Intracellular origin and secretion of milk fat globules

The cream or fat fraction of milk consists of fat droplets composed primarily of triacylglycerols that are surrounded by cellular membranes. In this review we discuss what is known about how these droplets are formed in and secreted by mammary epithelial cells during lactation. This secretion mechanism, which appears to be unique, is unlike the exocytotic mechanism used by other cell types to secrete lipids. Milk fat globules originate as small, triacylglycerol-rich, droplets that are formed on or in endoplasmic reticulum membranes. These droplets are released from endoplasmic reticulum into the cytosol as microlipid droplets coated by proteins and polar lipids. Microlipid droplets can fuse with each other to form larger cytoplasmic lipid droplets. Droplets of all sizes appear to be unidirectionally transported to apical cell regions by as yet unknown mechanisms that may involve cytoskeletal elements. These lipid droplets appear to be secreted from the cell in which they were formed by being progressively enveloped in differentiated regions of apical plasma membrane. While plasma membrane envelopment appears to be the primary mechanism by which lipid droplets are released from the cell, a mechanism involving exocytosis of lipid droplets from cytoplasmic vacuoles also has been described. As discussed herein, while we have a general overview of the steps leading to the fat globules of milk, virtually nothing is known about the molecular mechanisms involved in milk fat globule formation, intracellular transit, and secretion.     

Milk lipid globule precursor release from endoplasmic reticulum reconstituted in a cell-free system.

Lipid droplet precursors of milk lipid globules are believed to be derived from elements of endoplasmic reticulum in milk-secreting mammary epithelial cells. Endoplasmic reticulum isolated from mammary gland was able to generate small droplets morphologically resembling microlipid droplet precursors of milk lipid globules. Droplet generation was time and temperature dependent and required a cytosol fraction of Mr greater than 10,000. Droplet generation was enhanced by, but did not require, addition of nucleoside triphosphates, fatty acids, coenzyme A, glycerol-3-phosphate, and dithiothreitol. Microlipid droplets generated in this cell-free system were enriched in triacylglycerols and resembled microlipid droplets formed within mammary epithelial cells in polar lipid and polypeptide composition. Endoplasmic reticulum immobilized onto nitrocellulose retained activity in generation of putative microlipid droplets, and this immobilization method provided a facile means for separation of the donor from the generated products.     

Distribution of terminal transferases of acylglycerol synthesis in cell fractions from lactating mammary gland

Cytoplasmic lipid droplets and microlipid droplets, intracellular precursors of milk lipid globules, had little ability to incorporate radioactivity from glycerol 3-phosphate or palmitoyl-CoA into triacylglycerols. The limited incorporation of these precursors by micro- and cytoplasmic lipid droplets from rat and cow mammary gland was into phospholipids primarily. Acyltransferases catalyzing incorporation of glycerol 3-phosphate into acylglycerols were concentrated in a relatively high buoyant density class of rough microsomes. Palmitoyl-CoA-sn-1,2-diacylglycerol acyltransferase activity was distributed heterogeneously among fractions obtained by equilibrium density gradient fractionation of mammary homogenates. Observations suggest that terminal steps of acylglycerol synthesis are localized primarily in rough endoplasmic reticulum of milk secreting mammary epithelial cells. There appears to be a heterogeneous distribution of acyltransferases along the reticular network.     

Nuclear coactivator protein p100 is present in endoplasmic reticulum and lipid droplets of milk secreting cells

We have identified the p100 protein, previously known as a novel cellular coactivator, as a constituent of endoplasmic reticulum and cytosolic lipid droplets from milk secreting cells. Cytosolic lipid droplets of terminally differentiated mammary epithelial cells are secreted as milk lipid globules. However, milk lipid globules did not have detectable amounts of p100 protein. The p100 protein was found also in cytosol from lactating mammary gland, in storage lipid droplets from mouse adipocytes, and in endoplasmic reticulum from liver. Immunofluorescence microscopy of mammary epithelial cells confirmed the presence of p100 in non-nuclear regions of these cells. Partial sequence analysis of tryptic peptides from p100 from cow mammary gland showed extensive homology with the reported sequence of p100 determined from a human cDNA. Antibodies against a peptide synthesized to duplicate a sequence in human p100 recognized a protein of the size of p100 in cow, mouse and rat cell fractions.     

Antibodies to the major insoluble milk fat globule membrane-associated protein: specific location in apical regions of lactating epithelial cells

Milk lipid globules of various species are surrounded by a membrane structure that is separated from the triglyceride core of the globule by a densely staining fuzzy coat layer of 10- to 50-nm thickness. This internal coat structure remains attached to the membrane during isolation and extraction with low- and high-salt buffers, is insoluble in nondenaturing detergents, and is enriched in an acidic glycoprotein (butyrophilin) with an apparent Mr of 67,000. Guinea pig antibodies against this protein, which show cross-reaction with the corresponding protein in some (goat) but not other (human, rat) species, have been used for localization of butyrophilin on frozen sections of various tissues from cow by immunofluorescence and electron microscopy. Significant reaction is found only in milk-secreting epithelial cells and not in other cell types of mammary gland and various epithelial tissues. In milk-secreting cells, the staining is restricted to the apical cell surface, including budding milk lipid globules, and to the periphery of the milk lipid globules contained in the alveolar lumina. These findings indicate that butyrophilin, which is constitutively secreted by surface budding in coordination with milk lipid production, is located at the apical surface and is not detected at basolateral surfaces, in endoplasmic reticulum, and in Golgi apparatus. This protein structure represents an example of a cell type-specific cytoskeletal component in a cell apex. It is suggested that this antigen provides a specific marker for the apical surface of milk- secreting cells and that butyrophilin is involved in the vectorial discharge of milk lipid globules.     

Butyrophilin of milk lipid globule membrane contains N-linked carbohydrates and cross-links with xanthine oxidase

1. N-glycanase, but not O-glycanase, released carbohydrates from butyrophilin of rat and cow milk lipid globule membranes. 2. 1-Deoxynojirimycin, and inhibitor of glucosidases I and II of the glycoprotein processing pathway, increased the amount or extent of glycosylation of butyrophilin in rat milk lipid globules. 3. Butyrophilin and xanthine oxidase of milk lipid globule membrane had a nearest neighbor relationship, as demonstrated through specific crosslinking of these proteins. 4. From these results it is suggested that butyrophilin has asparagine-linked oligosaccharides which bypass the processing apparatus of endoplasmic reticulum and Golgi apparatus. Butyrophilin may be responsible for anchoring xanthine oxidase to the inner (cytoplasmic) face of milk lipid globule membrane.     

Metabolism of palmitate in perfused rat liver. Computer models of subcellular triacylglycerol metabolism

1. In the preceding paper [Kondrup (1979) Biochem. J.184, 63-71] the separation of two major fractions of hepatic triacylglycerol was described. One fraction contained triacylglycerol from the endoplasmic reticulum and from the Golgi apparatus. The other fraction contained triacylglycerol from the cytoplasmic lipid droplets. In the present paper possible precursor-product relationships between the two fractions were investigated by means of computer models. 2. The fatty acids present in di- and tri-acylglycerol in the fractions isolated in the time studies were analysed by gas chromatography. From this analysis the relative specific radioactivities, and contents, of palmitate in acylglycerols in the two fractions at the various time points were calculated. 3. A computer was used to predict relative specific radioactivities of pools in defined models of hepatic triacylglycerol metabolism. The acceptability of the models was evaluated by comparing predicted with measured relative specific radioactivities. 4. It is suggested that triacylglycerol in cytoplasmic lipid droplets does not originate (a) directly from triacylglycerol in the endoplasmic reticulum, (b) from a sub-pool of it or (c) directly from non-esterified fatty acids entering the cell. Rather, it is formed from diacylglycerol (and acyl-CoA) in the endoplasmic reticulum. Diacylglycerol, on the other hand, is furnished in part by hydrolysis of triacylglycerol in the endoplasmic reticulum. 5. This suggestion is discussed in relation to previous models of hepatic fatty acid metabolism.     

LIPID SYNTHESIS, INTRACELLULAR TRANSPORT, AND SECRETION : II. Electron Microscopic Radioautographic Study of the Mouse Lactating Mammary Gland

In the mammary glands of lactating albino mice injected intravenously with 9, 10-oleic acid-³H or 9, 10-palmitic acid-³H, it has been shown that the labeled fatty acids are incorporated into mammary gland glycerides. The labeled lipid in the mammary gland 1 min after injection was in esterified form (> 95%), and the radioautographic reaction was seen over the rough endoplasmic reticulum and over lipid droplets, both intracellular and intraluminal. At 10–60 min after injection, the silver grains were concentrated predominantly over lipid droplets. There was no concentration of radioactivity over the granules in the Golgi apparatus, at any time interval studied. These findings were interpreted to indicate that after esterification of the fatty acid into glycerides in the rough endoplasmic reticulum an in situ aggregation of lipid occurs, with acquisition of droplet form. The release of the lipid into the lumen proceeds directly and not through the Golgi apparatus, in contradistinction to the mode of secretion of casein in the mammary gland or of lipoprotein in the liver. The presence of strands of endoplasmic reticulum attached to intraluminal lipid droplets provides a structural counterpart to the milk microsomes described in ruminant milk.     

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 supression of milk fat globule secretion by colchicine: an effect coupled to inhibition of exocytosis

The effects of colchicine on release of milk lipids from mammary tissue were evaluated by biochemical analysis of milk and morphological study of the tissue following intramammary infusions of the alkaloid into lactating goats. Colchicine produces a reversible drop in milk yield. As the flow of milk resumes, 36–48 h after infusion, the fat content of the milk increases, phospholipid per g of total globule lipid falls, mean size of milk fat globules increased and diameters of fat droplets (presecretory milk fat globules) within lactating cells approximately double. These observations are consistent with the conclusion that colchicine suppresses milk fat globule secretion but that globules continue to grow in size within cells during the suppression period. These findings indicate that secretion of milk fat globules and the skim milk phase are coupled.     

Association of cytosolic lipids with fatty acid synthase from lactating mammary gland

• 1.1. Membrane-free cytosol contained over 4% of both the total lipids and phospholipids present in homogenates of lactating rat mammary gland, and much of this lipid was associated with a high molecular weight complex isolated from cytosol by gel exclusion chromatography or by density gradient centrifugation.
• 2.2. This complex principally consisted of polypeptides with apparent molecular weights of 220 and 116kDa. Lipids associated with this complex were transferred to endoplasmic reticulum and to intracellular lipid droplet precursors of milk lipid globules upon incubation in a cell-free system.
• 3.3. This lipoprotein complex was abundant in cytosol from lactating mammary gland, but was diminished in amount in cytosol from involuted mammary glands. The 220 kDa constituent of this complex was identified as the monomer of fatty acid synthase.
• 4.4. These results suggest that fatty acid synthase complex in lactating mammary gland may function in transfer of lipids necessary for formation or growth of lipid droplet precursors of milk lipid globules.

     

Expression of constitutively activated Akt in the mammary gland leads to excess lipid synthesis during pregnancy and lactation

Expression of constitutively activated Akt in the mammary glands of transgenic mice results in a delay in post-lactational involution. We now report precocious lipid accumulation in the alveolar epithelium of mouse mammary tumor virus-myr-Akt transgenic mice accompanied by a lactation defect that results in a 50% decrease in litter weight over the first 9 days of lactation. Although ductal structures and alveolar units develop normally during pregnancy, cytoplasmic lipid droplets appeared precociously in mammary epithelial cells in early pregnancy and were accompanied by increased expression of adipophilin, which is associated with lipid droplets. By late pregnancy the lipid droplets had become significantly larger than in nontransgenic mice, and they persisted into lactation. The fat content of milk from lactating myr-Akt transgenic mice was 65-70% by volume compared to 25-30% in wild-type mice. The diminished growth of pups nursed by transgenic mothers could result from the high viscosity of the milk and the inability of the pups to remove sufficient quantities of milk by suckling. Transduction of the CIT3 mammary epithelial cell line with a recombinant human adenovirus encoding myr-Akt resulted in an increase in glucose transport and lipid biosynthesis, suggesting that Akt plays an important role in regulation of lipid metabolism.     

Characterization of a secretory vesicle-rich fraction from lactating bovine mammary gland.

Fractions enriched in secretory vesicles were obtained from lactating bovine mammary tissue by a straightforward procedure involving gentle homogenization and centrifugation in isotonic milk salt solution containing Ficoll. Secretory vesicle-rich fractions could also be obtained from lactating rat mammary gland by this procedure. With rats, yields of vesicles were substantially increased by administration of colchicine or thioglucose to animals several hours before sacrifice. Isolated fractions were enriched in lactose and consisted predominantly of 0.2–1.2 μm diameter vesicles, many of which contained casein micelles. Enzymatic, compositional and morphological examination revealed vesicle preparations to be largely free of contamination by rough endoplasmic reticulum, mitochondria, nuclei, peroxisomes and lysosomes. Specific activity of several marker enzymes of the secretory vesicle fraction were similar to, or intermediate between, Golgi apparatus and milk lipid globule membranes. Amounts of cholesterol and gangliosides in vesicle fractions approached levels found in plasma membranes. In distribution of major phospholipids, secretory vesicles were intermediate between Golgi apparatus and milk lipid globule membranes. The pattern of polypeptides of secretory vesicle membrane was qualitatively similar to that of Golgi apparatus membranes. While there were similarities between these polypeptide patterns and that of lipid globule membranes, the latter contained relatively more of certain polypeptides, particularly the internal coat-associated polypeptides of the globule membrane. These observations are discussed in relation to the endomembrane hypothesis and the origin of the membrane of milk lipid globules.     

The epithelial cells and cell fragments in human milk

Summary The cell fragments and epithelial cells in human milk were examined in samples obtained from 30 women: 3 of these provided sequential samples at weekly intervals for 110 days. Membrane-bound cytoplasmic fragments in the sedimentation pellet greatly outnumbered the population of intact cells in all samples. Most of the fragments were derived from secretory cells and contained numerous cisternae of rough endoplasmic reticulum, lipid droplets and Golgi vesicles containing casein micelles. Secretory epithelial cells were present in small numbers in all samples and after the 2nd month of lactation replaced the macrophage as the predominant cell type. Ductal epithelial cells represented less than 1% of the total cell population up to 8 days post-partum, but thereafter they were very rarely found. They occurred in aggregates of 2–4 cells and possessed tight junctions that circumscribed the area of cell-cell contact. All samples of milk contained squamous epithelial cells derived from the galactophores and/or the skin of the nipple. Bacteria were often attached to the surface of the squamous cells. The possible relationship between the presence of secretory epithelial cells in milk and the occurrence of milk proteins in the blood of lactating women is discussed.     

A Test of Current Models for the Mechanism of Milk‐Lipid Droplet Secretion

Milk lipid is secreted by a unique process, during which triacylglycerol droplets bud from mammary cells coated with an outer bilayer of apical membrane. In all current schemes, the integral protein butyrophilin 1A1 (BTN) is postulated to serve as a transmembrane scaffold, which interacts either with itself or with the peripheral proteins, xanthine oxidoreductase (XOR) and possibly perilipin‐2 (PLIN2), to form an immobile bridging complex between the droplet and apical surface. In one such scheme, BTN on the surface of cytoplasmic lipid droplets interacts directly with BTN in the apical membrane without binding to either XOR or PLIN2. We tested these models using both biochemical and morphological approaches. BTN was concentrated in the apical membrane in all species examined and contained mature N‐linked glycans. We found no evidence for the association of unprocessed BTN with intracellular lipid droplets. BTN‐enhanced green fluorescent protein was highly mobile in areas of mouse milk‐lipid droplets that had not undergone post‐secretion changes, and endogenous mouse BTN comprised only 0.5–0.7% (w/w) of the total protein, i.e. over 50‐fold less than in the milk‐lipid droplets of cow and other species. These data are incompatible with models of milk‐lipid secretion in which BTN is the major component of an immobile global adhesive complex and suggest that interactions between BTN and other proteins at the time of secretion are more transient than previously predicted. The high mobility of BTN in lipid droplets marks it as a potential mobile signaling molecule in milk .     

The role of exocytosis in the apocrine secretion of milk lipid globules in mouse mammary gland during lactogenesis.

Functional relations between exocytotic vesicle membranes, plasmalemma and milk fat globule membranes (MFGM) were studied during the final stages of mouse mammary gland differentiation, in the gland during full lactation and in the postpartum gland in which the synthesis of secretory products was partly inhibited by application of 2-Br-alpha-ergocryptine. Analysis of ultrathin sections, freeze-fracture replicas, scanning electron microscopy and application of a cytochemical marker filipin showed that the apocrine secretion of lipid globules was closely related to the exocytosis of milk proteins. During the last days of gestation the secretion of lipid globules resulted from many exocytotic events of the secretory vesicles that accumulated and fused around the cytoplasmic lipid droplets. Seldom the lipid droplet protruded partly into the gland lumen and a part of its surface became covered with the apical plasmalemma. Although apical plasmalemma became more important in the formation of MFGM in the postpartum period, we could still confirm a direct contribution of secretory vesicle membranes to the final detachment of the lipid globule. The application of 2-Br-alpha-ergocryptine hindered the apocrine secretion of the lipid globules and a situation similar to the situation in the prepartum gland was observed.     

The surface of lipid droplets is a phospholipid monolayer with a unique Fatty Acid composition

We found that caveolin-2 is targeted to the surface of lipid droplets (Fujimoto, T., Kogo, H., Ishiguro, K., Tauchi, K., and Nomura, R. (2001) J. Cell Biol. 152, 1079-1085) and hypothesized that the lipid droplet surface is a kind of membrane. To elucidate the characteristics of the lipid droplet surface, we isolated lipid droplets from HepG2 cells and analyzed them by cryoelectron microscopy and by mass spectrometry. By use of cryoelectron microscopy at the stage temperature of 4.2 K, the lipid droplet surface was observed as a single line without any fixation or staining, indicating the presence of a single layer of phospholipids. This result appeared consistent with the hypothesis that the lipid droplet surface is derived from the cytoplasmic leaflet of the endoplasmic reticulum membrane and may be continuous to it. However, mass spectrometry revealed that the fatty acid composition of phosphatidylcholine and lysophosphatidylcholine in lipid droplets is different from that of the rough endoplasmic reticulum. The ample presence of free cholesterol in lipid droplets also suggests that their surface is differentiated from the bulk endoplasmic reticulum membrane. On the other hand, although caveolin-2beta and adipose differentiation-related protein, both localizing in lipid droplets, were enriched in the low density floating fraction, the fatty acid composition of the fraction was distinct from lipid droplets. Collectively, the result indicates that the lipid droplet surface is a hemi-membrane or a phospholipid monolayer containing cholesterol but is compositionally different from the endoplasmic reticulum membrane or the sphingolipid/cholesterol-rich microdomain.     

Regulation of Lipid Droplet Size in Mammary Epithelial Cells by Remodeling of Membrane Lipid Composition—A Potential Mechanism

Milk fat globule size is determined by the size of its precursors—intracellular lipid droplets—and is tightly associated with its composition. We examined the relationship between phospholipid composition of mammary epithelial cells and the size of both intracellular and secreted milk fat globules. Primary culture of mammary epithelial cells was cultured in medium without free fatty acids (control) or with 0.1 mM free capric, palmitic or oleic acid for 24 h. The amount and composition of the cellular lipids and the size of the lipid droplets were determined in the cells and medium. Mitochondrial quantity and expression levels of genes associated with mitochondrial biogenesis and polar lipid composition were determined. Cells cultured with oleic and palmitic acids contained similar quantities of triglycerides, 3.1- and 3.8-fold higher than in controls, respectively (P < 0.0001). When cultured with oleic acid, 22% of the cells contained large lipid droplets (>3 μm) and phosphatidylethanolamine concentration was higher by 23 and 63% compared with that in the control and palmitic acid treatments, respectively (P < 0.0001). In the presence of palmitic acid, only 4% of the cells contained large lipid droplets and the membrane phosphatidylcholine concentration was 22% and 16% higher than that in the control and oleic acid treatments, respectively (P < 0.0001). In the oleic acid treatment, approximately 40% of the lipid droplets were larger than 5 μm whereas in that of the palmitic acid treatment, only 16% of the droplets were in this size range. Triglyceride secretion in the oleic acid treatment was 2- and 12-fold higher compared with that in the palmitic acid and control treatments, respectively. Results imply that membrane composition of bovine mammary epithelial cells plays a role in controlling intracellular and secreted lipid droplets size, and that this process is not associated with cellular triglyceride content.     

Asymmetrical microtubule capping structures in frog palate cilia

The three-dimensional ultrastructure of the Golgi apparatus in milk secreting epithelial cells of bovine mammary gland was explored. From computer-aided reconstructions of serial thin sections, it was determined that the Golgi apparatus was composed of a single set of stacked cisternae. The three-dimensional shape of the dictyosome varied from cell to cell, but the overall shape was that of a hollow cone, cylinder, or bowl. The cis and trans surfaces of the dictyosome were arranged in three-dimensional space such that the cis face was located on the outer surface of the hollow structure and the trans face on the inner surface. The cytoplasmic channel (secretory channel) that traversed the longitudinal axis of the hollow dictyosome contained secretory vesicles. Densely stacked cisternae of rough endoplasmic reticulum surrounded the dictyosome, and microvesicles appeared to fuse with, or bud from, cisternae of both organelles. These findings suggest that Golgi apparatus of the lactating epithelial cell is highly organized and that the Golgi apparatus and secretory channel are essentially an independent compartment within the cell.