Proteome profile and biological activity of caprine, bovine and human milk fat globules

Upon combining bidimensional electrophoresis with monodimensional separation, a more comprehensive analysis of the milk fat globule membrane has been obtained. The proteomic profile of caprine milk fat globules revealed the presence of butyrophilin, lactadherin and perilipin as the major proteins, they were also associated to bovine and human milk fat globule membranes. Xanthine dehydrogenase/oxidase has been detected only in monodimensional gels. Biological activity of milk fat globules has been evaluated in Caco2-cells, as a representative model of the intestinal barrier. The increase of cell viability was indicative of a potential nutraceutical role for the whole milk fat globule, suggesting a possible employment in milk formula preparation.     

Crossed immunoelectrophoresis of bovine milk fat globule membrane protein solubilized with non-ionic detergent.

Detergent solubilized bovine milk fat globule membrane material studied by crossed immunoelectrophoresis combined with histochemical techniques revealed four major protein complexes. All four were found to bind to concanavalin A and three were identified as sialoglycoproteins. Xanthine oxidase activity was associated with the non-sialoglycoprotein precipitate. Immunoabsorption with intact milk fat globules showed an internal location of the xanthine oxidase, whereas the three other main proteins plus Mg2+-ATPase and 5'-nucleotidase were disposed on the outer membrane surface. The major proteins from milk fat globule membrane and membrane material isolated from skim milk showed immunochemical identity.     

Erratum

Detergent solubilized bovine milk fat globule membrane material studied by crossed immunoelectrophoresis combined with histochemical techniques revealed four major protein complexes. All four were found to bind to concanavalin A and three were identified as sialoglycoproteins. Xanthine oxidase activity was associated with the non-sialoglycoprotein precipitate. Immunoabsorption with intact milk fat globules showed an internal location of the xanthine oxidase, whereas the three other main proteins plus Mg²⁺-ATPase and 5′-nucleotidase were disposed on the outer membrane surface. The major proteins from milk fat globule membrane and membrane material isolated from skim milk showed immunochemical identity.     

Ultrastructural characterization by ruthenium red of the surface of the fat globule membrane of human and rat milk with data on carbohydrates of fractions of rat milk

The fat globules of the cream fractions of human and rat milk were stained with ruthenium red. Under the electron microscope, discrete granules and an amorphous coat of lesser density are seen at the surface of the milk fat globules. Since ruthenium red binds anionic groups selectively, it is probable that the granules contain the greatest concentration of these groups. The cream fraction of rat milk contains hexoses, hexosamines, methylpentoses and sialic acid. Methylpentoses and hexosamines are significantly enriched in the cream fraction. It is concluded that the finding of a surface coat in milk fat globules is in keeping with the Bargmann-Knoop model and suggests a distinct mechanism for carrying certain complex carbohydrates in milk. The role of the negative charges at the outer surface of the membrane coat is maintaining fat globules in suspension and in binding certain cations such as calcium is suggested.     

Preparation and characterization of the inner coat material associated with fat globule membranes from bovine and human milk

Milk fat globules of many species are characterized by a dense 10–50 nm thick layer sandwiched between the milk fat globule membrane (MFGM) and the outer shell of the fat droplet. This coat material is tightly associated with the membrane and survives isolation and extensive washing of the isolated MFGM. We have prepared these MFGM-associated coat structures from bovine and human milk by removal of membrane and loosely associated material using extractions in low and high salt buffers, non-ionic detergents such as Triton X-100, and/or solutions of lithium diiodosalicylate. Residual fractions obtained after such treatments are devoid of identifiable membrane structures but are enriched in MFGM coat material which appears in the form of densely stained plaques of a finely filamentous texture. MFGM fractions are enriched in some polypeptide bands seen after electrophoresis two of which are especially prominent in both species (band 3, apparent mol. wt 155 000; band 12, apparent mol. wt 67 000). Human and bovine MFGM coat fractions and isolated bovine band 12 polypeptide material separated after dissociation in sodium dodecylsulfate (SDS) by gel filtration, chromatography on hydroxylapatite or preparative electrophoresis in SDS-polyacrylamide gels are intimately associated with small amounts of phospholipids and gangliosides of a pattern different from that of total MFGM, contain carbohydrates (relatively high contents of mannose, glucosamine, galactose, and galactosamine; low levels of fucose and sialic acids) and show similar amino acid compositions. The relationship of band 12 polypeptide to components of MFGM coat preparations from various other species and to components present in other membrane fractions has been examined by immunodiffusion techniques and immunofluorescence microscopy using rabbit, mouse and guinea pig antibodies against purified band 12 polypeptide. Evidence is presented for the occurrence of related polypeptides in MFGM coat preparations from different species. The unusual structure and resistance of the MFGM coat material, especially the occurrence of glycopeptides in association with the cytoplasmic side of a membrane structure, are discussed in relation to the stabilization of the emulsified state of milk fat and the process of milk fat globule budding as well as a general model for local differentiation of membrane character.     

Focus on the supramolecular structure of milk fat in dairy products

Bovine fat is dispersed in raw milk as natural milk fat globules, with an average diameter of 4 microm, which are enveloped in a biological membrane, the milk fat globule membrane (MFGM). However, dairy processes modify the supramolecular structure and the surface composition of milk fat. Thus, milk fat is present in many dairy products under various forms. In this study, we focused on the fact that natural milk fat globules are rarely consumed in their native state, i.e. in fresh raw milk. In most drinking milks, fat globules are homogenised in order to avoid their rising at the surface of the products. Furthermore, fat globules are heat treated to avoid the growth of micro-organisms. As a consequence of the technological process applied, the volume-weighted average diameter of fat globules in drinking milks is in the range 0.2-0.5 microm. Homogenisation of fat globules led to the partial disruption of the MFGM and to the adsorption of milk proteins. Moreover, this study showed that in cheeses, milk fat can be dispersed as (i) fat globules with the MFGM, (ii) aggregates of fat globules, (ii) homogenised fat globules, (iii) free fat and (iv) a combination of different phases and structures. The knowledge of the supramolecular structure of milk fat in dairy products is of primary importance regarding its technological, sensorial and nutritional properties.     

Milk fat globule membranes devoid of intramembranous particles

When isolated milk fat globule membranes from bovine, human, and murine (rat) milk were examined by freeze-fracturing most of the membrane faces were devoid of membrane-intercalated particles whereas a minor portion showed relatively few particles, either in clusters or in apparent random distribution. A reduced particle density was also noted in membranes of intra-alveolar milk fat globules of cows and rats, in contrast to high particle densities in the apical plasma membrane of lactating epithelial cells. The observations suggest that certain membrane constituents recognized as intramembranous particles either are displaced from the region of the apical surface of the mammary epithelial cell which is involved in milk fat globule budding or are dislocated and rearranged during the budding process.     

Ultrastructure of the milk fat globule membrane with and without triglyceride

Summary The primary milk fat globule membrane (MFGM) around freshly secreted milk fat globules consists of a unit membrane separated from the triglyceride core by a dense material. This dense material may widen to include cytoplasmic organelles or may form small blebs. Preincubation and fixation of the globules at temperatures between 4° C and 60° C has no effect on the width or appearance of the dense material. Isolated MFGM profiles show structures identical to those found on intact globules. The dense material on the isolated MFGM profiles is unaffected by extractions which remove essentially all the triglyceride present in the pellets of MFGM.The structure of the primary MFGM is therefore independent of any triglyceride content and the earlier suggestions that the dark material represented a triglyceride layer of high melting point adsorped during cooling of the globules after milking are not supported by the work described in this paper.     

BIOCHEMICAL AND MORPHOLOGICAL COMPARISON OF PLASMA MEMBRANE AND MILK FAT GLOBULE MEMBRANE FROM BOVINE MAMMARY GLAND

Purified plasma membrane fractions from lactating bovine mammary glands and membranes of milk fat globules from the same source were similar in distribution and fatty acid composition of phospholipids. The sphingomyelin content of the phospholipid fraction of both membranes was higher than in these fractions from other cell components, β-carotene, a constituent characteristic of milk fat, was present in the lipid fraction of the plasma membrane. Cholesterol esters of plasma membrane were similar in fatty acid composition to those of milk fat globule membranes. Disc electrophoresis of either membrane preparation on polyacrylamide gels revealed a single major protein component characteristic of plasma membrane from other sources. Distinct morphological differences between plasma membrane and milk fat globule membranes were observed in both thin sections and in negatively stained material. Plasma membrane was vesicular in appearance while milk fat globule membranes had a platelike aspect. These observations are consistent with derivation of fat globule membrane from plasma membrane accompanied by structural rearrangement of membrane constituents.     

X-Ray Crystal Structure of Pyrenocine A,a Phytotoxin from Pyrenochaeta terrestris

The milk fat globule membrane (MFGM) enclosing fat droplets in bovine milk was isolated, and its effects on hydrolysis of milk fat by lipases were investigated by using a gum arabic-stabilized milk fat emulsion as substrate. The addition of isolated MFGM to the reaction mixture markedly inhibited hydrolysis by pancreatic and microbial (Rhizopus delemer) lipases. The inhibition was completely lost on tryptic digestion of MFGM, suggesting that the protein moiety of MFGM played a role in the inhibition. Soluble glycoprotein (SGP) which was isolated from delipidated MFGM produced marked inhibitory activity. The inhibition by SGP was dependent on substrate concentration, suggesting that the inhibition was at least partly due to coverage and blockage of the substrate surface by SGP.     

Sialoglycopeptides from bovine milk fat globule membrane.

Milk fat globule membrane was shown to contain sialic acid, all of which could be released without disruption of the fat globule. Sialoglycopeptides were cleaved from the surface of intact fat globules by Pronase and fractionated on Sephadex G-50. Further fractionation of the major sialoglycopeptide peak on DEAE-Sephadex gave two groups of sialoglycopeptides eluted with 0.1 M NaCl (Group A) and 0.5 M NaCl (Group B), respectively. Refractionation gave a major sialoglycopeptide from each of the two groups together with a total of three minor sialoglycopeptides. All five sialoglycopeptides eluted as single peaks using shallow salt gradients on DEAE-Sephadex and contained a hydrophilic peptide chain together with galactose, mannose, N-acetylgalactosamine, N-acetylglucosamine, and sialic acid. Glycopeptides of Group A but not Group B contained fucose. The major sialoglycopeptide of Group B released 35% of its hexose and hexosamine on treatment with alkaline borohydride leaving a sialoglycopeptide which had reduced serine and threonine and elevated alanine levels and in addition contained 2-aminobutyric acid. An oligosaccharide fraction containing N-acetylgalactosaminitol, galactose and sialic acid in a molar ratio of 1:1:2 was partially characterised from the clevage mixture. The major sialoglycopeptide of Group A had a more complex carbohydrate structure and showed no released carbohydrate on treatment with alkaline borohydride. The sialoglycopeptides of milk fat globule membrane show many similarities with those of erythrocyte membrane and have a potential use in comparative and structural studies.     

Filter-aided sample preparation with dimethyl labeling to identify and quantify milk fat globule membrane proteins

Bovine milk is a major nutrient source in many countries and it is produced at an industrial scale. Milk is a complex mixture of proteins, fats, carbohydrates, vitamins and minerals. The composition of the bovine milk samples can vary depending on the genetic makeup of the bovine species as well as environmental factors. It is therefore important to study the qualitative and quantitative differences of bovine milk samples. Proteins in milk can be present in casein micelles, in the serum (the water soluble fraction) or in fat globules. These fat globules have a double membrane layer with proteins being bound to or being incapsulated in the membrane layer. The identification and molecular composition of the milk proteins have gained increased interest in recent years. Proteomic techniques make it now possible to identify up to many thousands of proteins in one sample, however quantification of proteins is as yet not straightforward. We analyzed the proteins of the milk fat globule membrane using dimethyl labeling methods combined with a filter-aided sample preparation protocol. Using these methods, it is now possible to quantitatively study the detailed protein composition of many milk samples in a short period of time.     

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.     

Sialoglycopeptides from bovine milk fat globule membrane

Milk fat globule membrane was shown to contain sialic acid, all of which could be released without disruption of the fat globule. Sialoglycopeptides were cleaved from the surface of intact fat globules by Pronase and fractionated on Sephadex G-50. Further fractionation of the major sialoglycopeptide peak on DEAE-Sephadex gave two groups of sialoglycopeptides eluted with 0.1 M NaCI (Group A) and 0.5 M NaCI (Group B), respectively. Refractionation gave a major sialoglycopeptide from each of the two groups together with a total of three minor sialoglycopeptides. All five sialoglycopeptides eluted as single peaks using shallow salt gradients on DEAE-Sephadex and contained a hydrophilic peptide chain together with galactose, mannose, N-acetylgalactosamine, N-acetylglucosamine, and sialic acid. Glycopeptides of Group A but not Group B contained fucose.The major sialoglycopeptide of Group B released 35 % of its hexose and hexosamine on treatment with alkaline borohydride leaving a sialoglycopeptide which had reduced serine and threonine and elevated alanine levels and in addition contained 2-aminobutyric acid. An oligosaccharide fraction containing N-acetylgalactosaminitol galactose and sialic acid in a molar ratio of 1 : 1 : 2 was partially characterised from the cleavage mixture.The major sialoglycopeptide of Group A had a more complex carbohydrate structure and showed no released carbohydrate on treatment with alkaline borohydride.The sialoglycopeptides of milk fat globule membrane show many similarities with those of erythrocyte membrane and have a potential use in comparative and structural studies.     

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.     

Enzyme activities and electronmicroscopic structure of rat milk fractions obtained after centrifugation

Summary LDH and MDH activities were found to increase after freeze-thawing of the cream and a non-fat fraction of rat milk isolated by centrifugation.Electronmicroscopy of these fractions revealed that cellular components occurred especially in association with milk fat globules but also in combination with secretion granules.The fat globule fraction represented only 20% of the milk volume but accounted for more than 50% of the LDH and 75% of the MDH activities in milk.The results show that in the rat mammary gland an apocrine secretion type occurs. The reason why the LDH and MDH activities increase in the milk during the lactation of the rat must be that increasing amounts of cellular material is passed into milk at secretion, containing increasing activities of LDH and MDH.This investigation was supported by grants from the Foundation of Magnus Bergwall and the Swedish Natural Science Research Council.The skillful technical assistance of Mrs Anna-Greta Petersen and Mrs Marie Adler-Maihofer and the secretarial help of Miss Marianne Andersson are gratefully acknowledged.     

Glycosphingolipids from bovine milk and milk fat globule membranes: a comparative study. Adhesion to enterotoxigenic Escherichia coli strains

Several components of milk fat globule membranes (MFGMs) have been reported to display beneficial health properties and some of them have been implicated in the defense of newborns against pathogens. These observations prompted us to determine the glycosphingolipid content of MFGMs and their interaction with pathogens. A comparative study with whole milk components was also carried out. Milk fat globules and MFGMs were isolated from milk. Gangliosides and neutral glycosphingolipids were obtained from MFGMs and whole milk and their fatty acid contents were determined by gas chromatography-mass spectrometry (GC-MS). MFGMs and whole milk showed similar ganglioside and neutral glycosphingolipid contents, with whole milk having more GM3 and glucosylceramide and less GD3, O-acetyl GD3, O-acetyl GT3, and lactosylceramide. The fatty acid content of gangliosides from both sources showed a similar composition. However, the neutral glycosphingolipid fatty acid content seemed to be quite different. Whole milk had fewer very-long-chain fatty acids (18.1% vs. 46.4% in MFGMs) and more medium-chain and unsaturated C18:1 and C18:2 fatty acids. Milk fat globules, MFGMs, lactosylceramide, and gangliosides GM3 and GD3 were observed to bind enterotoxigenic Escherichia coli strains. Furthermore, bacterial hemagglutination was inhibited by MFGMs and glycosphingolipids.     

Glycosyl transferases in mouse and human milk fat globule membranes

Summary Membranes isolated from mouse and human milk fat globules were found to contain the enzymes responsible for the synthesis of dolichol monophosphate mannose and dolichol monophosphate glucose as well as those involved in the transference of the glycosyl residues from the two dolichol derivatives to dolichol diphosphate oligosaccharides. The levels of most of the enzymes were comparable to those found in mouse mammary gland microsomes. The presence of enzymes involved in protein glycosylation via dolichol derivatives in the milk fat globule membrane provides evidence in favor of an outward flow of membrane components from the rough endoplasmic reticulum, where these enzymes are active in vivo, towards the cell surface.     

Chemical composition of the membranes of fat globules of cow's milk

The methods of microthin-layer chromatography on plates with silica gel and disc-electrophoresis in PAAG are used to determine the lipid and protein composition of fat globule membranes of cow milk on the first (foremilk) and the tenth day (milk) of lactation as well as of the buttermilk, a by-product of the technological processing of milk. Differences are found in the quantitative content of the basic classes of lipids and proteins in membranes of fat globules produced from foremilk and milk of cows. The membranes of buttermilk and milk fat globules are characterized by the identical qualitative and similar quantitative chemical composition, that permits using buttermilk as easily available and rich source of components from membranes of cow milk fat globules in the first place of phospholipids and sterols.     

Exploiting the Functionality of Lactic Acid Bacteria in Ice Cream

In this study, the fermented milk of three ropy (NCFB 2483, CRNZ 737, and LB18) and one non-ropy strains (LH30) of lactic acid bacteria were each added to aged ice cream mixes prepared with and without commercial stabilizers. Ice cream mixes with NCFB 2483 and LB18 (without stabilizers) achieved significantly higher overrun than the sample with non-ropy culture (with stabilizers). Evaluation of meltdown resistance and firmness of the ice cream indicated that samples with NCFB 2483 and LB18 ferment (without stabilizers) were comparable to ice cream with non-ropy culture (with stabilizers). Results of the particle size D[4,3] of the ice cream melt showed that the main mechanism for fat destabilization was not partial coalescence but fat aggregation due to the interactions of milk proteins and/or polysaccharides at the interface of fat globules. There was generally no significant difference in partial coalescence of the fat globules in all samples except LB18 (with stabilizers) where partial coalescence appeared to be significantly lower. The viscoelastic properties of ropy milk appeared to influence the functional properties of ice cream.