 4 days of lactation. Within the first 10 days of STAT5-omitted lactation, alveolar occupancy regressed by 50% compared to that measured at delivery. By Day 10, only 18% of the fat-pad area was involved in milk production. The alveolar regression caused by 4 days of STAT5 deficiency was reversible, but neonate growth remained delayed. STAT5 deficiency resulted in reduced estrogen receptor α and connexin 32 gene expression, accompanied by delayed induction of both anti- and pro-apoptotic Bcl-2 family members. An increase in Gata-3 expression may reflect an attempt to maintain alveolar progenitors. A decrease of 39% and 23% in WAP and α-lactalbumin expression, respectively, with no associated effects on β-casein, also resulted from lack of STAT5 expression in the first 10 days of lactation. This deficiency enhances the major effect of alveolar regression on delayed weight gain in newborns.     

Genetic manipulation of individual somatic mammary cells in vivo reveals a master role of STAT5a in inducing alveolar fate commitment and lactogenesis even in the absence of ovarian hormones

Assessing the molecular control of development and cell fate in individual cells in the intact mammary epithelium has not been possible to date. By exploiting an intraductal retrovirus (RCAS)-mediated gene delivery method to introduce a marker gene, we found that ductal epithelial cells are turned over with a half time of approximately 1 month in adult virgin mice. However, following RCAS-mediated introduction of a constitutively activated STAT5a (caSTAT5a), caSTAT5a-activated ductal epithelial cells expand and replace other cells in the epithelium, eventually forming a mammary gland resembling that in a late pregnant mouse, suggesting that STAT5a activation alone is sufficient to mediate pregnancy-induced mammary cell expansion, alveolar cell fate commitment, and lactogenesis. Furthermore, such caSTAT5a-induced alveolar differentiation does not require ovarian functions, although caSTAT5a-induced cell proliferation is partly reduced in ovariectomized mice. In conclusion, in this first report of studying the developmental role of a gene in a few cells in a normally developed virgin mammary ductal tree, STAT5a activation causes alveolar fate commitment and lactogenesis, and with the help of ovarian hormones, drives alveolar expansion.     

Abnormal Mammary Development in 129:STAT1-Null Mice is Stroma-Dependent

Female 129:Stat1-null mice (129S6/SvEvTac-Stat1^tm1Rds homozygous) uniquely develop estrogen-receptor (ER)-positive mammary tumors. Herein we report that the mammary glands (MG) of these mice have altered growth and development with abnormal terminal end buds alongside defective branching morphogenesis and ductal elongation. We also find that the 129:Stat1-null mammary fat pad (MFP) fails to sustain the growth of 129S6/SvEv wild-type and Stat1-null epithelium. These abnormalities are partially reversed by elevated serum progesterone and prolactin whereas transplantation of wild-type bone marrow into 129:Stat1-null mice does not reverse the MG developmental defects. Medium conditioned by 129:Stat1-null epithelium-cleared MFP does not stimulate epithelial proliferation, whereas it is stimulated by medium conditioned by epithelium-cleared MFP from either wild-type or 129:Stat1-null females having elevated progesterone and prolactin. Microarrays and multiplexed cytokine assays reveal that the MG of 129:Stat1-null mice has lower levels of growth factors that have been implicated in normal MG growth and development. Transplanted 129:Stat1-null tumors and their isolated cells also grow slower in 129:Stat1-null MG compared to wild-type recipient MG. These studies demonstrate that growth of normal and neoplastic 129:Stat1-null epithelium is dependent on the hormonal milieu and on factors from the mammary stroma such as cytokines. While the individual or combined effects of these factors remains to be resolved, our data supports the role of STAT1 in maintaining a tumor-suppressive MG microenvironment.