The effects of hormones on milk-fat synthesis in mammary explants from pseudopregnant rabbits

1. When freshly prepared explants from pseudopregnant-rabbit mammary gland were incubated with sodium [1-¹⁴C]acetate plus glucose, they synthesized triglyceride and phospholipid containing long-chain fatty acids. Explants cultured with insulin and corticosterone also synthesized these products. The addition of prolactin to this culture medium increased the rate of fatty acid synthesis up to 40-fold and the explants synthesized predominantly triglyceride enriched with C_8:0 and C_10:0 fatty acids characteristic of rabbit milk. 2. The maximum rates of fatty acid synthesis obtained by explants from pseudopregnant-rabbit mammary gland after culture with insulin, corticosterone and prolactin were similar to those observed with freshly prepared explants from lactating-rabbit mammary gland. The time in culture required to attain these maximum rates varied between animals, and did not appear to be connected with the time required (6–7 days) to synthesize the maximum proportions of C_8:0 and C_10:0 acids. 3. As the pattern of short- and medium-chain milk fatty acids is characteristic for many species, the techniques described to determine the time-course for the development of this pattern can be used to investigate hormonal response.     

Inhibition by low concentrations of ouabain of prolactin-induced lactogenesis in rabbit mammary-gland explants

1. Explants of mammary tissue from pseudopregnant rabbits were cultured at 37 degrees C in air for 24-48h in Medium 199 buffered with 20mm-Hepes [4-(2-hydroxyethyl)-1-piperazine-ethanesulphonic acid]. The medium contained insulin and corticosterone, or insulin, corticosterone and sheep prolactin in the presence or absence of ouabain, an inhibitor of Na(+)/K(+)-dependent adenosine triphosphatase. The responses of explants were assessed histologically, by measuring the tissue concentration of K(+), and by rates of synthesis of RNA, protein and fatty acids. The effect of ouabain on Na(+) and K(+) concentrations in slices of lactating rabbit mammary-gland tissue incubated for 1h at 37 degrees C in Krebs bicarbonate buffer was also studied. 2. Prolactin increased the concentration of K(+) in mammary explants, an effect prevented by ouabain. In slices of lactating tissue, there was a linear relationship between the log dose of ouabain (from 0.1 to 10mum) and increased Na(+) and decreased K(+) concentrations in the tissue. 3. Ouabain at concentrations up to 1mum did not affect the rate of synthesis of RNA, protein or fatty acids by explants cultured with insulin and corticosterone. By contrast, the stimulatory effect of prolactin on protein synthesis was diminished and the induction of medium-chain fatty acid synthesis by prolactin was almost abolished. RNA synthesis was unaffected. Histological examination showed no tissue damage by 1mum-ouabain. 4. Explants cultured in the presence of 2mum-ouabain for 24h retained their ability to respond to prolactin when the ouabain was removed from the culture medium. Between 24 and 48h they showed responses to prolactin of a magnitude similar to those of explants never exposed to ouabain. 5. These results show that a fully functional Na(+)/K(+)-dependent adenosine triphosphatase system is necessary for prolactin to promote secretory activity in rabbit mammary gland.     

The effect of progesterone on prolactin stimulation of fatty acid synthesis, glycerolipid synthesis and lipogenic-enzyme activities in mammary glands of pseudopregnant rabbits, after explant culture or intraductal injection.

The activities of lipogenic enzymes, such as acetyl-CoA carboxylase, fatty acid synthetase and glucose-6-phosphate dehydrogenase, and glycerolipid synthesis increased significantly in mammary explants of 11-day-pseudopregnant rabbits in response to prolactin, in the presence of near-physiological concentrations of insulin and corticosterone in culture. Increasing the concentration of progesterone in culture resulted in suppression of glycerolipid synthesis and activities of acetyl-CoA carboxylase and fatty acid synthetase, but not the pentose phosphate dehydrogenases. However, at near-physiological concentration of progesterone, only acetyl-CoA carboxylase activity was decreased. Injection of prolactin intraductally into 11-day-pseudopregnant rabbits stimulated glycerolipid synthesis, fatty acid synthesis and enzymes involved in fatty acid synthesis, after 3 days. Intraductal injection of progesterone separately or together with prolactin had no significant effect on basal or stimulated lipogenesis in mammary glands. Intramuscular injection of progesterone at 10 mg/day did not suppress fatty acid synthesis stimulated when prolactin was injected intraductally, but a significant inhibition was observed at a higher dose (80 mg/day).     

Fatty acid biosynthesis in rabbit mammary gland during pregnancy and early lactation

The pattern of fatty acids synthesized by mammary-gland explants from rabbits during pregnancy and early lactation has been studied. From day 12 to day 18 of pregnancy, long-chain (C(14:0)-C(18:1)) fatty acids were the major products. From day 18 to day 21 of pregnancy there was an increase of up to 12-fold in the rate of fatty acid synthesis per unit wet weight of tissue that was almost exclusively caused by the synthesis of octanoic fatty acid and decanoic fatty acid, which are characteristic of rabbit milk. These medium-chain fatty acids were mainly incorporated into triglycerides. From day 22 to day 27 of pregnancy there was little change in the rate of fatty acid synthesis and the proportions of fatty acids synthesized were essentially the same as those synthesized by the lactating gland, i.e. 80-90% octanoic acid plus decanoic acid. About 2-4 days before parturition a second lipogenic stimulus occurred, although the pattern of fatty acids synthesized did not change.     

Regulation of enzyme turnover during tissue differention. Studies on the effects of hormones on the turnover of fatty acid synthetase in rabbit mammary gland in organ culture.

1. Explants of mammary gland from mid-pregnant rabbits were cultured with insulin, prolactin and cortisol. 2. Antibodies raised to fatty acid synthetase were used to measure the amount as well as the rate of synthesis and the rate of degradation of the enzyme in the explants over defined periods in organ culture. These measurements were also made after the hormones had been removed from the culture medium. The changes which occur in the activity of fatty acid synthetase are due to changes in the amount of the enzyme present. They are not due to activation or inactivation of the enzyme. 3. The rate of lipogenesis (measured from [1-14C]acetate) in the explants during culture varies independently of the amount of fatty acid synthetase both in the presence and after removal of the hormones. Hence the amount of fatty acid synthetase does not limit lipogenesis. The proportion of medium-chain fatty acids C8:0 and C10:0 (which are characteristic of rabbit milk) synthesized by the explants in the presence of hormones increases at about the same rate as the amount of fatty acid synthetase present. However, when hormones are removed from the medium the proportion of these acids synthesized declines as rapidly as the rate of lipogenesis and not as the amount of fatty acid synthetase presen. 4. The rates of synthesis of fatty acid synthetase and of the total particulate-free supernatant protein in the explants were compared by measuring the incorporation of L-[U-14C]leucine into the protein of the explants. These rates increase by 5-fold and 3.6-fold respectively when explants are cultured with hormones, and they then reach approximately constant rates. When the hormones are removed there is a rapid fall in the rate of synthesis of fatty acid synthetase and of the total particulate-free supernatant protein to values which are similar to those obtained with freshly prepared explanted tissue. 5. In unstimulated explants fatty acid synthetase appears to be degraded with a half-life of 15-21h. During the hormonally stimulated differentiation of the tissue the rate of degradation of the enzyme is considerably decreased or is switched off completely. After the amount of fatty acid synthetase has increased to a maximum the enzyme complex is again degraded with a half-life of 23-29h. The removal of hormones after the explants have been hormonally stimulated for different times results in an increase in the rate of degradation of fatty acid synthetase. However, this increase only occurs if degradation was previously proceeding at a considerably decreased rate. The degradation of the total particulate-free supernatant protein continues throughout the period of differentiation of the explant tissue in culture. It appears to be somewhat decreased during the period of rapid maturation of the tissue during culture.     

The endocrine regulation of milk lipid synthesis and secretion in tammar wallaby (Macropus eugenii)

Lipids in tammar milk are predominantly triacylglycerols, and the fatty acid composition varies during the lactation cycle. Little is known about the regulation of their synthesis. This study investigates the endocrine regulation of lipid synthesis in mammary explants from pregnant tammars. Treatment of mammary explants with insulin resulted in a high level of lipid synthesis, but the lipids accumulated in the cytosol. Culture with prolactin resulted in a small increase in lipid synthesis, but electron microscopy showed lipid globules were synthesized in the mammary epithelial cells and secreted into the lumen. Culture with both insulin and prolactin demonstrated elevated levels of synthesis and secretion of lipid. Analysis of the type of fatty acids synthesized in these mammary explants showed that the initiation of synthesis of C(16:0), which also occurs in the first week of lactation, could be reproduced in the pregnant explants cultured with prolactin alone. However, treatment of mammary explants with hydrocortisone did not show a significant effect on lipid synthesis, secretion or the fatty acid synthesized. These results provide new information identifying the role of insulin and prolactin in regulating milk lipid synthesis and secretion in the tammar.     

The endocrine regulation of milk lipid synthesis and secretion in tammar wallaby (Macropus eugenii)

Lipids in tammar milk are predominantly triacylglycerols, and the fatty acid composition varies during the lactation cycle. Little is known about the regulation of their synthesis. This study investigates the endocrine regulation of lipid synthesis in mammary explants from pregnant tammars. Treatment of mammary explants with insulin resulted in a high level of lipid synthesis, but the lipids accumulated in the cytosol. Culture with prolactin resulted in a small increase in lipid synthesis, but electron microscopy showed lipid globules were synthesized in the mammary epithelial cells and secreted into the lumen. Culture with both insulin and prolactin demonstrated elevated levels of synthesis and secretion of lipid. Analysis of the type of fatty acids synthesized in these mammary explants showed that the initiation of synthesis of C_16:0, which also occurs in the first week of lactation, could be reproduced in the pregnant explants cultured with prolactin alone. However, treatment of mammary explants with hydrocortisone did not show a significant effect on lipid synthesis, secretion or the fatty acid synthesized. These results provide new information identifying the role of insulin and prolactin in regulating milk lipid synthesis and secretion in the tammar.     

Medium-chain fatty acid synthesis in lactating-rabbit mammary gland. Intracellular concentration and specificity of medium-chain acyl thioester hydrolase.

The concentration of medium-chain acyl thioester hydrolase and of fatty acid synthetase was determined by rocket immunoelectrophoresis in nine different particle-free supernatant fractions from lactating-rabbit mammary gland. The molar ratio of the hydrolase to fatty acid synthetase was 1.99 +/- 0.66 (mean +/- S.D.). A rate-limiting concentration of malonyl-CoA was required to ensure the predominant synthesis of medium-chain fatty acids when 2 mol of the hydrolase was added per mol of fatty acid synthetase. The interaction of the hydrolase with fatty acid synthetase was concentration-dependent, though an optimum concentration of hydrolase to synthetase could not be obtained. The lactating-rabbit mammary gland hydrolase altered the pattern of fatty acids synthesized by fatty acid synthetases prepared from cow, goat, sheep and rabbit lactating mammary glands, rabbit liver and cow adipose tissue.     

Novel multialveolar epithelial structures from rabbit mammary gland that synthesize milk specific fatty acids in response to prolactin

Multialveolar mammary epithelial structures have been prepared from rabbit mammary gland by treating the tissue with collagenase plus hyaluronidase. These structures synthesize milk specific fatty acids when cultured with physiological concentrations (0.5 micrograms/ml) of prolactin in the presence of insulin and corticosterone. They have many of the advantages but few of the disadvantages of either mammary explants or primary cells in culture. For example, they are easily prepared in large numbers and respond to prolactin in culture even in the absence of serum or other tissue extracts. Because their level of organization is intermediate between that of explants and single cells, they provide a complementary system for studies on mammary differentiation.     

Immunological properties of medium-chain acyl-thioester hydrolase and fatty acid synthetase from lactating-rabbit mammary gland.

The cytosol from lactating-rabbit mammary gland contains a medium-chain acyl-thioester hydrolase. This hydrolase terminates chain lengthening of the fatty acids synthesised by fatty acid synthetase so as to release C8:0 and C10:0 fatty acids which are characteristic of rabbit milk. The medium-chain hydrolase and the fatty acid synthetase present in this cytosol have been shown to be immunologically distinct. When fatty acid synthetase was purified from this cytosol it showed unexpected immunological reactivity towards antiserum raised to the medium-chain hydrolase. The precipitate formed was not due to fatty acid synthetase, but to medium-chain hydrolase contaminating the synthetase. However, the proportion of this medium-chain hydrolase which was recovered with the purified synthetase was too small to be detected by sodium dodecyl sulphate-polyacrylamide gel electrophoresis, and was too small to elicit an antibody response in sheep. Immunological techniques have shown that the medium-chain hydrolase appears in rabbit mammary gland between days 17 and 22 of pregnancy. This coincides with the onset of milk-fat synthesis. The medium-chain hydrolase could not be detected in the cytosol from lactating-rabbit liver.     

Biosynthesis of medium-chain fatty acids by mammary epithelial cells from virgin rats.

Epithelial cells were isolated from the undifferentiated mammary glands of mature virgin female rats, and their lipogenic characteristics were studied. These cells synthesized predominantly medium-chain fatty acids, albeit at a low rate. In contrast, whole tissue from mammary glands of virgin rats synthesized predominantly long-chain fatty acids at a relatively higher rate, indicating that the lipogenic activity is dominated by the adipocyte component of the gland. Enzyme assays revealed that thioesterase II, the enzyme which regulates production of medium-chain fatty acids by the fatty acid synthetase, was present at a high activity in the undifferentiated mammary epithelial cells of virgin rats. Immunohistochemical studies confirmed this observation and showed that the regulatory enzyme was present exclusively in the epithelial cells lining the alveolar and ductal elements of the undifferentiated gland. This study demonstrates that the potential to elaborate tissue-specific medium-chain fatty acids is already expressed in the undifferentiated tissue of virgin rats and is not acquired as a result of the differentiation associated with the lactogenic phase of development. In this species mammary epithelial cells apparently synthesize predominantly medium-chain fatty acids at all stages of development, and only the overall rate of synthesis is increased on induction of the fatty acid synthetase during lactogenesis.     

Dietary regulation of mammary lipogenesis in lactating rats.

The proportion of medium-chain fatty acids (C8:0, C10:0 and C12:0) in rat milk increased significantly between day 4 and day 8 of lactation and for the remainder of lactation these acids comprised 40-50mol% of the total fatty acids. The milk fatty acid composition from day 8 was markedly dependent on the presence of dietary fat and altered to include the major fatty acids of the fats (peanut oil, coconut oil and linseed oil). The distribution of fatty acids made within the gland, however, was independent of dietary lipid and C8:0, C10:0 and C12:0 acids accounted for over 70% of the fatty acids made. The rates of lipogenesis in both the mammary gland and liver determined in vivo after the administration of 3H2O were affected by the presence of dietary lipid. In the mammary gland the rate for rats fed a diet containing peanut oil for 7 days was only one fifth that for rats fed a fat-free diet. Coconut oil also suppressed lipogenesis. Both dietary fats also suppressed lipogenesis in the liver.     

Effects of cyclic nucleotides on lipid biosynthesis in mouse mammary gland explants

The effects of dibutyryl cAMP, 1-methyl-3-isobutyl xanthine (MIX), cGMP, dibutyryl cGMP, and 8-bromo cGMP on the rate of lipid synthesis in mouse mammary gland explants were studied. Dibutyryl cAMP at 10(-4) M selectively inhibited the effect of prolactin on the rate of [14C]acetate incorporation into lipids. At 10(-3) M, dB-cAMP inhibited the effects of insulin, insulin plus cortisol, and prolactin. The phosphodiesterase inhibitor, MIX, inhibited both basal and prolactin-stimulated incorporation rates in a concentration-dependent fashion. These data suggest an inhibitory role for cAMP in the regulation of lipogenesis in the mammary gland. Cyclic GMP, db-cGMP, and 8-bromo cGMP were all without effect on either basal or prolactin-stimulated incorporation rates. Therefore, it appears that cGMP, by itself, is not involved in the regulation of lipogenesis in the mammary gland.     

Rapid inhibition of lipogenesis in vivo in lactating rat mammary gland by medium- or long-chain triacylglycerols and partial reversal by insulin.

An intragastric load of medium- or long-chain triacylglycerols inhibited lipogenesis in lactating rat mammary gland in vivo by 82 or 89% respectively. This inhibition was reversed partially by insulin administration. Long-chain triacylglycerols inhibited hepatic lipogenesis in vivo but medium-chain triacylglycerols increased it 2-fold. Glucose utilization in vitro by mammary gland acini from triacylglycerol-fed rat was normal.     

Evidence for a role of insulin in the regulation of lipogenesis in lactating rat mammary gland. Measurements of lipogenesis in vivo and plasma hormone concentrations in response to starvation and refeeding.

Fatty acid synthesis in the mammary gland of lactating rats in vivo was 5-fold higher than in the liver. Starvation decreased fatty acid synthesis in the gland 50-fold, whereas refeeding for 2h completely reversed this change. The plasma insulin concentration decreased 2-fold in starvation and was restored to the fed-rat value on refeeding. Glucagon and prolactin concentrations did not always change in parallel with lipogenesis, suggesting that insulin may be a regulator of this process in the gland.     

Regulation of enzyme turnover during tissue differentiation. Interactions of insulin, prolactin and cortisol in controlling the turnover of fatty acid synthetase in rabbit mammary gland in organ culture

1. Explants of mammary gland from mid-pregnant rabbits were cultured in Medium 199 containing combinations of insulin, prolactin and cortisol. With hormone combinations which included prolactin, a sustained increase in the apparent rate of synthesis and in the amount of fatty acid synthetase was measurable immunologically. Maximum increase was produced with insulin, prolactin and cortisol present together. 2. With prolactin present alone, synthetase activity in the explants decreased to undetectable values after 1 day in culture, whereas the incorporation of l-[U-(14)C]leucine into immunodetectable material increased. Prolactin may therefore direct the synthesis of immunologically cross-reactive precursors of fatty acid synthetase which are enzymically inactive. 3. Culture with dibutyryl cyclic AMP plus theophylline in the presence of insulin, prolactin and cortisol delayed the increase in the rate of synthesis and accumulation of the synthetase. These compounds may also prevent the apparent decrease in the rate of degradation of the synthetase which occurs on day 2 of culture. 4. A large decrease in the apparent rate of degradation of the synthetase on day 2 of culture occurs during culture with hormone combinations which include prolactin. The protein obtained by centrifugation of explant homogenates for 6min at 14000g(av.) is degraded continuously throughout the culture period. 5. This decrease in the apparent rate of degradation of the synthetase was measured by radio-immunological precipitation. It is probably part of a regulated programme of enzyme degradation and not a reflexion of the reutilization of radioactive amino acids for the following reasons. (a) The calculated increase in the amount of the synthetase in explants on day 2 of culture with insulin, prolactin and cortisol was approximately equal to the measured increase of the enzyme complex which accumulates in the explants. This suggests little or no enzyme degradation has occurred. (b) Explants were cultured for 24h with insulin, prolactin and cortisol. They were then incubated with l-[U-(14)C]leucine, washed and incubated again for up to 4(1/2)h. l-[U-(14)C]Leucine rapidly equilibrated with the intracellular amino acid pool. Within 10min of incubation after washing explants to remove endogenous l-[U-(14)C]leucine the previously linear incorporation of l-[U-(14)C]-leucine into total explant protein ceased. This suggests that protein is synthesized from an amino acid pool which rapidly equilibrates with amino acids in the culture medium. (c) Explants were cultured for 24h as described in (b) but after washing they were cultured with insulin, prolactin and cortisol for 24h. Approx. 90% of the radioactivity lost from the ;free' intracellular amino acid pool and from amino acids derived from the degradation of explant protein in this period was detected in the culture medium. This suggests that the ;free' intracellular amino acids and amino acids derived from protein degradation can equilibrate with amino acids in the medium. A residual ;free' radioactive amino acid pool was present in the tissue. (d) Casein represents approx. 20% of the protein synthesized after 1 day in culture with insulin, prolactin and cortisol. Histological evidence suggests that on day 2 of culture, casein is unlikely to be degraded in the tissue. No increase in the radioactivity incorporated into casein can be measured in the 23h after incubation of explants with l-[U-(14)C]leucine as described in (b). This suggests that the incorporation of radioactivity into proteins during culture after incubation with l-[U-(14)C]leucine is minimal. (e) Inhibition of protein synthesis in explants by cycloheximide after incubation with l-[U-(14)C]leucine does not reveal a latent continuous degradation of fatty acid synthetase on day 2 of culture which might have been masked by the high rates of protein synthesis and therefore the accumulation of the enzyme. 6. The conclusion is discussed that there is a real decrease (or even cessation) in the rate of degradation of fatty acid synthetase during the period when the enzyme accumulates in explants cultured with hormone combinations which contain prolactin.     

Hormone-Stimulated Iipid Synthesis in Mammary Culture

Mammary explants from midpregnant mice were cultured for upto 96 hr with various combinations of insulin, prolactin, andcorticosterone. Labeled glucose was added to cultures at 4 hrprior to termination, and explant morphology, glucose uptake,and lipid synthesis were studied in hormone-free and hormone-containingmedia. The results show that without hormones, explants takeup glucose and synthesize lipid at minimal rates. After 48 hrthese activities appear to be primarily those of adipose tissuesince epithelial and connective tissue degenerate without hormones. Insulin increases cell number for 24 hr and maintains survivalfor 96 hr. Its stimulatory effect on lipogenesis precedes itsenhancement of glucose uptake. The addition of prolactin toinsulin-containing cultures has little effect on glucose uptakeand lipogenesis, but stimulates minimal secretion in alveolarlumina. The absence of intracellular vacuoles indicates thatthese products probably contain little lipid. Corticosteroneenhances the effects of insulin on lipid synthesis, but haslittle apparent effect on the secretory morphology of the alveoli. The three-hormone combination has no effect on glucose uptakeabove that obtained with insulin alone; however, it inducesmarked increases in Iipid synthesis as well as maximal morphologicalsecretion by 48 hr. Thus, as for other lactogenic responsesin vitro, insulin, prolactin, and corticosterone act synergisticallyto stimulate lipid synthesis in mammary explants.     

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.     

Novel multialveolar epithelial structures from rabbit mammary gland that synthesize milk specific fatty acids in response to prolactin

Summary Multialveolar mammary epithelial structures have been prepared from rabbit mammary gland by treating the tissue with collagenase plus hyaluronidase. These structures synthesize milk specific fatty acids when cultured with physiological concentrations (0.05 μg/ml) of prolactin in the presence of insulin and corticosterone. They have many of the advantages but few of the disadvantages of either mammary explains or primary cells in culture. For example, they are easily prepared in large numbers and respond to prolactin in culture even in the absence or other tissue extracts. Because their level of organization is intermediate between that of explants and single cells, they provide a complementary system for studies on mammary differentiation. This work was supported by grants from the Agricultural Research Council of Great Britain and the Royal Society to R. R. Dils, by U.S. Public Health Service Grant CA-16392, and an American Cancer Society-Eleanor Roosevelt International Cancer Fellowship to H. L. Hosick. Prolactin was a gift from the Endocrinology Study Section, National Institutes of Health, Bethesda, MD.     

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.