Properties of casein micelles cross-linked by transglutaminase

Factors affecting the cross-linking of milk proteins by transglutaminase (TGase) were studied. Cross-linking of caseins in bovine skim milk was optimal over a very wide pH range. The role of micellar calcium phosphate (MCP) in maintaining the integrity of TGase-treated casein micelles was studied by incubating skim milk with 0.01% (w/v) TGase at 30°C for 1–24 h, followed by removal of MCP from untreated or TGase-treated milk by acidification and dialysis. The protein content and profile of the samples were determined by Kjeldahl and SDS-PAGE, respectively. Whey proteins in unheated milk were not susceptible to TGase-induced cross-linking. The higher level of sedimentable protein in MCP-free TGase-treated milk than in MCP-free control milk indicated that TGase treatment partially prevented disintegration of the micelle on removal of MCP, probably due to extensive intramicellar TGase-induced cross-linking of casein molecules which led to the formation of sedimentable covalently bonded casein aggregates.     

A biological perspective on the structure and function of caseins and casein micelles

Caseins belong to a larger group of secreted calcium phosphate-binding phosphoproteins that have a natively unfolded conformation. Nearly all members of the group are involved in aspects of calcium phosphate biology and nearly all have recognition sites for phosphorylation by the Golgi protein kinase. In the caseins these are often close together in the primary structure, forming the so-called phosphate centres. Certain highly phosphorylated phosphopeptides derived from the calcium-sensitive caseins will combine with amorphous calcium phosphate to form defined chemical complexes called calcium phosphate nanoclusters. Both the substructure of casein micelles and the partition of salts in milk can be explained quantitatively by the ability of the calcium-sensitive caseins to sequester calcium phosphate and form nanocluster-like structures. A simple stability rule for milk can be derived by applying equilibrium thermodynamics to the process of calcium phosphate sequestration. In principle, the stability rule can be extended to problems of instability encountered in milk-processing operations and to the formulation of other types of high calcium foods.     

Observations of casein micelles in skim milk concentrate by transmission electron microscopy

The microstructure of casein micelles in ultrafiltrated (UF) skim milk concentrate at pH 6.5 and 5.8 was investigated by transmission electron microscopy using three different preparation methods. The volume fraction of the casein micelles in the UF concentrate was 62.8% (v/v) at pH 6.5 and fixation by glutaraldehyde revealed the close packing of micelles in the UF concentrate as well as a higher degree of micelle aggregation at pH 5.8. No details of the microstructure of the micellar surface or core could, however, be observed. Freeze-fracture of cryoprotected, i.e. glycerol, UF concentrate on the other hand, exposed the finer structures of the micellar core but no pH dependent differences were observed. As cryoprotection includes a dilution of the sample with glycerol, the packing of the micelles in the UF concentrate could not be observed. Undiluted UF concentrate exposed to rapid freezing using a propane jet followed by freeze-fracture exhibited development of ice crystals but rough areas on the micrographs were identified as fractured casein micelles. The micellar core appeared rougher and differences in the micellar core microstructure due to changing pH could be observed when this preparation method was used.     

Behaviour of partially cross-linked casein micelles under high pressure

High pressure (HP) treatment of a casein micelle suspension at 250 and 300 MPa leads to an initial rapid increase of its light transmission, as measured in situ , indicating micellar disruption. Subsequently, a much slower, partial reversal of the HP-induced increase in light transmission is observed, indicating re-association of micellar fragments. Partial internal cross-linking of the casein micelles by the enzyme transglutaminase prior to pressure treatment slows down both the disruption and the reassociation process considerably. It is proposed that covalent cross-linking provides the micelle with extra stability against pressure-induced disruption and also prevents a molecular reorganization process required to induce reassociation of micellar fragments during prolonged pressure treatment.     

Apparent voluminosity of casein micelles in the temperature range 35–70 °C

Casein micelles are basic units of dairy matrices that can be aggregated by reducing their electrostatic repulsion or by surface modifications. Studying casein micelles in terms of a colloidal suspension demands of a preferably complete physico-chemical characterisation. Process control in dairy technology as well as mechanistic models that explain the formation and structure of dairy products build on the specific hydration of the casein micelles. The effect of the temperature on the voluminosity of native casein micelles at pH 6.6–6.7 was investigated using rheometry covering a wide range of temperatures and mass fractions. Increasing temperature resulted in a constant decrease of the voluminosity up to 70 °C. A quadratic polynomial was tested to fit the temperature dependency the best. The apparent voluminosity of casein micelle suspensions was determined with 4.0 mL g⁻¹ at 35 °C, 3.6 mL g⁻¹ at 50 °C, and 3.5 mL g⁻¹ at 70 °C.     

Dynamics of casein micelles in skim milk during and after high pressure treatment

The effect of high hydrostatic pressure on turbidity of skim milk was measured in situ together with casein micelle size distribution. High pressure (HP) treatment reduced the turbidity of milk with a stronger pressure dependency between 50 and 300 MPa when the temperature was decreased from 20 to 5 °C, while at 30 °C (50–150 MPa) turbidity exceeded that of untreated milk. At 250 and 300 MPa turbidity decreased extremely. During pressurization of milk at 250 and 300 MPa, the turbidity initially decreased, but treatments longer than 10 min increased the turbidity progressively, indicating that re-association followed dissociation of casein micelles. Especially at 40 °C and at 250 and 300 MPa, the turbidity increased beyond untreated milk. Dynamic light scattering was used to investigate casein micelle sizes in milk immediately after long time (up to 4 h) pressurization at 250 and 300 MPa and casein micelle size distributions were bimodal with micelle sizes markedly smaller and markedly larger than those of untreated milk. Pressure modified casein micelles present after treatment of milk at 250 and 300 MPa were concluded to be highly unstable, since the larger micelles induced by pressure showed marked changes toward smaller particle sizes in milk left at ambient pressure.     

Preparation of casein phosphorylated peptides and casein non-phosphorylated peptides using alcalase

Casein was digested with a cheaper enzyme, alcalase, to produce casein phosphorylated peptides and casein non-phosphorylated peptides concurrently. The casein hydrolyzates were separated to the two kinds of peptides by using combined treatment of CaCl₂ and ethanol. Casein phosphorylated peptides and non-phosphorylated peptides constitute some peptides with molecular weight lower than 2509 Da and 2254 Da respectively as determined using size exclusion HPLC, particularly when a degree of hydrolysis of 20% for the casein hydrolyzates was achieved. At the end, the recovery of casein phosphorylated peptides reached 24%. Phosphorus component of casein phosphorylated peptides was found to be 3.08%. The nitrogen recovery of casein non-phosphorylated peptides was about 76%.     

High pressure effects on the structure of casein micelles in milk as studied by cryo-transmission electron microscopy

Milk was processed with high hydrostatic pressure in order to modify the casein micelles. Images, that in details showed the casein micelle structure in untreated and pressure-treated skim milk, were obtained by using cryo-transmission electron microscopy (cryo-TEM). Sizes and shapes adopted by casein micelles in pressurised milk are concluded to be a result of an equilibrium distribution between self-assembling casein molecules in the serum phase and caseins adsorbed to surfaces of casein micelles and are governed by an initial pressure-dependent displacement of caseins into the serum phase. Pressurisation of milk at moderately high pressure, in the range 150–300 MPa, favoured formation of a large number of small micelles that coexisted with a fraction of large micelles, and which appeared perfectly spherical with smooth and well-defined surfaces, features which are suggested to originate from secondary adsorption of caseins. Pressurisation of milk at 400 MPa favoured formation of smaller casein assemblies, with sizes between 30 nm and 100 nm. Measurements of free calcium concentration [Ca²⁺] showed that calcium was rebound to casein micelles after pressurisation of milk. Furthermore, the electron microscopy images indicated that the substructures were similar for pressure-modified casein micelles and casein micelles in untreated milk.     

Comparison of milk‐derived whey protein concentrates containing various levels of casein

Milk permeate was obtained from microfiltration (MF) and concentrated to produce milk‐derived whey protein concentrate (MWPC); MF at low temperatures yielded permeate with caseins (MWPC‐HC), and at higher MF temperatures, low concentrations of caseins were present (MWPC‐LC). MWPC samples were compared to whey protein concentrates (WPCs). Solutions of MWPC were less turbid and produced larger foam overruns and more stable foams than WPC. MWPC‐HC solutions produced the most stable foams. MWPC contained fewer types and lower relative quantities of volatile compounds than WPC before and after storage. Compared with WPC, MWPC have superior sensory, foaming and storage properties.     

Binding,stability, and antioxidant activity of curcumin with self-assembled casein–dextran conjugate micelles

This work studied the potential of self-assembled micelles of casein–dextran conjugates (CD) as a protective carrier for bioactive curcumin. CD was prepared through the Amadori rearrangement of the Maillard reaction. In casein micelles and CD micelles, the addition of curcumin can quench the intrinsic fluorescence of casein gradually. According to the double logarithm equation, the binding constants were determined as 3.9 × 10⁴ and 1.8 × 10⁵ M^?1 for the binding of curcumin with casein micelles and CD micelles, respectively. The higher affinity of hydrophobic binding of curcumin with CD micelles was ascribed to the more hydrophobic and compact structure of casein core surrounded by the hydrophilic dextran shell, which was supported by the fluorescence spectrum and fluorescence anisotropy of curcumin. Furthermore, CD micelles were found to be superior to casein micelles for improving the stability and radical scavenging activity of curcumin.     

Comparison of casein micelles in raw and reconstituted skim milk

During the manufacture of skim milk powder, many important alterations to the casein micelles occur. This study investigates the nature and cause of these alterations and their reversibility upon reconstitution of the powders in water. Samples of skim milk and powder were taken at different stages of commercial production of low-, medium-, and high-heat powders. The nature and composition of the casein micelles were analyzed using a variety of analytical techniques including photon correlation spectroscopy, transmission electron microscopy, turbidity, and protein electrophoresis. It was found that during heat treatment, whey proteins are denatured and become attached to the casein micelles, resulting in larger micelles and more turbid milk. The extent of whey protein attachment to the micelles is directly related to the severity of the heat treatment. It also appeared that whey proteins denatured during heat treatment may continue to attach to casein micelles during water removal (evaporation and spray-drying). The process of water removal causes casein and Ca in the serum to become increasingly associated with the micelles. This results in much larger, denser micelles, increasing the turbidity while decreasing the viscosity of the milk. During reconstitution, the native equilibrium between colloidal Ca and serum Ca is slowly reestablished. The reequilibration of the caseins and detachment of the whey proteins occur even more slowly. The rate of reequilibration does not appear to be influenced by shear or temperature in the range of 4 to 40°C.     

The production of volatile compounds in model casein systems with varying fat levels as affected by low-frequency ultrasound

The effects of low-frequency ultrasound on the production of volatile compounds in model casein protein systems containing various fat concentrations of 2%, 4% and 6% (w/w) were investigated. Ultrasound application was performed at 20 kHz for up to 10 min which corresponded to energy densities ranging from 9.54 to 190.8 J mL⁻¹. Similar volatile compounds were detected both in pure fat and mixtures of casein and fat (CF) systems. These volatiles belonged to the groups of aldehydes, ketones, esters, alcohols and hydrocarbons, which were the products of oxidation of lipids or protein degradation due to acoustic cavitation. The amount of fat in the casein systems had minor effects on the production of volatiles, whereas the production of volatile compounds was significantly affected by the ultrasound treatment. Short sonication times <5 min generated similar volatile profiles to the untreated samples. In contrast, prolonged sonication for 5 and 10 min considerably increased the production of volatile compounds and the amounts of fatty acids. Thus, the application of low–frequency ultrasound for short periods should be considered to minimise the production of volatile compounds which can ultimately affect the taste.     

Digestibility and allergenicity assessment of enzymatically crosslinked β‐casein

Crosslinking enzymes are frequently used in bioprocessing of dairy products. The aim of this study was to examine the effects of enzymatic crosslinking on IgE binding, allergenicity and digestion stability of β‐casein (CN). β‐CN was crosslinked by transglutaminase, tyrosinase, mushroom tyrosinase/caffeic acid and laccase/caffeic acid. The IgE binding to β‐CN was compared in vitro by CAP inhibition assay, ELISA inhibition as well as ex vivo by basophil activation assay. Crosslinked CNs were digested by simulated gastric fluid for 15 and 60 min and obtained digests analyzed for their ability to inhibit IgE binding by CAP inhibition assay and SDS‐PAGE. The ability of crosslinked CNs to activate basophils was significantly reduced in seven patients in the case of CN crosslinked by laccase and moderately reduced in the case of tyrosinase/caffeic acid crosslinked CN (in two cow's milk allergy patients tested with different allergen concentrations). The response to various crosslinked CNs differed individually among patients' sera tested by ELISA inhibition assay. The presence of caffeic acid hampered digestion by pepsin, and this effect was most pronounced for the tyrosinase/caffeic acid crosslinked CN. The laccase/caffeic acid and mushroom tyrosinase/caffeic acid had the highest potential in mitigating IgE binding and allergenicity of the β‐CN out of all investigated enzymes. The presence of a small phenolic compound also increased digestion stability of β‐CN.     

Characterization of casein lactosylation by capillary electrophoresis and mass spectrometry

Capillary electrophoresis (CE) and mass spectrometry have been used to verify the formation of lactosylated casein variants. CE was performed in a hydrophilically coated capillary at low pH and in the presence of urea. Lactosylated α-casein, β-casein, and κ-casein migrate shortly after the unmodified proteins. Evidence for casein lactosylation was obtained by electrospray ionization-mass spectrometry (ESI-MS). Lactosylated β-casein can be monitored not only in milk and milk powders but also in the complex protein mixture of processed cheese. The formation of lactosylated β-casein A1 and A2 during heating of processed cheese was found to correlate with the furosine content. Consequently, CE of casein may be a possible method for directly assessing the extent of the early Maillard reaction in dairy products.     

Microdetermination of phosphorus from infant formulas, casein and casein phosphopeptides

A spectrophotometric method, which has been proposed for the determination of phosphorus in biological fluids based on the formation of a phosphomolybdate complex, is adapted and validated for the determination of phosphorus in milk-based infant formulas, casein, casein phosphopeptides (CPPs) and the soluble fractions resulting from their gastrointestinal digestion, as well as in the fractions resulting from the ion-exchange high-performance liquid chromatography (IE-HPLC) of CE90CPP and in the soluble fraction of infant formula. The detection and quantification limits (1.1 and 3.6 mg P/100 g sample, respectively) are low enough for the purpose described. The linearity (from 0.1 to 8 g of phosphorus in the assay) is adequate. The precision of the method, expressed as relative standard deviation, is lower than 1%, and the accuracy checked by the analysis of SRM 1846: milk-based powdered infant formula is good. The quality of the method, together with the low cost and ease of use, makes it suitable for routine analysis.     

Kinetic description of heat‐induced cross‐linking reactions of whey protein‐free casein solutions

Heat treatment of milk products induces several physico‐chemical changes that can compromise rennetability and milk protein functionality. The aim of this study was to investigate the kinetic parameters of heat‐induced polymerisation of whey protein‐free casein micelles in the native environment of skim milk, which were produced by microfiltration and ultrafiltration in a diafiltration mode. The intra‐ or intermolecular polymerisation of casein monomers by covalent cross‐linking of amino acids was analysed by gel‐permeation chromatography. The degree of polymerisation and the amounts of polymerisation products such as lysinoalanine and histidinoalanine leading to cross‐linking of proteins could be described as zero‐order reaction.     

Chaperone‐like activity of β‐casein and its effect on residual in vitro activity of horseradish peroxidase

In this study, the residual activity horseradish peroxidase was used as a novel marker of chaperone‐like activity of β‐casein under elevated temperature. It was shown that β‐casein does affect residual activity of horseradish peroxidase (HRP) depending on the concentration and molar ratio between proteins. Incubating HRP (0.1 mg mL^?1) for 10 min at 72 °C resulted in residual activity of 59 ± 5%, while addition of 1 mg mL^?1 β‐casein resulted in increase in residual activity up to 85 ± 1%. Increased residual activity is not merely attributed to an effect of higher total protein concentration, as similar experiment with bovine serum albumin resulted in residual activity of horseradish peroxidase that was significantly lower than without any addition. The effect of β‐casein on HRP disappears when pH is below the isoelectric point of β‐casein. It was also proven by light scattering studies that β‐casein interacts with horseradish peroxidase when the temperature was increased from 25 to 70 °C whereas interactions seem to cease when temperature was lowered back to 25 °C. This study highlights how specific proteins can influence enzyme activity, which is of potential importance for various industries such as enzyme manufacturers and food industry.     

Application of high‐power ultrasounds during red wine vinification

Wine colour is one of the main organoleptic characteristics influencing its quality. It is of special interest in red vinifications due to the economic resources that wineries have to invest for the extraction of the phenolic compounds responsible for wine colour, compounds that are mainly located inside the skin cell vacuoles, where the volatile compounds are also found. The transfer of phenolic compounds from grapes to must during vinification is closely related to the type of grapes and the winemaking technique. During traditional winemaking, grapes are crushed and skin macerated for several days, with pumps overs to facilitate the colour extraction. To increase this extraction, some chemical (maceration enzymes) or physical technologies (thermovinification, cryomaceration, flash‐expansion) can be applied. In this work, a new methodology has been tested. This methodology consists in the application of high‐power ultrasounds to crushed grapes to increase the extraction of phenolic compounds. Crushed grapes were treated with this non‐thermal technology and vinified, with 3, 6 and 8 days of skin maceration time, and the results were compared with a control vinification, where crushed grapes were not subjected to any treatment and were skin macerated during 8 days. The wine chromatic characteristics (determined spectrophotometrically) and the individual phenolic compounds (anthocyanins and tannins, determined by HPLC) were followed during the maceration period, at the end of alcoholic fermentation and after two months in bottle. Also, the wine volatile compounds were determined by GC‐MS. The wines made with ultrasound‐treated grapes showed differences with the control wine, especially regarding total phenol content and tannin content. The wines elaborated with sonicated grapes and with only three days of skin maceration time presented similar concentration of anthocyanins and twice the concentration of tannins than control wines elaborated with 8 days of skin maceration.     

Production and properties of casein hydrolysate microencapsulated by spray drying with soybean protein isolate

The aim of this work was to encapsulate casein hydrolysate by spray drying with soybean protein isolate (SPI) as wall material to attenuate the bitter taste of that product. Two treatments were prepared: both with 12 g/100 g solids and containing either two proportions of SPI: hydrolysate (70:30 and 80:20), called M1 and M2, respectively. The samples were evaluated for morphological characteristics (SEM), particle size, hygroscopicity, solubility, hydrophobicity, thermal behavior and bitter taste with a trained sensory panel using a paired-comparison test (non-encapsulated samples vs. encapsulated samples). Microcapsules had a continuous wall, many concavities, and no porosity. Treatments M1 and M2 presented average particle sizes of 11.32 and 9.18 μm, respectively. The wall material and/or the microencapsulation raised the hygroscopicity of the hydrolysate since the free hydrolysate had hygroscopicity of 53 g of water/100 g of solids and M1 and M2 had 106.99 and 102.19 g of water/100 g of solids, respectively. However, the hydrophobicity decreases, the absence of a peak in encapsulated hydrolysates, and the results of the panel sensory test considering the encapsulated samples less bitter (p < 0.05) than the non-encapsulated, showed that spray drying with SPI was an efficient method for microencapsulation and attenuation of the bitter taste of the casein hydrolysate.