Effects of glucocorticoids on casein gene expression in the rabbit.

Milk protein synthesis is initiated by prolactin and a glucocorticoid. In the rabbit, prolactin alone is sufficient. However, glucocorticoids potentiate the action of prolactin. The stimulatory effect of glucocorticoids was evaluated after injections of hydrocortisone acetate alone or associated with prolactin by measurements of (a) the total RNA and DNA content of mammary glands, (b) the lactose synthetase activity, (c) casein synthesis, and (d) the concentration of casein mRNA in total cellular RNA and in polysomal RNA by hybridization with its cDNA. The glucocorticoid, totally inactive alone, proved to have a stimulatory effect proportional to the dose injected when prolactin was present. This effect was more evident with low doses of prolactin. Glucocorticoids proceeded by amplifying the capacity of prolactin to enhance the concentration of casein mRNA available for translation. A parallel effect of glucocorticoids on translation of casein mRNA was suspected. Glucocorticoids injected with low doses of prolactin were unable to mimic all the effects of high doses of prolactin alone.     

Effect of ouabain on the lactogenic action of prolactin and on the level of mammary prolactin receptors

Ouabain added to the culture medium of rabbit mammary gland inhibits prolactin action on the initiation of lactose and casein synthesis. The degree of inhibition is a function of the ouabain concentration in the medium. Likewise, ouabain blocks the accumulation of casein mRNA supported by prolactin. In addition, ouabain provokes a rapid disappearance of prolactin receptors. Conversely prolactin keeps its capacity to enhance the concentration of casein mRNA and the parallel casein synthesis when K+ ions are totally absent from the culture medium. These results suggest that although prolactin induces a modification of the K+/Na+ ratio in the mammary cell and ouabain prevents this effect of prolactin, the inhibitory action of ouabain on lactogenesis can be explained essentially by its effect on the hormone receptors.     

Role of prolactin and glucocorticoids in the expression of casein genes in rabbit mammary gland organ culture. Quantification of casein mRNA

Milk synthesis is initiated solely by prolactin in the pseudopregnant rabbit and glucocorticoids potentiate this action of prolactin. In organ culture, prolactin, in the presence or in the absence of insulin, enhances casein synthesis and cortisol (inactive alone) amplifies this action. Measurements of casein mRNA concentration in total cellular RNA, by hybridization with DNA complementary to casein mRNA, revealed that the stimulation of casein synthesis by the glucocorticoid is accompanied by an increase in the amount of casein mRNA. A systematic comparison of variations of these two parameters indicated that the major effect of glucocorticoids on lactogenesis in the rabbit at this stage of mammary gland development is mediated through an increase in the quantity of casein mRNA available for translation. No simultaneous control of casein mRNA translation by cortisol was observed.     

Stabilization of casein mRNA by prolactin and glucocorticoids.

Prolactin injected into pseudopregnant rabbits led to a parallel enhancement of casein synthesis and casein mRNA concentration. When this stimulation was followed by a withdrawal of prolactin obtained by injections of bromocriptine, the rate of casein synthesis progressively diminished. In the presence of endogenous prolactin after the initial stimulation, the decline of casein synthesis was delayed. Hydrocortisone acetate injected with bromocriptine after the initial stimulation by prolactin was able to maintain a high rate of casein synthesis. Measurements of casein mRNA concentration by hybridization with casein cDNA indicated that in all cases the amount of casein mRNA was correlated with the magnitude of casein synthesis. This suggests that the lactogenic hormones, prolactin and glucocorticoids, which were previously demonstrated to be responsible for the enhancement of casein mRNA concentration are involved in their stabilization.     

Prolactin induction of casein mRNA in organ culture. A model system for studying peptide hormone regulation of gene expression

The peptide hormone, prolactin, when added to organ explants of rat mammary gland, rapidly (within 1 h) induced the accumulation of casein mRNA. Casein mRNA sequences, as determined by hybridization with a specific cDNA probe, were shown to increase for up to 48 h after prolactin addition. The magnitude of this response was dependent upon the day of pregnancy at which the tissue was placed in culture. Maximal levels of induction (as great as 45-fold) were obtained using tissue from 15-day pregnant rats. Further data indicate that two steroid hormones, hydrocortisone and progesterone, were able to modulate the prolactin-induced accumulation of casein mRNA. The continuous presence of hydrocortisone was not necessary for prolactin induction of casein mRNA. However, the presence of hydrocortisone was required for maximal accumulation of casein mRNA. The induction of casein mRNA by prolactin was inhibited in a dose-dependent manner by the simultaneous addition of progesterone to the organ culture. Thus, hydrocortisone appears to potentiate the prolactin induction of casein mRNA, whereas progesterone is able to prevent casein mRNA accumulation. Since mammary gland organ culture is performed in a serum-free, chemically defined medium, this system allows a detailed examination of the mechanims by which a peptide hormone regulates the rapid accumulation of a specific mRNA.     

Role of glucocorticoids and progesterone in the development of rough endoplasmic reticulum involved in casein biosynthesis.

Hydrocortisone acetate injected into pseudopregnant rabbits induced casein synthesis and a parallel accumulation of casein mRNA. These effects were not accompanied by any enrichment of total RNA in the mammary cell. Hydrocortisone acetate did not favour the attachment of polysomes to endoplasmic reticulum. Casein mRNA concentration was enhanced in free and membrane-bound polysomes. After long treatments, the concentration of casein mRNA reached a plateau in membrane bound polysomes whereas it continued to be accumulated in free polysomes, suggesting that a substantial part of casein synthesis is then carried out by free polysomes. Progesterone injected with high doses of prolactin was unable to prevent the stimulatory action of prolactin on the synthesis of casein, the accumulation of casein mRNA and mammary gland growth, as judged by DNA content. By contrast, the increase in the total RNA content of mammary gland was still significantly reduced by progesterone. In addition, progesterone inhibited almost completely the formation of membrane-bound polysomes and the anchorage of casein mRNA to endoplasmic reticulum. From these data, it was concluded that the formation of the endoplasmic reticulum is not a prerequisite for the initiation of casein synthesis. Glucocorticoids do not play a major role in the formation of the endoplasmic reticulum and the Golai apparatus and in the binding of casein synthesizing polysomes to membranes. Progesteronne is capable of inhibiting preferentially and gradually the stimulation of cellular functions requiring the most potent prolactin stimulation.     

Prolactin-induced accumulation of casein mRNA in mouse mammary explants: A selective role of glucocorticoid

The role of glucocorticoid in the prolactin-induced accumulation of casein mRNA in mammary explants from midpregnant mice has been studied after an initial 4-day incubation to allow the level of messenger to decline to undetectable levels. Subsequent culture for 3 days: 1) with insulin and glucocorticoid did not result in detectable accumulation of messenger; 2) with insulin and prolactin resulted in a very small accumulation; 3) with insulin, glucocorticoid and prolactin elicited a 20-fold greater accumulation of casein mRNA than the system with only insulin and prolactin. Therefore, although glucocorticoids are not an absolute requirement for casein gene expression in mouse mammary tissue, they are necessary for massive accumulation of casein mRNA induced by prolactin. It appears that this dependence is not a result of either mRNA stabilization or alteration in prolactin receptors. By contrast, stimulation of total epithelial RNA synthesis by prolactin does not have this glucocorticoid dependency.     

Hormonal regulation of the synthesis of casein and alpha-lactalbumin in a primary mammary cell culture system

The addition of 5 micrograms/ml of both insulin and prolactin, 3 microM cortisol and 5% fetal bovine serum stimulated casein synthesis during a 5 day culture of mammary epithelium from lactating mice using a floating collagen gel as a culture substratum. Omission of any of the three hormones or serum decreased casein synthesis substantially. The use of 10% serum or the attached gel culture system also decreased casein synthesis. Cells cultured with the combination of the three hormones and 5% serum contained a low level of casein mRNA on day 2, but it increased to much higher levels on day 4 and 5, amounting to over 30% of total mRNA on day 5. In contrast to casein synthesis, the maximal increase in alpha-lactalbumin synthesis required the presence of 0.03 microM cortisol. The combination of insulin, prolactin and 3 microM cortisol or insulin and prolactin elicited smaller increases. The translatable mRNA for alpha-lactalbumin in cells cultured with insulin, cortisol and prolactin for 5 days was detected, but not in cells with insulin and cortisol. Both a high and low concentration of cortisol in combination with insulin increased prolactin binding capacity of cultured cells to the same extent, whereas cells cultured with insulin alone contained much lower levels of prolactin binding. The difference in the capacity of prolactin binding between cells cultured with insulin alone and those cultured with insulin and cortisol correlated well with their ability to synthesize casein in response to prolactin.     

The interaction of cortisol and prostaglandins on the phenotypic expression of the alpha-lactalbumin gene in the mouse mammary gland in culture

Addition of cortisol at concentrations above 300 nM selectively inhibited the synthesis of alpha-lactalbumin and the accumulation of its mRNA in the mouse mammary gland cultured in the presence of insulin and prolactin, whereas the same treatment augmented casein synthesis and the accumulation of casein mRNA. Prostaglandin E2 or F2 alpha reversed the inhibitory effects of cortisol in a dose-dependent manner, without affecting casein production. The levels of prostaglandin E2 or F2 alpha in tissue explants cultured with insulin and prolactin increased about 2.6-fold over those in uncultured tissue, and the addition of cortisol decreased these levels approximately 2-fold. These results indicate the ability of prostaglandins to counteract the inhibitory effect of cortisol on the alpha-lactalbumin gene expression in the mouse mammary gland.     

Cortisol induces rapid accumulation of whey acid protein mRNA but not of asl and b-casein mRNA in rabbit mammary explants

Mammary explants from rabbit were cultured in the presence of various combinations of insulin, cortisol and prolactin. The concentration of whey acidic protein (WAP) asl-casein and b-casein mRNA was measured using specific cDNA probes. Medium alone was added to the explants for one day. Prolactin with and without cortisol was then added to the medium. Prolactin alone induced rapidly asl-and b-casein gene but not WAP gene. When cortisol was added with prolactin, the asl- and b-casein genes were induced at the same rate as in the absence of the steroid. In contrast, the WAP mRNA was then rapidly accumulated. This induction process was not altered by cycloheximide for two hours and it was blocked at a later stage. In a second experiment, insulin and prolactin were first added for 24 hours in the culture medium. Cortisol was then added and the concentration of the three mRNA was measured. Cortisol did not significantly modify the level of asl- and b-casein mRNA. On the contrary, the WAP mRNA was rapidly accumulated. These data indicate that the well-established amplificatory effect of glucocorticoids on casein gene expression is a slow process whereas their effect on the WAP gene is rapid. This suggests that glucocorticoids induce casein gene expression through an indirect cellular mechanism not involving a glucocorticoid receptor element in casein gene promoters and that WAP gene is more classically stimulated through the direct binding of the steroid receptor to a glucocorticoid receptor element located in its promoter.     

Correlation between nuclear histone acetylation and casein messenger RNA induction in the mammary gland

Sodium butyrate prevented the accumulation of casein mRNA induced by the combined action of prolactin and glucocorticoid in the presence of insulin in the cultured mammary gland. This inhibition was reversible and dose-dependent. In addition to the inhibition of the mRNA induction, both nuclear histone acetylase and deacetylase activities were inhibited by the incubation of the glands with butyrate, whereas these enzyme activities were stimulated by glucocorticoid and prolactin, or by glucocorticoid alone, in the presence of insulin. These data strongly suggest that the increased metabolism of histone acetyl groups is involved in the hormone-mediated casein mRNA induction and that glucocorticoid plays a preferential role on this increased metabolism.     

The hormonal control of ovine beta-lactoglobulin gene in cultured ewe mammary explants

Mammary explants from pregnant ewes were cultured in the presence of insulin, cortisol and prolactin, either alone, or in combination. After 2 d of culture, total RNA was extracted from explants and the content of beta-lactoglobulin mRNA was estimated using a specific labelled cDNA probe. The mRNA for beta-lactoglobulin was only deinduced slowly in the absence of hormone during the culture. Prolactin alone induced the accumulation of the mRNA. Insulin and cortisol added together were also stimulatory, but they only moderately amplified the prolactin effect. Beta-lactoglobulin gene in ewes, is therefore, controlled by the lactogenic hormones which also induce casein gene expression. The amplitude of the stimulation was unexpectedly low. This seems due in part to the fact that the gene was only deinduced weakly. In this respect, beta-lactoglobulin gene appears to be less dependent on lactogenic hormones under these experimental conditions than casein genes.     

The differential actions of cortisol on the synthesis and turnover of alpha-lactalbumin and casein and on accumulation of their mRNA in mouse mammary gland in organ culture.

Cortisol was previously shown to exert different, concentration-dependent, effects on the accumulation of casein and alpha-lactalbumin in mammary glands from mid-pregnant mice cultured in the presence of insulin and prolactin [Ono & Oka (1980) Cell 19, 473-480]. The present study demonstrated that the addition of 30nM-cortisol to the medium containing insulin and prolactin resulted in a marked enhancement of the rate of synthesis of both alpha-lactalbumin and casein in cultured tissue. The addition of 3 microM-cortisol in combination with insulin and prolactin caused a marked decrease in the rate of alpha-lactalbumin synthesis, but increased casein synthesis substantially. Similar changes were also observed in the amount of translatable mRNA for alpha-lactalbumin and casein in mammary explants cultured with insulin, prolactin and the two concentrations of cortisol. The study of the turnover of the milk proteins in cultured explants showed that virtually all of the casein synthesized remained intact in tissue explants cultured with 3 microM cortisol, whereas about 45% of casein disappeared in 40h from explants cultured with 30nM-cortisol. In contrast, the two concentrations of cortisol did not differentially affect the disappearance of alpha-lactalbumin, which was about 55% in 40h. These results indicate that the concentration-dependent differential actions of cortisol on the accumulation of alpha-lactalbumin and casein are exerted through its effects on the rate of synthesis and turnover of the two proteins as well as on the accumulation of their mRNA species.     

Further characterization of the inhibition of casein production in a primary mouse mammary epithelial cell culture by epidermal growth factor. Antagonism by cyclic AMP

Epidermal growth factor (EGF) inhibited casein production and the accumulation of casein mRNA activity induced by insulin (I), cortisol (F) and prolactin (P) in a primary culture of mammary epithelial cells from pregnant mice. The inhibitory effects of EGF were blocked by 8-bromo cyclic AMP (8-br-cAMP) in a dose-dependent manner. The effect of 8-br-cAMP was observed at a concentration as low as 20 microM and was maximal at 500 microM. Dibutyryl cyclic AMP (db-cAMP), cAMP, and 3-isobutylmethylxanthine (IBMX), an inhibitor of phosphodiesterase, also antagonized the inhibitory effect of EGF on casein production. 8-Br-cAMP had, however, no effect on the mitogenic activity of EGF in this system. These results suggest a possible modulatory role of cAMP in EGF-induced inhibition of casein production in cultured mammary epithelial cells.     

Effects of amiloride on the induction of DNA synthesis and casein gene expression in rabbit mammary explants

Amiloride, an inhibitor of Na+/H+ exchange, was added at various concentrations to the culture medium of rabbit mammary explants. In the concentration range 100-250 microM, amiloride progessively inhibited 14C-thymidine incorporation induced by insulin, EGF or prolactin. Up to 250 microM, amiloride, which did not inhibit basal protein synthesis, was not cytotoxic, but it reduced basal DNA synthesis at the highest concentration. Addition of amiloride to the culture medium of mammary explants also strongly inhibited the induction of casein synthesis and casein mRNA accumulation by prolactin. The inhibition by amiloride is therefore not specific of the mitogenic action of prolactin since this drug also prevented its lactogenic action. The data reported here describe a new inhibitory action of amiloride on the transmission of the lactogenic signals.     

Effect of prolactin on the secretion of milk casein: metabolism of arachidonic acid

Mammary gland fragments were incubated in the presence of prolactin and arachidonic acid which stimulate casein secretion. The effects of these stimuli in the presence of agents that influence arachidonic acid metabolism were investigated. Chloroquine, a blocker of phospholipase A2 activity, decreased prolactin but not arachidonic acid stimulation of casein secretion. Phospholipase A2 markedly stimulated casein secretion. Nordihydroguaiaretic acid (NDGA), an antioxidant that inhibits lipoxygenase, blocked the stimulating effect of prolactin and arachidonic acid. Ultrastructural studies indicated that phospholipase A2-induced stimulation of secretion was comparable to that of prolactin but that arachidonic acid-induced stimulation did not involve the same Golgi membrane modifications. These studies suggest that prolactin and phospholipase A2 stimulate secretion by a common way, and that arachidonic acid interferes with secretion by metabolic products of the lipoxygenase pathway.     

Simultaneous occurrence of pregnancylike lobuloalveolar morphogenesis and casein-gene expression in a culture of the whole mammary gland

Summary Entire second thoracic mammary glands of estrogen- and progesterone-treated immature virgin BALB/c mice were stimulated to pregnancylike lobuloalveolar morphogenesis after 6 days of incubation with insulin (5 μg/ml), aldosterone (1 μg/ml), growth hormone (5 μg/ml), cortisol (5 μg/ml), and prolactin (80 ng/ml, present as a contaminant in 5 μg/ml growth hormone). The alveolar growth in the glands, as judged by morphological studies, was accompanied by an increase in cell number as a function of incubation time in the hormonal medium. Hybridization of the total RNA from these glands to the casein mRNA specific complementary DNA probe (cDNA_csn) revealed that the level of casein mRNA rises from 0.00012 to 0.005% between 1 and 6 days of incubation. Estimates showed that the concentration of casein mRNA per cell rises 17-fold from 70 molecules on Day 1 to 1200 molecules on Day 6, whereas the number of epithelial cells increases only twofold during the same incubation time. When the growth hormone preparation was totally replaced by 80 ng of prolactin during the 6-day incubation, casein-mRNA levels were found to be 0.0083%. These results demonstrate that a pregnancy-like morphogenesis and concurrent expression of the casein gene in vitro can be achieved in a controlled hormone environment containing high cortisol and low prolactin concentrations. This one-step mammogenesis-lactogenesis culture model should be useful for studying the mechanisms of hormonal regulation of casein-gene expression observed in prepartum mammary gland in vivo. This work was supported by Department of Health, Education and Welfare Grants CA11058 and CA25304 from the National Cancer Institute.