Mammary gland secretion: hormonal coordination of endocytosis and exocytosis.

The mammary epithelium coordinates the uptake of milk precursors and the transport of milk components in order to produce milk of relatively constant composition at a particular stage of lactation, as long as the mammary gland is healthy. The mammary epithelial cell controls the uptake of blood-borne molecules at its basal side and the release of products into milk at its apical side, through mechanisms of internalization (endocytosis) and mechanisms of release (exocytosis). These events are strictly dependent on the physiological stage of the mammary gland. This review addresses the mechanisms responsible for these processes and points out new questions that remain to be answered concerning possible interconnections between them, for an optimal milk secretion.

Prolactin signalling to milk protein secretion but not to gene expression depends on the integrity of the Golgi region.

Prolactin added to the incubation medium of lactating mammary epithelial cells is transported from the basal to the apical region of cells through the Golgi region and concomitantly stimulates arachidonic acid release and protein milk secretion. We report that when PRL is added after disorganisation of the Golgi apparatus by brefeldin A treatment, prolactin signalling to expression of genes for milk proteins and prolactin endocytosis are not affected. However, prolactin transport to the apical region of cells (transcytosis), as well as prolactin-induced arachidonic acid release and subsequent stimulation of the secretion of caseins, which are located in a post-Golgi compartment, are inhibited. This inhibition was not a consequence of damage to the secretory machinery, as under the same conditions, protein secretion could be stimulated by the addition of arachidonic acid to the incubation medium. Thus, it is possible to discriminate between prolactin-induced actions that are dependent (signalling to milk protein secretion) or independent (signalling to milk gene expression) on the integrity of the Golgi apparatus. These results suggest that these two biological actions may be transduced via distinct intracellular pathways, and support the hypothesis that prolactin signals may be emitted at various cellular sites.

Targeting of PKA in mammary epithelial cells. Mechanisms and functional consequences.

Targeting of protein kinases, promoting association with specific partner-molecules and localisation to particular sites within the cell, has come to be recognised as a key mechanism for attributing specificity to these enzymes. In mammary epithelial cells, the repertoire of acute regulatory roles played by cyclic AMP-dependent protein kinase (PKA) differs from that in other lipogenic cell-types. Furthermore, PKA is implicated in the regulation of mammary-specific function, mediating a tonic stimulation of the flux of newly-synthesised casein through its basal secretory pathway. Both these observations imply mammary-specific properties of either PKA targeting systems or of PKA itself. Evidence for the latter is currently lacking. Pulse-chase labelling experiments in the presence and absence of selective effectors of PKA have enabled the site(s) of action of this protein kinase on casein secretion to be localised to the early stages of the secretory pathway. Possible mechanisms are considered for the physical targeting of PKA to the membrane-enclosed components of the secretory pathway and evidence for their occurrence in mammary epithelial cells is presented.

High expression of the human hepatocarcinoma-intestine-pancreas/pancreatic-associated protein (HIP/PAP) gene in the mammary gland of lactating transgenic mice. Secretion into the milk and purification of the HIP/PAP lectin.

The human hepatocarcinoma-intestine-pancreas/pancreatic-associated protein (HIP/PAP) gene was previously identified because of its increased expression in primary liver cancers and during the acute phase of pancreatitis. In normal tissues, HIP/PAP is expressed both in endocrine and exocrine cells of the intestine and pancreas. HIP/PAP is a lactose binding C-type lectin which acts as an adhesion molecule for rat hepatocytes. The aim of the work was to study the HIP/PAP secretory pathway and to produce high levels of HIP/PAP in the milk of lactating transgenic mice. In view of its lactose C-type lectin properties, we have studied the consequences of the expression of HIP/PAP on mammary epithelial cells. In homozygous mice, production reached 11.2 mg.mL-1 of milk. High levels of soluble and pure HIP/PAP (18.6 mg) were purified from 29 mL of milk. The purified protein was sequenced and the N-terminal amino acid of the mature HIP/PAP was identified as Glu27, thus localizing the site of cleavage of the signal peptide. The HIP/PAP transgene was only expressed in the mammary gland of lactating transgenic mice. HIP/PAP was detected by immunofluorescence in the whole gland, but labelling was heterogeneous between alveolar clusters, with strongly positive sparse cells. Using immuno electron microscopy, HIP/PAP was observed in all the compartments of the secretory pathway within the mammary epithelial cells. We provide evidence that HIP/PAP is secreted through the Golgi pathway. However, the number of distended Golgi saccules was increased when compared to that found in wild-type mouse mammary cells. These modifications could be related to HIP/PAP C-type lectin specific properties.

The majority of clathrin coated vesicles from lactating rabbit mammary gland arises from the secretory pathway.

Clathrin coated vesicles were isolated from lactating rabbit mammary gland by differential centrifugation, centrifugation on (2)H2O-sucrose cushions and Sephacryl S-1000 chromatography. Mammary epithelial cells contain an unexpectedly high quantity of clathrin coated vesicles which appear heterogeneous in size, with a mean diameter of 95.9+/-10.5 nm and a density of 1.23 g x ml(-1). Analysis of clathrin coated vesicle adaptor composition by SDS-PAGE and western blot showed that only approximately 5-10% of total APs consist of AP-2 in isolated mammary gland clathrin coated vesicles whereas it represents approximately 70% of the total APs from bovine brain clathrin coated vesicles. Cargo molecules known to be transcytosed such as IgG, IgA, and the pIgR were detected in the clathrin coated vesicles, indicating that part of this vesicle population is involved in transcytotic pathways. However, as the vast majority of the clathrin coated vesicles contained AP-1, it was likely that these clathrin coated vesicles were involved in the secretory pathway. Relatively high quantities of furin and cation-independent mannose 6-phosphate receptor were detected in mammary clathrin coated vesicles. By immuno electron microscopy, AP-1 and the cation-independent mannose 6-phosphate receptor were localized in Golgi-associated vesicles and on the membrane of secretory vesicles. The presence of AP-1 in the coat patches on the membrane of secretory vesicles containing casein micelles, and the presence of alpha(s1)-casein in mammary gland clathrin coated vesicles, support a role for AP-1 in the maturation of secretory vesicles. Our data pinpoint the importance of clathrin coated vesicles in lactating mammary epithelial cells, and suggest these vesicles are involved in the transcytotic pathway, in sorting at the trans-Golgi network and in the biogenesis of casein-containing secretory vesicles.

Alpha(S1)-casein is required for the efficient transport of beta- and kappa-casein from the endoplasmic reticulum to the Golgi apparatus of mammary epithelial cells.

In lactating mammary epithelial cells, interaction between caseins is believed to occur after their transport out of the endoplasmic reticulum. We show here that, in alpha(S1)-casein-deficient goats, the rate of transport of the other caseins to the Golgi apparatus is highly reduced whereas secretion of whey proteins is not significantly affected. This leads to accumulation of immature caseins in distended rough endoplasmic reticulum cisternae. Casein micelles, nevertheless, were still observed in secretory vesicles. In contrast, no accumulation was found in mammary epithelial cells which lack beta-casein. In mammary epithelial cells secreting an intermediate amount of alpha(S1)-casein, less casein accumulated in the rough endoplasmic reticulum, and the transport of alpha(S1)-casein to the Golgi occurred with kinetics similar to that of control cells. In prolactin-treated mouse mammary epithelial HC11 cells, which do not express alpha(S)-caseins, endoplasmic reticulum accumulation of beta-casein was also observed. The amount of several endoplasmic reticulum-resident proteins increased in conjunction with casein accumulation. Finally, the permeabilization of rough endoplasmic reticulum vesicles allowed the recovery of the accumulated caseins in soluble form. We conclude that optimal export of the caseins out of the endoplasmic reticulum is dependent upon alpha(S1)-casein. Our data suggest that alpha(S1)-casein interacts with the other caseins in the rough endoplasmic reticulum and that the formation of this complex is required for their efficient export to the Golgi.

Casein secretion in mammary tissue: tonic regulation of basal secretion by protein kinase A.

Despite its quantitative importance in the secretion of lactoproteins, little is known about the triggering and control mechanisms that initiate, regulate and terminate the operation of the basal pathway of lactoprotein secretion throughout the lactation cycle. This study investigated the possible modulation by cAMP-mediated mechanisms, of cellular transit of newly-synthesised caseins and their basal secretion in explants of mammary tissue from lactating rats and rabbits. Enhancement of the rate of secretion of newly-synthesised caseins occurs when mammary explants are challenged in vitro with agents that activate protein kinase A (PKA). Inhibition of PKA slows casein secretion. The PKA-sensitive step(s) in casein secretion is early in the exocytosis pathway but inhibition of PKA does not impair casein maturation. Ultrastructural, immunochemical and biochemical methods locate PKA on membranes of vesicles situated in the Golgi region. Exposure of tissue to a cell-permeant PKA inhibitor results in morphological modification of these vesicular structures. We conclude that PKA mediates tonic positive regulation of the basal secretory pathway for lactoproteins in the mammary epithelial cell.

Transferrin and prolactin transcytosis in the lactating mammary epithelial cell.

The mammary epithelial cell ferries constituents originating from blood and from stromal cells, into milk, by transcytosis. Morphological analysis of a membrane marker of transcytosis in the lactating mammary epithelial cell showed that very rapid endocytosis of surface membrane occurs from both the basolateral and the apical side of the cell. In both cases, membrane trafficking between endosomes and the Golgi complex allows communication between the endocytic and the biosynthetic pathways. Transferrin and prolactin are internalized in mammary cells and transported through multivesicular bodies and Golgi stacks. They are released into milk via different types of secretory vesicles, prolactin being carried in secretory vesicles containing casein micelles. Consequences of the intracellular transport of these proteins and physiological benefits for cell function are discussed.

Lipid-depleted diet perturbs membrane composition and intracellular transport in lactating mammary cells.

When rats were fed a control or a lipid-depleted diet for five generations, reproduction was not disturbed but pup growth was affected. The membrane organization and the secretory activity of mammary epithelial cells from these lactating rats were investigated. This diet induced a large decrease in the level of polyunsaturated fatty acids of membrane phospholipids (26.6% versus 44.0%). The level of 20:4 (n-6) was strongly decreased, mainly in phosphatidylethanolamine. Annexin VI, which interacts preferentially with this phospholipid, accumulated at the periphery of the cell and was largely associated to the hydrophobic region of the bilayer as compared to control membranes. Casein synthesis and casein secretion measured in incubated explants, after pulse-chase metabolic labeling, were both reduced by about 60% in lipid-deprived cells. The secretory ratio (radioactive secreted caseins in %) was not modified, suggesting that the mechanism of basal secretion was not mainly affected. On the contrary, the secretagogue effect of prolactin disappeared. The intracellular transport of the hormone was considerably slowed down by the diet and prolactin did not reach the lumen of the acini after 1 h of chase, in contrast to what occurred in control cells. Addition of 20:4 (n-6), in vitro, to mammary fragments from lipid-deprived rats restored the localization of annexin VI, increased synthesis and secretion of caseins as well as intracellular transport of PRI. Together, these data underline the importance of the level of 20:4 (n-6) in membrane phospholipids for exocytic and endocytic transport in lactating mammary epithelial cells.

Brefeldin A differently affects basal and prolactin-stimulated milk protein secretion in lactating rabbit mammary epithelial cells.

When lactating mammary epithelial cells were treated with prolactin in vitro, numerous small vesicles rapidly accumulated in the Golgi area, and secretion of milk proteins increased. The effects of brefeldin A on these intracellular events were investigated. As observed by electron microscopy, stacks of the median Golgi were not altered after incubation in the presence of 50 nM brefeldin A but were dissociated when the drug concentration was > or = 500 nM. Small vesicles did not accumulate in the Golgi area when mammary cells were incubated in medium containing both prolactin and brefeldin A, whatever the concentration of the latter. Immunofluorescence experiments showed that 50 nM brefeldin A did not modify the localization of the CTR 433 median Golgi protein, but it induced redistribution of trans-Golgi network-associated proteins such as TGN38, AP-1 adaptor and clathrin. These effects occurred in the presence of brefeldin A plus prolactin. Pulse-chase experiments showed that brefeldin A concentrations > or = 100 nM induced the intracellular accumulation of milk proteins, provoked the appearance of immature forms of caseins, and inhibited milk protein secretion. In contrast, concentrations of brefeldin A of < or = 50 nM did not affect basal casein secretion but inhibited the secretagogue effect of prolactin. These data show not only that several biochemical events in the transport of milk proteins which are sensitive to different brefeldin A concentrations occur in lactating mammary epithelial cells, but also that it is possible to inhibit a hormonal stimulus in a selective manner, while the machinery responsible for basal secretion is still active.

Rat prolactin synthesis by lactating mammary epithelial cells.

It has previously been suggested that the mammary cell could produce prolactin (PRL). This hypothesis was investigated by incubation with [35S]methionine-cysteine followed by SDS-PAGE, immunoblotting and autoradiography of immunoprecipitated PRL, and by electron microscopic analysis after incubation without or with cycloheximide. Immunoreactive 14-, 23-, 25-, 32- and 36-kDa PRL forms were radioactive. By two-dimensional electrophoresis analysis, immunoreactive and radioactive spots, of about 25 kDa and high molecular weight, were also detected. After incubation of mammary epithelial cells with cycloheximide, immunogold electron microscopy showed a drastic decrease of labelling in organelles involved in synthesis and secretion, compared to those incubated in control medium. These results make it possible to conclude that lactating mammary tissue is able to synthesize PRL.

Intracellular routing and release of caseins and growth hormone produced into milk from transgenic mice.

Growth hormone (GH) secretion, in mammary tissue from transgenic mice, containing a chimeric gene composed of the regulatory region of whey acidic protein gene and the structural region of GH gene, was compared to casein secretion. GH was expressed in milk and for a small percentage (1:1000) in blood as revealed by SDS-polyacrylamide gel electrophoresis and radioimmunoassay. As attested by immunofluorescence and immunogold electron microscopy, caseins and GH followed the same secretory pathway. However, contrary to caseins, which are essentially in micellar form, GH was detected in a nonaggregated form in secretory vesicles and in the lumen of the acini. Newly synthesized caseins and GH were carried simultaneously, mainly to the lumen of the acini, but also to the base of the cell. Secretion of newly synthesized proteins was increased by prolactin (PRL). As shown by immunoblotting, the proportion of GH versus other proteins, secreted in the presence of PRL was not modified, suggesting that GH secretion is subjected to the same hormonal regulation by PRL as other milk proteins. These results show that, in lactating mammary epithelial cells from transgenic mice, a recombinant GH and the caseins are carried simultaneously to the lumen and suggest that secretion of both proteins is increased by PRL during the same time course. Transport of these newly synthesized proteins occurs also to the base of the cell.

Two monoclonal antibodies against prolactin-receptor are internalized in epithelial mammary cells without mimetic prolactin effect on casein secretion.

Prolactin exerts an early stimulatory effect on casein secretion which was qualified as a secretagogue effect. After binding to its receptor, the hormone transits intracellularly through the mammary epithelial cell. When this transit is slowed down the secretagogue effect does not occur. Different monoclonal antibodies which bind to the rabbit prolactin receptor have been previously developed. One of them (A917) mimics prolactin effect on casein gene expression. Another (M110) blocks this prolactin effect. In order to study the respective role of the hormone and its receptor, we have examined the binding of the two monoclonal antibodies (M110 and A917), labeled with biotin or colloidal gold, to the receptor of lactating rabbit mammary epithelial cells in incubation. Subsequently, the intracellular movement of these antibodies and the secretory response have been measured. Irrespective of the labeling (biotin or colloidal gold) or the preparation of tissues (fragments or enzymatically dissociated cells), M110 and A917 bound to the basal membrane of mammary epithelial cells. However, only M110 bound to apical membrane of dissociated cell when this membrane was in direct contact with the incubation medium, showing that the two antibodies discriminate the receptor located on the apical membrane. Following internalization, each antibody was carried via a peculiar pathway. M110 remained associated with the cells during a 1-h incubation, mainly in endosomes, multivesicular bodies and lysosomes like vesicles. In contrast, A917 was very quickly detectable in endosomes, multivesicular bodies and vesicles of the Golgi region and was carried throughout the cell to the lumen of the acini. M110 and A917 were extremely rare in secretory vesicles containing casein micelles.(ABSTRACT TRUNCATED AT 250 WORDS)

Deficiency of (n-6) but not (n-3) polyunsaturated fatty acids inhibits the secretagogue effect of prolactin in lactating rat mammary epithelial cells.

The repercussions of various kinds of dietary polyunsaturated fatty acid (PUFA) deficiencies on the fatty acid composition of membranes and on the secretory activity of lactating female rat mammary epithelial cells were investigated. Primiparous female rats were fed different PUFA diets from weaning: adequate (n-6) and (n-3) PUFA supply; overall PUFA deficiency; specific (n-6) PUFA deficiency or specific (n-3) PUFA deficiency. Mammary gland phospholipids contained very low amount of (n-3) PUFA in control rats, and only 1% docosahexaenoic acid. The fatty acid composition of membrane phospholipids reflected the type of diet received by the animals, i.e., the diets deficient in the (n-3) or (n-6) PUFA series resulted in lower (n-3) or (n-6) PUFA, and the (n-3) + (n-6) deficient diet caused a true overall PUFA deficiency in the membranes. The morphology of cells from overall PUFA- or (n-6) PUFA-deficient rats showed an accumulation of secretory vesicles in the cytoplasm. Basal casein secretion was independent of the diet and of the composition of membrane phospholipids. However, prolactin did not have a secretagogue effect on cells from (n-6) PUFA- or overall PUFA-deficient rats but retained this effect on cells from (n-3)-deficient rats. These results emphasize the specific role of (n-6) PUFA in the functioning of the lactating mammary epithelial cell.

Prolactin transit through mammary epithelial cells and appearance in milk.

In lactating mammary epithelial cells, prolactin (PRL) binds to its receptors, is endocytosed and carried to the milk. In order to study the transit of the hormone and its receptor respectively, the intracellular pathway of PRL and ot two monoclonal antibodies against PRL-receptor (PRL-R), labelled with biotin and colloidal gold, were monitored in incubated fragments of enzymatically dissociated mammary cells of lactating rabbits. PRL was internalised in endosomes and carried to microvesicular bodies, lysosomes, Golgi apparatus and secretory vesicles containing casein micelles. After 60 min of incubation at 37 degrees C, PRL was released in the incubation medium. M110 anti PRL-R was internalised in endosomes and detected mainly in microvesicular bodies during a one hour incubation. In contrast, A917 anti PRL-R also internalised in endosomes and in microvesicular bodies, was carried out to the Golgi apparatus and to the lumen of the acini after 5 min of incubation at 37 degrees C. These results suggest that an intracellular sorting occurs in the presence of the hormone or the different antibodies. The fatty acid composition of the mammary epithelial cell membranes influences the activity of these cells. To examine the effect of this membrane composition on the transit of PRL, the intracellular pathway of the hormone was studied in mammary cells of lactating rats previously fed with lipid deficient diets. Plasma levels of PRL were not modified in rats receiving a deficient diet compared to controls. Labelled PRL was accumulated inside the microvesicular bodies during a one-hour incubation at 37 degrees C. However, PRL was always detectable in milk, suggesting that the intracellular transit of PRL could be slowed down but not inhibited. Possible relationships between endocytosis of PRL and its secretagogue effect are discussed.

Endocytosis and intracellular transport of transferrin across the lactating rabbit mammary epithelial cell.

To study the transcytosis and segregation of ligand in the mammary epithelial cell, endocytosis and intracellular transit of human blood transferrin were followed in lactating rabbit mammary epithelial cells. Human transferrin labeled with biotin added to an incubation medium was bound to the basal membrane of mammary epithelial cells and carried across the cell to the lumen of the acini within 5-60 min. At the same time, biotinylated human transferrin accumulated at the apex of the cell. After incubation with human transferrin labeled with colloidal gold, label was detected inside endosome-like structures, vesicles and saccules of the Golgi apparatus, and inside the lumen within 2-5 min. A significant label accumulated at the apex of the cell after 30-60 min. Biotin labeling did not modify the time of transit of human transferrin, as attested by comparison with the time of transit of native transferrin. Human transferrin was never detected inside vesicles containing casein micelles. In contrast, rabbit milk transferrin was immunocytochemically detected inside vesicles containing casein micelles. These results indicate that transcytosis of human transferrin follows a pathway different from vesicles that carry casein micelles.

The possible involvement of protein kinase C(s) and inositol phosphate metabolism in the basal but not in the prolactin stimulated casein release by the lactating rabbit mammary epithelial cell.

The secretagogue effect of prolactin (PRL) on casein release by epithelial mammary cells has been previously related to stimulation of the phospholipase A2-arachidonic acid cascade. In order to determine whether other intracellular pathways are implicated in this secretagogue effect, different agents acting on protein kinase C (PKC) and phospholipase C (PLC) activity have been assessed in vitro in lactating rabbit mammary gland fragments. Phorbol ester (20 nm TPA and 1-oleoyl-2-acetyl-sn-glycerol (10 microM (OAG) stimulated newly synthesized casein secretion and potentiated the PRL secretatogue effect. However, 100 microM quercetin, 100 microM H-7 and 5 and 20 nM staurosporine did not inhibit the latter effect. Exogenous PLC did not stimulate casein secretion. PRL did not affect production of inositol phosphates (IPs) during 10 or 60 min exposure. These results show that PKC activation may increase basal levels of casein secretion, and demonstrate that PRL does not act primarily via PKC activation or by PLC activation to stimulate casein secretion.

Crotoxin, a phospholipase A2 neurotoxin from snake venom, interacts with epithelial mammary cells, is internalized and induces secretion.

Prolactin (PRL) induces liberation of arachidonic acid (AA) from phospholipids of lactating mammary epithelial cells and stimulates casein secretion. In order to investigate the possible involvement of phospholipase A2 (PLA2) activity in the hormonal control of casein secretion by PRL, we examined the effects of crotoxin, a PLA2 neurotoxin from snake venom, on mammary epithelial cells. Crotoxin is made of two subunits: a basic PLA2 with low toxicity (component B, CB) and an acidic, non-toxic and enzymatically inactive component A (CA) which enhances the pharmacological action of CB. While CA is inactive, the PLA2 subunit (CB) induces an accumulation of secretory products in the lumen of mammary acini, an extensive development of the Golgi apparatus. The secretion of newly synthesized casein is increased in the presence of CB and this effect is inhibited by nordihydroguaiaretic acid (NDGA) and caffeic acid, two inhibitors of the lipoxygenase pathway which also prevent stimulation of secretion by PRL. Further, CB transiently induces the release of radiolabelled AA from mammary tissues previously labelled with [14C]AA, the highest release being observed between 15 s and 5 min of contact with CB and CA. Immunofluorescence labelling by anti-CB antibodies of epithelial mammary tissues previously incubated with CA, CB or a combination of CA and CB indicates that CB binds to epithelial cells and is internalized, at least in part, and that CA enhances both CB binding and its internalization. These observations emphasize the involvement of PLA2 in the control of casein secretion and suggest that PLA2 acts intracellularly.

Temperature dependence of prolactin endocytosis and casein exocytosis in epithelial mammary cells.

As previously reported in epithelial mammary cells of lactating rabbit, prolactin exerts a stimulatory effect on casein secretion. After binding to a membrane receptor, the complex hormone-receptor is internalized in mammary cells. Peptide hormone action involves the generation of second messengers. These second messengers can be emitted as soon as hormone is linked to the membrane receptor. However, it is not excluded that endocytosis and transfer of prolactin inside the cell take part in the emission of second messenger and related secretory response. In order to precise intracellular transport pathways in the lactating mammary cell, we have examined the effects of reduced temperature on the one hand on prolactin endocytosis, on the other hand on casein secretion and on the stimulating effect of prolactin on casein secretion. Endocytosed prolactin was cytochemically localized mainly on the plasma membrane at 4 degrees C. At 25 degrees C, the hormone accumulated, during 60 min, in endosomes and multivesicular bodies. At 37 degrees C, prolactin was detectable after 15 and 30 min inside the cells and disappeared after 60 min. Transport and exocytosis of secretory proteins were only partly inhibited at 25 degrees C as attested by autoradiography localization and biochemical assays of newly synthesized caseins. However, at 25 degrees C, prolactin was no more able to stimulate casein exocytosis. These results show that intracellular transport of prolactin and secretagogue effect of the hormone does not proceed at 25 degrees C. However, secretory mechanisms of the cell are always able to be stimulated by exogenous arachidonic acid at this temperature. Low temperature appears as a good means to study intracellular transport in the mammary cell.