Franklyn F. Bolander

Prolactin regulation of mouse mammary tumor virus (MMTV) expression in normal mouse mammary epithelium.

The hormonal regulation of mouse mammary tumor virus (MMTV) RNA in normal mouse mammary epithelium was studied in an explant system. In tissue from parous mice, physiological concentrations of prolactin stimulated MMTV expression, while only pharmacological concentrations of cortisol were effective. Regulation in explants from virgin mice was similar to that in parous animals except that the former were less sensitive to prolactin; this relative unresponsiveness may explain why uninduced tissue from virgin mice does not express MMTV RNA, while that from parous mice does exhibit some basal production. These results suggest that prolactin plays a major role in MMTV expression in normal mammary epithelium and that glucocorticoids may only have a permissive effect or may act through an indirect mechanism requiring high concentrations. These data also suggest that the greater susceptibility of parous mice to MMTV-induced tumorigenesis may reflect the greater prolactin sensitivity in the glands from these animals.

The role of nitric oxide in the biological activity of prolactin in the mouse mammary gland

In mouse mammary epithelial cells, prolactin transiently elevates nitric oxide (NO) to a maximum of 6 nmol/mg protein at 15 min, after which levels fall rapidly. This stimulation can be achieved by as little as 100 ng prolactin/ml and can be mimicked by 100 microg sodium nitroprusside/ml. NO is both necessary and sufficient to mediate the prolactin-induced redistribution of its receptor from internal pools to the cell surface. NO can also enhance DNA synthesis stimulated by submaximal prolactin concentrations (50 ng/ml), but it is not necessary at pharmacological prolactin concentrations (1 microg/ml). In contrast, NO completely inhibits alpha-lactalbumin production. In summary, prolactin transiently elevates NO to enhance DNA synthesis and suppress premature differentiation; thereafter, NO declines, DNA synthesis ceases and differentiation proceeds. This data suggest that NO may mediate some of the effects of prolactin on growth in the mammary gland.

Differential characteristics of the thoracic and abdominal mammary glands from mice.

The anatomical and physiological characteristics of thoracic and abdominal mammary glands were investigated in order to understand why the incidence of mammary tumors is higher in the former. Epithelium in explants from both sets of glands required DNA synthesis, insulin, cortisol, and prolactin for full differentiation as measured by alpha-lactalbumin accumulation. The temporal pattern and magnitude of response were the same with respect to both DNA synthesis and differentiation; however, the epithelium in explants from the thoracic glands required concentrations of hormones for alpha-lactalbumin accumulation only one-half to one-third those from abdominal glands. Tumor distribution did not appear to correlate with mammary gland histology, size, or epithelial content.

The role of sex steroids in the expression of MMTV in the normal mouse mammary gland

Infection with the mouse mammary tumor virus (MMTV) is associated with hyperplastic alveolar growth and subsequent tumorigenesis. The role of the sex steroids in the initial phase of this pathological chain of events is investigated in this study. In normal mammary epithelium, progesterone stimulates MMTV RNA expression both in vivo (2.6-fold) and in vitro (2.9-fold); although estradiol is ineffective alone, it does enhance the effect of progesterone (6.8- and 5.7-fold stimulation, respectively). These results suggest that the sex steroids may play an important role in inducing MMTV expression which can then lead to epithelial hyperplasia and, eventually, malignant transformation.

Hormonal regulation of protein kinase C in the mouse mammary gland

Abstract The hormonal regulation of protein kinase C (PKC) induction over 3 to 14 days was investigated in the mouse mammary gland in vitro and in vivo. In intact mice, estradiol (1 μg/ mouse injected daily for 2 weeks) stimulated PKC activity 70%, while progesterone (1 mg/mouse injected daily) inhibited it by 30%. Prolactin, whose levels were elevated for 2 weeks by two pituitary isografts, had no effect. When mammary gland explants were cultured in insulin and Cortisol, the further addition of estradiol (1 ng/ml), progesterone (1 μg/ml), or prolactin (1 μg/ml) did not alter PKC activity after 3 days. These data suggest the following conclusions: although previous studies have implicated prolactin in the transient, calcium-phospholipid activation of PKC, it does not appear to elevate total levels of this kinase over prolonged periods. In contrast, the sex steroids do appear to affect long-term levels of this kinase; furthermo, this latter effect may be indirect.

The effect of 5-azacytidine on mammary gland differentiation in vitro

Summary 5-Azacytidine, a cytidine analog which leads to hypomethylation in DNA and usually induces differentiation, actually inhibits differentiation in mammary gland explants. Either the genes for casein and the components of lactose synthetase are inactivated by hypomethylation or, more likely, mammary differentiation is inhibited by regulatory gene(s) which must be inactivated by methylation before differentiation can commence.

Regulation of prolactin receptor glycosylation and its role in receptor location.

In unstimulated mammary epithelial cells from virgin mice, the prolactin receptor exists as two isoforms: a 78 and a 70 kDa species. Both proteins are reduced to a single 61 kDa molecule after N-glycanase F treatment, indicating that their size difference is solely a result of carbohydrate content. Membrane fractionation experiments reveal that the smaller species is exclusively intracellular, while the larger one is located on the cell surface. Nitric oxide (NO) stimulates the migration of prolactin receptors from an internal pool to the plasmalemma in only 30 min and this redistribution is associated with an increase in molecular weight. Redistribution is blocked by swainsonine, but not by castanospermine or 1-deoxymannojirimycin, suggesting that the glycosylation step involved with translocation is either alpha-mannosidase II or N-acetylglucosamine (NAG) transferase I. The former is unaffected by NO but the activity of the latter is doubled 30 min after exposure to NO. These data suggest that prolactin receptors are retained intracellularly because of their incomplete N-glycosylation and that NO triggers their redistribution by stimulating the completion of this process, in part by increasing NAG transferase I activity.

Transduction pathways involved in rapid hormone receptor regulation in the mammary epithelium

Previous studies have shown that the envelope protein of the mouse mammary tumor virus (MMTV) rapidly upregulates prolactin (PRL) receptors by shifting them from internal pools to the cell surface and downregulates epidermal growth factor (EGF) receptors by inducing their internalization and degradation. This study shows that the effect on PRL receptors is mediated by the nitric oxide (NO)/cGMP pathway, since it can be mimicked by an NO donor or 8-bromo-cGMP and can be blocked by an NO synthase inhibitor. In contrast, the effect on EGF receptors is mediated by tyrosine phosphorylation and phosphatidylinositol 3-kinase (PI3K), since it can be blocked by either a tyrosine kinase inhibitor or by a PI3K inhibitor. Both of these pathways can be activated by a calcium ionophore and inhibited by calcium chelation. Therefore, it appears that the mouse mammary tumor virus envelope protein, like other retroviral envelope proteins, initially elevates cytoplasmic calcium, which can then stimulate both the NO/cGMP and the tyrosine phosphorylation/PI3K pathways, leading to PRL receptor upregulation and EGF receptor downregulation, respectively.Previous studies have shown that the envelope protein of the mouse mammary tumor virus (MMTV) rapidly upregulates prolactin (PRL) receptors by shifting them from internal pools to the cell surface and downregulates epidermal growth factor (EGF) receptors by inducing their internalization and degradation. This study shows that the effect on PRL receptors is mediated by the nitric oxide (NO)/cGMP pathway, since it can be mimicked by an NO donor or 8-bromo-cGMP and can be blocked by an NO synthase inhibitor. In contrast, the effect on EGF receptors is mediated by tyrosine phosphorylation and phosphatidylinositol 3-kinase (PI3K), since it can be blocked by either a tyrosine kinase inhibitor or by a PI3K inhibitor. Both of these pathways can be activated by a calcium ionophore and inhibited by calcium chelation. Therefore, it appears that the mouse mammary tumor virus envelope protein, like other retroviral envelope proteins, initially elevates cytoplasmic calcium, which can then stimulate both the NO/cGMP and the tyrosine phosphorylation/PI3K pathways, leading to PRL receptor upregulation and EGF receptor downregulation, respectively.

Enhanced hormonal responsiveness in mammary glands from parous mice: molecular mechanisms

Mammary glands from parous mice required lower concentrations of hormones in vitro than those from virgins to effect differentiation, as measured by lactose synthetase activity. This phenomenon could not be explained by changes in receptor levels, since both mammary gland insulin and prolactin binding, although elevated at midpregnancy, returned to baseline in tissue from parous mice. Ethidium bromide, an intercalating dye, was a potent inhibitor of lactose synthetase induction in explants from virgins but much less potent in tissue from pregnant mice; explants from parous animals displayed intermediate sensitivity, suggesting that DNA structure was permanently altered. However, casein synthesis in glands from parous mice required hormone concentrations as high as in virgins and are just as susceptible to ethidium bromide as in virgins. Similarly, the vulnerability of the casein gene to DNAase I digestion is low in mammary epithelial cells from virgins, high in cells from pregnant mice, and low again in cells from parous animals. These data suggest that during the first pregnancy of mice, there are changes in the chromatin configuration that may facilitate the transcription of milk-related mRNA. Furthermore, after mammary gland involution these changes in the casein gene undergo reversion, while those involved with lactose synthetase activity persist; this may explain the disparate hormonal responsiveness seen in these animals with respect to casein and lactose synthesis.

REQUIREMENTS FOR MOUSE MAMMARY TUMOUR VIRUS INTERNALIZATION IN MOUSE MAMMARY EPITHELIAL CELLS

Methylamine, a lysosomotropic alkalinizing agent, blocked mouse mammary tumour virus (MMTV) infection in normal mouse mammary epithelium, suggesting that internalization and acidification are necessary for cell penetration. This mechanism was further supported by the fact that intact MMTV induced the translocation of its cellular binding protein from the plasmalemma to the microsomes; however, isolated gp52, the MMTV envelope protein that binds this receptor, did not redistribute the binding protein. These data suggest that either another viral component, in addition to gp52, is needed for cell entry or that internalization requires receptor aggregation, which only the multivalent viral envelope can induce.