The study of differentiative potential of the lactating mouse mammary gland in organ culture

The organ culture of the mammary gland of lactating mice was used to examine the response of the differentiated gland to lactogenic stimuli, insulin, cortisol, and prolactin. Time course studies showed that casein synthesis in cultured tissue decreased rapidly during the first 2 d despite the presence of the three hormones, but on the 3rd d tissue cultured with either insulin and prolactin or all three hormones regained the ability to synthesize milk proteins, casein, and alpha-lactalbumin: a greater increase occurred in the three hormone system. The delayed addition of prolactin on Day 2 to the culture system containing insulin and cortisol also stimulated casein synthesis. The addition of cytarabine, which inhibited insulin-dependent cell proliferation in cultured explants, did not block the rebound of milk protein synthesis. These results indicate that in the presence of insulin, cortisol, and prolactin mammary epithelial cells in culture first lose and then regain the ability of synthesizing milk protein without requiring the formation of new daughter cells.     

The study of differentiative potential of the lactating mouse mammary gland in organ culture

Summary The organ culture of the mammary gland of lactating mice was used to examine the response of the differentiated gland to lactogenic stimuli, insulin, cortisol, and prolactin. Time course studies showed that casein synthesis in cultured tissue decreased rapidly during the first 2 d despite the presence of the three hormones, but on the 3rd d tissue cultured with either insulin and prolactin or all three hormones regained the ability to synthesize milk proteins, casein, and α-lactalbumin: a greater increase occurred in the three hormone system. The delayed addition of prolactin on Day 2 to the culture system containing insulin and cortisol also stimulated casein synthesis. The addition of cytarabine, which inhibited insulin-dependent cell proliferation in cultured explants, did not block the rebound of milk protein synthesis. The results indicate that in the presence of insulin, cortisol, and prolactin mammary epithelial cells in culture first lose and then regain the ability of synthesizing milk protein without requiring the formation of new daughter cells.     

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.     

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.     

Casein turnover in rabbit mammary explants in organ culture

1. Explants of mammary gland from mid-pregnant rabbits were cultured in medium 199 containing insulin, prolactin and cortisol, and specific anti-casein immunoglobulin G was used to measure the amount, rate of synthesis and rate of degradation of casein in the explants in the presence of hormones and after removal of hormones from previously stimulated tissue. 2. The amount of casein in particle-free supernatants prepared from mammary explants was measured by ;rocket' immunoelectrophoresis. 3. The rate of incorporation of l-[4,5-(3)H]leucine into casein was measured after isolation of the casein by immunoadsorbent chromatography and polyacrylamide-gel electrophoresis in the presence of urea and sodium dodecyl sulphate. 4. Casein accumulates in mammary explants in the presence of insulin, prolactin and cortisol, but not in the absence of hormones. Removal of hormones after 24h in culture results in a decrease in the rate of accumulation of casein in the explants. 5. Casein-synthetic rate increases in mammary explants in the presence of insulin, prolactin and cortisol, but not in the absence of hormones. Removal of hormones after 24h in culture results in continued casein synthesis at approx. 30% of the rate in the presence of hormones. The synthetic rate does not decrease to values observed in explants cultured throughout in the absence of hormones. 6. Casein is not degraded in mammary explants during a phase of rapid casein accumulation (36-72h) in the presence of hormones. Furthermore casein is not degraded when hormones are removed from the tissue after between 36 and 72h in culture. 7. Casein is glycosylated in mammary explants; the extent of glycosylation parallels the rate of synthesis. The glycosylated protein is rapidly secreted from the tissue. 8. The results are consistent with the notion that after hormonal stimulation mammary explants from mid-pregnant rabbits synthesize, glycosylate and rapidly secrete casein. Removal of hormones decreases the synthetic rate of casein, but does not cause the accumulation of a pool of degradable casein in the lobuloalveolar 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.     

Hormonal control of casein synthesis in mammary explants from pregnant goats

The effects of insulin, cortisol, prolactin, 3,3',5-triiodo-L-thyronine (L-T3) and progesterone on the synthesis of total protein and casein in mammary explants from pregnant goats were studied. In the absence of hormones and in the presence of insulin plus cortisol the rate of incorporation of 14C-leucine into proteins that were precipitated with the anti-casein antibody decreased during culture. The addition of prolactin to hormonal combination of insulin and cortisol caused large stimulation of rates of casein synthesis. Maximum incorporation of leucine was attained between 3 and 5 days of culture in the presence of 0.5 microgram ml-1 of prolactin. Prolactin stimulated-casein and total protein synthesis were not consistently affected by the addition of L-T3 or progesterone. The inhibition of DNA synthesis by hydroxyurea or cytosine-arabinofuranoside had no effect on casein synthesis in mammary explants from pregnant goats.     

Hormone-responsive survival of mammary gland explants from the pregnant tammar wallaby (Macropus eugenii) in the absence of exogenous hormones and growth factors.

1. The level of beta-lactoglobulin mRNA increased maximally in mammary explants from late pregnant tammars cultured for 3 days in media containing either prolactin or insulin, cortisol and prolactin. 2. The same level of accumulation occurred when explants were first cultured for 4 days in a chemically defined medium with no exogenous hormones, serum or growth factors, suggesting that the tissue remains viable and hormone-responsive during the initial incubation. 3. Mammary explants cultured for 4 days in medium with no hormones demonstrated a progressive increase in the rate of RNA and DNA synthesis suggesting that the tissue is under a positive autocrine/paracrine stimulus.     

Effects of estramustine, a new anti-microtubule drug, on the induction of casein gene expression by prolactin

Estramustine, a new anti-microtubule drug, was added to the culture medium of rabbit mammary explants with lactogenic hormones. In the absence of the drug, prolactin with insulin and cortisol stimulated DNA synthesis and it induced beta-casein and beta-casein mRNA accumulation in the tissue. As opposed to other anti-microtubule agents such as colchicine, estramustine was unable to prevent prolactin actions. An examination of the mammary cells by immunofluorescence revealed that the microtubule network was significantly altered under the influence of estramustine. These data indicate that the integrity of microtubules is not required for prolactin to deliver its message to the mammary cell. These data also suggest that other anti-microtubule drugs such as colchicine which prevent prolactin action act through their binding to tubulin molecule unrelated to microtubule structures.     

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.     

The differential actions of cortisol on the accumulation of α-lactalbumin and casein in midpregnant mouse mammary gland in culture

The dose-response relationship between cortisol and the accumulation of the two milk proteins, casein and α-lactalbumin, was studied in organ culture of mammary gland from midpregnant mice. The accumulation of casein was low in culture with insulin but was enhanced by the further addition of prolactin. Further increases in casein were effected by the addition of cortisol in increasing concentrations up to 3 × 10^?6 M, which was optimal for the accumulation of this protein. The content of α-lactalbumin in explants was similarly low in culture with insulin alone, but, in contrast, was increased to a maximal level by the addition of insulin and prolactin. The addition of cortisol up to 3 × 10^?8 M with insulin and prolactin did not further increase the level of α-lactalbumin; in fact, at concentrations above 3 × 10^?7 M the steroid caused progressive inhibition of the accumulation of this protein in cultured explants. Studies of the appearance of casein and α-lactalbumin in incubation medium during organ culture revealed the presence of substantial amounts of these milk proteins. During the first 2 days of culture with insulin, prolactin and 3 × 10^?6 M cortisol, the amount of α-lactalbumin in culture medium was almost equal to the level found in tissue, whereas in the presence of 3 × 10^?8 M cortisol, or in the absence of exogenous steroid, over 70% of total α-lactalbumin was retained in tissue. The observed difference in the amount of α-lactalbumin in culture medium can, however, only partially account for the inhibitory effect of high doses of cortisol on the accumulation of α-lactalbumin in cultured mammary explants. In contrast to α-lactalbumin, the relative amount of casein in culture medium containing insulin and prolactin was smaller—19% of total casein synthesized—and was further reduced to 16% and 11% of the total in the presence of 3 × 10^?8 M and 3 × 10^?6 M cortisol, respectively. The above results indicate that cortisol exerts dose-dependent differential actions on the accumulation of casein and α-lactalbumin in mouse mammary epithelium in vitro.     

Lactogenic response of mouse mammary explants from different days of pregnancy to placental lactogen and pituitary prolactin

The lactogenic response of mouse mammary gland explants to human placental lactogen (hPL) and ovine pituitary prolactin (oPRL) was examined on days 10 to 18 of pregnancy by measuring 3H-amino acid incorporation into calcium-rennin precipitable casein. To determine the lactogenic response of the explants, the mean slopes of dose-response curves were calculated for each hormone treatment. Slope means of dose-response curves for oPRL and hPL did not differ from each other on any day of pregnancy examined. A triphasic pattern of response was suggested when slope means of dose-response curves for both hormones were plotted as a function of day of gestation. Peak responses were observed on days 10, 13 and 17-18. Combinations of oPRL and hPL, in ratios of oPRL:hPL = 2:1 and oPRL:hPL = 1:2, also produced a triphasic pattern of sensitivity very similar to that produced by either hormone alone. These results suggest that mouse mammary explants may be more sensitive to oPRL and hPL on days 10, 13 and 17-18 of pregnancy.     

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.     

Inhibition of casein synthesis by progestagens in vitro: modulation in relation to concentration of hormones that synergize with prolactin

We studied the effect of progesterone and its agonist, R 5020, on casein and transferrin production in pregnant rabbit mammary gland explant culture and its modulation by hormones that synergize with prolactin. The glands were obtained from rabbits on days 12-14 of gestation. The progestins had no effect alone, but significantly inhibited ovine and porcine prolactin stimulation of casein synthesis in a dose dependent manner. There were no effects on transferrin content of the tissue, demonstrating a specific effect of progesterone on casein synthesis. In approx 15% of the cultures, prolactin stimulated casein production to very high levels and the progestins lost their inhibitory action. Progestins were also ineffective when the tissue was cultured with prolactin and unphysiologically high levels of insulin (5 mg/l) or cortisol (280 nmol/l), which stimulated casein synthesis to higher levels than prolactin alone. The concentration of cortisol used was 10 times higher than the serum levels seen in rabbits at the stage of gestation studied (approx 10 ng/ml) and corresponded to levels seen at the end of gestation, a period when the glands are secreting milk and progesterone serum levels have commenced to decrease. Thus, when the prolactin effect upon casein synthesis had been potentiated, whether spontaneously or through synergism with insulin or corticoids, progestins were unable to inhibit it, as is the case in lactating tissues. The results show that utilization of unphysiological levels of hormones in culture may distort the response of the tissue, masking responses that are clearly seen in vivo.     

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.     

Pituitary-induced lactation in mammary gland explants from the pregnant tammar (Macropus eugenii): a negative role for cyclic AMP

1. alpha-Lactalbumin and casein have been isolated from tammar milk. 2. alpha-Lactalbumin was induced in mammary explants by culture with anterior pituitary. 3. Casein was induced maximally in the presence of a physiological concentration of prolactin alone. 4. Progesterone did not inhibit the prolactin-induced synthesis of casein, alpha-lactalbumin, galactosyltransferase or fatty acids. 5. Both dibutyryl cAMP and a combination of cholera toxin and IBMX did significantly inhibit the induction of casein and alpha-lactalbumin. 6. Progesterone withdrawal is not a component of the lactogenic trigger in this marsupial but cAMP may be a common intracellular signal for negative control of lactogenesis in both marsupials and eutherians.     

The effect of calcium on synthesis and degradation of mammary cytosolic proteins and casein

In mammary explants prepared from mid-pregnant rabbits, rates of intracellular and secretory protein synthesis and degradation can be manipulated by the addition or removal of hormones (insulin, prolactin, cortisol). Under both culture conditions, depletion of extracellular calcium with EGTA markedly decreases cytosolic protein synthesis and degradation, and also decreases the rate of synthesis of casein. Culture of explants in calcium-free medium also inhibits cytosolic protein synthesis, but has no significant effect on protein degradation, either in the presence or the absence of hormones. The results suggest that mammary protein synthesis and degradation may be affected by changes in the intracellular concentration or distribution of calcium.     

Substrate specificity of a high-affinity, monovalent cation-dependent amino acid carrier.

When mammary gland explants from mid-pregnant rats were incubated with insulin (5 μg/ml) and [³H]cortisol (5 μg/ml) for one day, the tissue accumulated 1.69 μg cortisol/g wet tissue. During a second incubation with insulin and prolactin (5 μg/ml), only 20% of the steroid was lost per day. Such retention of glucocorticoid had an important biological consequence: the tissue exposed for one day to insulin and cortisol showed a transient stimulation of casein synthesis during a subsequent, five-day incubation with insulin and prolactin. No casein synthesis was detected, if the first culture medium contained only insulin. In conclusion, mammary gland explants from mid-pregnant rats require a glucocorticoid for casein synthesis, but this requirement may be obscured if the explants are initially incubated in medium containing cortisol, since they are capable of accumulating and retaining this steroid. Similar interpretative difficulties may arise in studies on other steroid-tissue relationships.     

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.     

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.