High-pressure-induced interactions between milk fat globule membrane proteins and skim milk proteins in whole milk

The association of beta-lactoglobulin (beta-LG) and alpha-lactalbumin (alpha-LA) with milk fat globule membrane (MFGM), when whole milk was treated by high pressure in the range 100 to 800 MPa, was investigated using sodium dodecyl sulfate (SDS)-PAGE under reducing and nonreducing conditions. In SDS-PAGE under reducing conditions, beta-LG was observed in the MFGM material isolated from milk treated at 100 to 800 MPa for 30 min, and small amounts of alpha-LA and kappa-casein were also observed at pressures >600 MPa for 30 min. However, these proteins were not observed in SDS-PAGE under nonreducing conditions. These results indicate that beta-LG and alpha-LA associated with MFGM proteins via disulfide bonds during the high-pressure treatment of whole milk. The amount of beta-LG associated with the MFGM increased with an increase in pressure up to 800 MPa and with increasing time of pressure treatment. The maximum value for beta-LG association with the MFGM was approximately 0.75 mg/g of fat. Of the major original MFGM proteins, no change in butyrophilin was observed during the high-pressure treatment of whole milk, whereas xanthine oxidase was reduced to some extent beyond 400 MPa. In contrast to the behavior during heat treatment, PAS 6 and PAS 7 were stable during high-pressure treatment, and they remained associated with the MFGM.     

不同均质工艺处理对巴氏杀菌乳脂肪球膜蛋白质组成的影响

乳脂肪球大小和膜蛋白组分的变化决定了脂肪球稳定性,从而影响巴氏杀菌乳在贮藏期内的品质稳定性。本研究通过十二烷基硫酸钠-聚丙烯酰胺凝胶电泳和液相色谱-质谱联用法分析不同预热温度（50、60、70?℃）和不同均质压力（20、30、40、45?MPa）对脂肪球膜蛋白的影响,并通过稳定性分析仪探究脂肪球膜蛋白变化与稳定性的关系。结果表明,均质工艺对脂肪球膜蛋白种类无显著影响,但对脂肪球膜蛋白的含量有一定影响：黄嘌呤氧化还原酶（xanthine dehydrogenase/oxidase,XO）、嗜乳脂蛋白（butyrophilin,BTN）、脂肪滴结合蛋白（adipophilin,ADPH）在预热60 ℃时的含量最低,黏液素（mucin 1,MUC1）在预热60 ℃时的含量最高,脂肪酸结合蛋白（fatty acid binding protein,FABP）、组织糖蛋白高碘酸烯夫6/7（periodic acid Schiff 6/7,PAS6/7）的含量随着预热温度的升高而减少,组织糖蛋白高碘酸薛夫IV（cluster of differentiation 36,CD36）的含量随着预热温度的升高而增多;XO、PAS6/7、BTN、ADPH、FABP在均质压力40 MPa时含量最低,CD36的含量随均质压力的增加而减少;脂肪球膜蛋白构成中,牛血清白蛋白（bovine serum albumin,BSA）、αs1-酪蛋白（casein,CN）和β-CN含量增加,其中BSA含量增加最明显。综上,推测均质工艺导致αs1-CN、β-CN和BSA组分参与了脂肪球膜的构建,并对脂肪球稳定性产生了积极的影响。     

Proteolysis of milk fat globule membrane proteins during in vitro gastric digestion of milk

The influence of gastric proteolysis on the physicochemical characteristics of milk fat globules and the proteins of the milk fat globule membrane (MFGM) in raw milk and cream was examined in vitro in simulated gastric fluid (SGF) containing various pepsin concentrations at pH 1.6 for up to 2 h. Apparent flocculation of the milk fat globules occurred in raw milk samples incubated in SGF containing pepsin, but no coalescence was observed in either raw milk samples or cream samples. The changes in the particle size of the fat globules as a result of the flocculation were dependent on the pepsin concentration. Correspondingly, the physical characteristics of the fat globules and the composition of the MFGM proteins in raw milk changed during incubation in SGF containing pepsin. The major MFGM proteins were hydrolyzed at different rates by the pepsin in the SGF; butyrophilin was more resistant than xanthine oxidase, PAS 6, or PAS 7. Peptides with various molecular weights, which altered with the time of incubation and the pepsin concentration, were present at the surfaces of the fat globules.     

Interactions of fat globule surface proteins during concentration of whole milk in a pilot-scale multiple-effect evaporator

The changes in milk fat globules and fat globule surface proteins during concentration of whole milk using a pilot-scale multiple-effect evaporator were examined. The effects of heat treatment of milk at 95 degrees C for 20 s, prior to evaporation, on fat globule size and the milk fat globule membrane (MFGM) proteins were also determined. In both non-preheated and preheated whole milk, the size of milk fat globules decreased while the amount of total surface proteins at the fat globules increased as the milk passed through each effect of the evaporator. In non-preheated samples, the amount of caseins at the surface of fat globules increased markedly during evaporation with a relatively small increase in whey proteins. In preheated samples, both caseins and whey proteins were observed at the surface of fat globules and the amounts of these proteins increased during subsequent steps of evaporation. The major original MFGM proteins, xanthine oxidase, butyrophilin, PAS 6 and PAS 7, did not change during evaporation, however, PAS 6 and PAS 7 decreased during preheating. These results indicate that the proteins from the skim milk were adsorbed onto the fat globule surface when the milk fat globules were disrupted during evaporation.     

Major proteins of the goat milk fat globule membrane

Fat is present in milk as droplets of triglycerides surrounded by a complex membrane derived from the mammary epithelial cell called milk fat globule membrane (MFGM). Although numerous studies have been published on human or bovine MFGM proteins, to date few studies exist on MFGM proteins from goat milk. The objective of this study was thus to investigate the protein composition of the goat MFGM. Milk fat globule membrane proteins from goat milk were separated by 6% and 10% sodium dodecyl sulfate-PAGE and were Coomassie or periodic acid-Schiff stained. Most of MFGM proteins [mucin-1, fatty acid synthase, xanthine oxidase, butyrophilin, lactadherin (MFG EGF-8, MFG-E8), and adipophilin] already described in cow milk were identified in goat milk using peptide mass fingerprinting. In addition, lectin staining provided a preliminary characterization of carbohydrate structures occurring on MFGM proteins from goat milk depending on α_S1-casein genotype and lactation stage. We provide here first evidence of the presence of O-glycans on fatty acid synthase and xanthine oxidase from goat milk. A prominent difference between the cow and the goat species was demonstrated for lactadherin. Indeed, whereas 2 polypeptide chains were easily identified by peptide mass fingerprinting matrix-assisted laser desorption/ionization-time of flight analysis within bovine MFGM proteins, lactadherin from goat milk consisted of a single polypeptide chain. Another striking observation was the presence of caseins associated with MFGM preparations from goat milk, whereas virtually no caseins were found in MFGM extracts from bovine milk. Taken together, these observations strongly support the existence of a singular secretion mode previously hypothesized in the goat.     

Invited review: Bovine milk fat globule membrane as a potential nutraceutical

For the last 15 yr, a great deal of knowledge has been accumulated on health beneficial factors, protein and nonprotein, of bovine milk fat globule membrane (MFGM). Among the health-beneficial components of the MFGM are cholesterolemia-lowering factor, inhibitors of cancer cell growth, vitamin binders, inhibitor of Helicobacter pylori, inhibitor of beta-glucuronidase of the intestinal Escherichia coli, xanthine oxidase as a bactericidal agent, butyrophilin as a possible suppressor of multiple sclerosis, and phospholipids as agents against colon cancer, gastrointestinal pathogens, Alzheimer's disease, depression, and stress. All of the above compel us to consider bovine MFGM as a potential nutraceutical.     

Developmental changes in the milk fat globule membrane proteome during the transition from colostrum to milk

Shotgun proteomics, using amine-reactive isobaric tags (iTRAQ), was used to quantify protein changes in milk fat globule membranes (MFGM) that were isolated from d 1 colostrum and compared with MFGM from d 7 milk. Eight Holstein cows were randomly assigned to 2 groups of 4 cow sample pools for a simple replication of this proteomic analysis using iTRAQ. The iTRAQ labeled peptides from the experiment sample pools were fractionated by strong cation exchange chromatography followed by further fractionation on a microcapillary high performance liquid chromatograph connected to a nanospray-tandem mass spectrometer. Data analysis identified 138 bovine proteins in the MFGM with 26 proteins upregulated and 19 proteins downregulated in d 7 MFGM compared with colostrum MFGM. Mucin 1 and 15 were upregulated greater than 7-fold in MFGM from d 7 milk compared with colostrum MFGM. The tripartite complex of proteins of adipophilin, butyrophilin, and xanthine dehydrogenase were individually upregulated in d 7 MFGM 3.4-, 3.2-, and 2.6-fold, respectively, compared with colostrum MFGM. Additional proteins associated with various aspects of lipid transport synthesis and secretion such as acyl-CoA synthetase, lanosterol synthase, lysophosphatidic acid acyltransferase, and fatty acid binding protein were upregulated 2.6- to 5.1-fold in d 7 MFGM compared with colostrum MFGM. In contrast, apolipoproteins A1, C-III, E, and A-IV were downregulated 2.6- to 4.3-fold in d 7 MFGM compared with colostrum MFGM. These data demonstrate that quantitative shotgun proteomics has great potential to provide new insights into mammary development.     

Changes in the surface protein of the fat globules during homogenization and heat treatment of concentrated milk

The changes in milk fat globules and fat globule surface proteins of both low-preheated and high-preheated concentrated milks, which were homogenized at low or high pressure, were examined. The average fat globule size decreased with increasing homogenization pressure. The total surface protein (mg m-2) of concentrated milk increased after homogenization, the extent of the increase being dependent on the temperature and the pressure of homogenization, as well as on the preheat treatment. The concentrates obtained from high-preheated milks had higher surface protein concentration than the concentrates obtained from low-preheated milks after homogenization. Concentrated milks heat treated at 79 degrees C either before or after homogenization had greater amounts of fat globule surface protein than concentrated milks heat treated at 50 or 65 degrees C. This was attributed to the association of whey protein with the native MFGM (milk fat globule membrane) proteins and the adsorbed skim milk proteins. Also, at the same homogenization temperature and pressure, the amount of whey protein on the fat globule surface of the concentrated milk that was heated after homogenization was greater than that of the concentrated milk that was heated before homogenization. The amounts of the major native MFGM proteins did not change during homogenization, indicating that the skim milk proteins did not displace the native MFGM proteins but adsorbed on to the newly formed surface.     

Oxidation of aldehydes by xanthine oxidase located on the surface of emulsions and washed milk fat globules

The enzymatic activity of xanthine oxidase (XO) located within the native and recombined milk fat globule membrane (MFGM) on emulsion surfaces was investigated after successive washing with deionised water (DW) or simulated milk ultrafiltrate (SMUF). DW was more effective than SMUF at removing non-MFMG proteins from the globule surface. Surface XO activity on a protein basis increased after three washes due to loss of MFGM proteins to the serum phase. Recombined emulsions had higher surface enzymatic activity than washed native fat globule samples. The oxidation of acetaldehyde, 3-methylbutanal, 2-methylpropanol and 2-methylbutanal to the corresponding acids by XO on the globule surface was analysed. A higher proportion of aldehydes were depleted at higher XO activity when the initial aldehyde concentration was constant, and for higher initial concentrations of aldehydes. The recovery of aldehydes and acids was above 79%, indicating that the depleted aldehydes were mostly converted to the corresponding acids.     

The impact of cream churning conditions on xanthine oxidase activity and oxidation–reduction potential in model emulsion systems

Six types of milk fat globule membrane (MFGM) fractions were isolated from fresh raw cream using various churning conditions at different temperature (10, 15 or 20 °C) and pH values (5.5 or 6.6) and characterised for protein composition, xanthine oxidase (XO) content and activity, and oxidation–reduction potential (E_h). A greater proportion of non-membrane proteins was found at higher temperatures and higher cream pH, and the XO content decreased significantly under these conditions. XO activity was greater at lower temperatures and pH, yielding a more positive E_h value for the emulsions. Storage at 4 °C for 14 d significantly reduced the Eh of the emulsions to between −320 mV and −580 mV for low pH/low temperature, and high pH/high temperature emulsions, respectively. This study suggests that it is possible to obtain MFGM fractions with specific Eh reducing ability by altering churning conditions.     

Chemical changes in bovine milk fat globule membrane caused by heat treatment and homogenization of whole milk

The effects of heat treatment and homogenization of whole milk on chemical changes in the milk fat globule membrane (MFGM) were investigated. Heating at 80 degrees C for 3-18 min caused an incorporation of whey proteins, especially beta-lactoglobulin (beta-Ig), into MFGM, thus increasing the protein content of the membrane and decreasing the lipid. SDS-PAGE showed that membrane glycoproteins, such as PAS-6 and PAS-7, had disappeared or were weakly stained in the gel due to heating of the milk. Heating also decreased free sulphydryl (SH) groups in the MFGM and increased disulphide (SS) groups, suggesting that incorporation of beta-Ig might be due to association with membrane proteins via disulphide bonds. In contrast, homogenization caused an adsorption of caseins to the MFGM but no binding of whey proteins to the MFGM without heating. Binding of caseins and whey proteins and loss of membrane proteins were not significantly different between milk samples that were homogenized before and after heating. Viscosity of whole milk was increased when milk was treated with both homogenization and heating.     

Protein and lipid composition of bovine milk-fat-globule membrane

Using mass spectrometry and other analytical methods, the proteins and lipids isolated from bovine milk-fat-globule membrane (MFGM) were characterised. The major MFGM protein composition consisted of xanthine oxidase, butyrophilin, adipophilin and periodic acid schiff 6/7. The minor proteins were polymeric immunoglobulin receptor protein, apolipoprotein E, apolipoprotein A1, 71 kDa heat-shock cognate protein, clusterin, lactoperoxidase, immunoglobulin heavy chain and peptidylprolyl isomerase A, actin, fatty acid-binding protein, cluster of differentiation 26 and mucin. The MFGM lipid component consisted predominantly of triglycerides (56%) and phospholipids (40.6%). The major fatty acids associated with the glycerol phospholipids were C16:0, C18:0, C18:1 and C18:2. Sphingomyelin had a high proportion of C20:0, C23:0, C24:1 and C24:0 fatty acids linked to the sphingoloid base. However, the sphingoloid base itself consisted predominantly of C16:1, C17:1 and C18:1 fatty acids. Small amounts of both lactosyl- and glucosyl-cerebrosides were found in the bovine MFGM sample and trace levels of lyso-phosphatidyl ethanolamine and lyso-phosphatidyl choline were detected.     

Impact of cream washing on fat globules and milk fat globule membrane proteins

Milk proteins, contained within the aqueous phase surrounding fat globules, should be removed before analysis of the composition of the native milk fat globule membrane (MFGM). The effect of the conditions applied during washing of cream on MFGM integrity has not been fully studied, and factors potentially effecting a modification of MFGM structure have not been systematically assessed so far. In this study, a cream separator was used to investigate the impact of cream washing on milk fat globule stability and the corresponding loss of MFGM proteins. Flow velocity, fat content, and type of washing solution were varied. Particle size measurements and protein analyses were carried out after each washing step to determine fat globule coalescence, removal of skim milk proteins, and efficiency of MFGM isolation. Significant differences in fat globule stability and protein amount in the MFGM isolates were measured using different washing conditions.     

Changes in the surface protein of the fat globules during ultra-high pressure homogenisation and conventional treatments of milk

Disruption of fat globules upon homogenisation provokes a reduction of their size and a concomitant increase in their specific surface area. In order to overcome this phenomenon, the milk fat globule membrane (MFGM) adsorbs non-native MFGM proteins. The aim of the present study was to examine the effects of UHPH conditions (temperature and pressure) on the milk fat globule and the surface proteins by comparison with conventional treatments applied in the dairy industry. Transmission electron microscopy and SDS-PAGE revealed major differences. In UHPH-treated milk, casein micelles were found to be adsorbed on the MFGM in a lesser extent than in conventional homogenisation–pasteurisation. However, greater adsorption of directly bonded casein molecules, released by UHPH through the partial disruption of casein micelles, was observed especially at high UHPH pressures. Adsorption of whey proteins on the MFGM of conventionally homogenised–pasteurised milk was mainly through intermolecular disulfide bonds with MFGM material, whereas in UHPH-treated milk, disulfide bonding with both indirectly and directly adsorbed caseins was also involved.     

Impact of different milk fat globule membrane preparations on protein composition,xanthine oxidase activity,and redox potential

The protein composition, redox potential (E_h), and xanthine oxidase (XO) content and activity were determined for anhydrous milk fat emulsions containing milk fat globule membrane (MFGM) fractions derived from either buttermilk or commercial sources of bovine α-serum, β-serum, and buttermilk powder (BMP). Caseins were the dominant proteins in the MFGM fractions isolated from BMP and buttermilk, whereas fractions from α- and β-serum contained higher amounts of membrane proteins. The XO content and activity was >70-fold and >700-fold higher in α- and β-serum samples, respectively, compared with the BMP fraction. The E_h values of the recombined emulsions were highest for α-serum (196 mV), and β-serum (169 mV), followed by BMP (131 mV). These positive values contrasted with the highly negative E_h of the buttermilk emulsion (−580 mV). This study demonstrates how milk-processing methods can alter the composition and functionality of the MFGM.     

Technical difficulties and future challenges in isolating membrane material from milk fat globules in industrial settings – A critical review

Research on the milk fat globule and surrounding membrane began a century ago. Synthesis and secretion mechanisms of milk fat globules in mammary epithelial cells are well documented, but there is still controversy about the composition of the milk fat globule membrane (MFGM). In recent years, interest in isolating MFGM material has increased because of the presumed functional potential of the proteins and lipids. However, no standardised isolation procedure exists to our knowledge. Consequently, published reports on the MFGM composition differ significantly. Various isolation methods under different conditions were applied, and contradictory effects on the MFGM structure were obtained. In addition to compositional changes, losses of MFGM material also occur under particular conditions. This makes it difficult to compare reports on the composition of the isolated MFGM material. We therefore saw a necessity to critically review past and current literature with emphasis on the reported isolation methods and respective results.     

Ultrasonication retains more milk fat globule membrane proteins compared to equivalent shear-homogenization

Ultrasonication, like common shear homogenization, can reduce the milk fat globule size and may change the milk fat globule membrane (MFGM). This work compared the effect of ultrasonication to equivalent shear homogenization on MFGM proteins and lipid-derived volatile components. Results showed that treating milk with ultrasound at 35 kJ/L would realize a similar size distribution of the milk fat globules as shear-homogenization at 20 MPa. Proteomics analysis revealed that in total 192 MFGM proteins were identified and quantified and a number of these proteins were lost after both treatments; however, more MFGM proteins remained after ultrasonication than after shear-homogenization. SDS-PAGE results showed that milk plasma proteins, and especially caseins, were absorbed on the milk fat globules after both treatments. In addition, the amount of the volatile free fatty acids increased after both treatments.Industrial relevance: Ultrasonication, as an innovative food processing technology, in comparison to traditional homogenization, was shown to equally efficiently decrease the MFG size, but lead to less damage to native MFGM proteins, which may be due to its longer homogenization time window. These results increased knowledge on the biochemical changes of milk fat globules after their size reduction and showed that ultrasonication could be used as a novel approach to improve dairy product quality.     

Influence of thermal processing conditions on flavor stability in fluid milk: benzaldehyde

Flavor loss in dairy products has been associated with enzymatic degradation by xanthine oxidase. This study was conducted to investigate the influence of milk thermal processing conditions (or xanthine oxidase inactivation) on benzaldehyde stability. Benzaldehyde was added to whole milk which had been thermally processed at 4 levels: (1) none or raw, (2) high temperature, short time (HTST) pasteurization, (3) HTST pasteurization, additionally heated to 100 degrees C (PAH), and (4) UHT sterilized. Additionally, PAH and UHT milk samples containing benzaldehyde (with and without ferrous sulfate) were spiked with xanthine oxidase. Azide was added as an antimicrobial agent (one additional pasteurized sample without) and the microbial load (total plate count) was determined on d 0, 2, and 6. The concentration of benzaldehyde and benzoic acid in all milk samples were determined at d 0, 1, 2, 4, and 6 (stored at 5 degrees C) by gas chromatography/mass spectrometry in selective ion monitory mode. Over the 6-d storage period, more than 80% of the benzaldehyde content was converted (oxidized) to benzoic acid in raw and pasteurized milk, whereas no change in the benzaldehyde concentration was found in PAH or UHT milk samples. Furthermore, the addition of xanthine oxidase or xanthine oxidase plus ferrous sulfate to PAH or UHT milk samples did not result in benzaldehyde degradation over the storage period.     

Influence of storage, heat, and homogenization upon xanthine oxidase activity of milk

Xanthine oxidase activity in milk was determined by measuring the rate of formation of vanillic acid from vanillin. Raw milk received at a dairy plant had .208 units xanthine oxidase activity per ml and after 24-h storage at 4 C, .228 units per ml. Upon further storage activity decreased. Heating the fresh raw milk in a water bath to 55 C increased xanthine oxidase activity to .236 units per ml. Partial inactivation of the enzyme occurred when milk was heated at 60, 65, or 70 C for 5 min, and destruction was almost complete with heat at 75 C for 5 min. Raw milk heated at 48 C for 5 min and homogenized at pressures between 70.3 and 281.2 kg/cm2 had xanthine oxidase activities which were a linear function of pressure and showed that each additional kg/cm2 pressure resulted in additional xanthine oxidase activity of .16 milliunits per ml of milk.