The distribution of glyco-kappa-casein and carbohydrate-free kappa-casein between large and small bovine casein micelles, and its implication in micelle structure

Determination of the proportion of κ-casein hydrolysed by rennet on coagulation of skim-milk

A method has been developed for quantitative determination of para-κ-casein, involving spectrophotometric scanning of stained protein bands following polyacrylamide gel electrophoresis. The rate of hydrolysis of κ-casein in skim-milk at pH 6·6 and 30 °C was compared with that in EDTA-treated skim-milk under the same conditions. This showed that at the visually observed clotting time, at least 90% of the total κ-casein in milk had been hydrolysed. The time course of the reaction was consistent with all the κ-casein molecules being hydrolysed with the same efficiency. The results strongly suggest that essentially all of the κ-casein in milk is equally accessible to rennet action. This is consistent with the casein micelle being porous, or having all the κ-casein on the surface.

Formation of reconstituted casein micelles with human beta-caseins and bovine kappa-casein

Human beta-casein (CN) is the major protein of the human milk casein fraction (approximately 80%) and exists in six calcium-sensitive forms, having zero to five organic phosphates per molecule. The major forms are the doubly-phosphorylated (beta-CN-2P; approximately 30%) and the quadruply phosphorylated (beta-CN-4P; approximately 35%) forms. Although calcium-insensitive, kappa-CN is known for its role in preventing the precipitation of beta-CN in the presence of Ca+2, but it is not known how the different levels of phosphorylation may affect this. In the present investigation, turbidity, measured at 400 nm, was determined at increasing temperatures (4 up to 37 degrees C) for solutions of beta-CN-2P and beta-CN-4P (3 mg/ml in 0.02 M NaCl, 0.01 M imidazole, pH 7) individually and also mixed with bovine kappa-CN in 6/1 and 3/1 weight ratios of beta/kappa and containing 0, 5, and 10 mM Ca+2. The results indicate that the first step of micelle formation probably leads to polymers of limited size, the only complexes available to beta-CN-2P under most conditions. With beta-CN-4P, these polymers aggregate further to give reconstituted micelles, probably because of the ability to form crosslinks at this phosphorylation level. The formation of reconstituted micelles under various conditions of pH, Ca+2 concentration and kappa-CN content indicates that both hydrophobic interactions and Ca+2 bridges or crosslinks may contribute to protein aggregation and micelle building.

The two-stage coagulation of milk proteins in the minimum of the heat coagulation time-pH profile of milk: effect of casein micelle size

Milks with casein micelles larger or smaller than control milk were prepared by differential centrifugation. The heat stability of these modified milks increased markedly throughout the pH range 6.4 to 7.1 with decreasing casein micelle size. Within the region of the minimum in the heat coagulation time-pH profile, the control milk coagulated by a two-stage process, but the modified milks, because of their narrower casein micelle size distribution, coagulated by a single-stage process at the pH of minimum stability. The content of kappa-CN and protein hydration increased as the size of the casein micelles decreased, and the level of glycosylation of kappa-CN and protein surface hydrophobicity increased as a function of micelle size. The effect of casein micelle size on the heat stability of milk is likely to be related to changes in the above physico-chemical properties.

Liberation of tryptic fragments from caseinomacropeptide of bovine kappa-casein involved in platelet function. Kinetic study

Carbohydrate-free caseinomacropeptide (CMP) was purified from rennet-hydrolysed caseinate by trichloroacetic acid precipitation and DEAE-TSK Fractogel-650 ion-exchange chromatography. To study the liberation of 106-112, 106-116 and 113-116 fragments from carbohydrate-free CMP involved in platelet function, a quantitative study was made on the rate of hydrolysis of the three peptidic bonds that are susceptible to the action of trypsin. Data were obtained from reverse-phase (Ultrabase column) and cationic-exchange (Mono S column) h.p.l.c. On the basis of the disappearance of substrate, kcat. and Km were respectively 3.95 s-1 and 0.2 mM. The two 111-112 and 112-113 bonds were split according to similar kinetic parameters (kcat. = 1.97 s-1, Km = 0.2 mM) and much faster than the 116-117 bond. The difference in susceptibility of the bonds can probably be attributed to the nature of residues flanking the primary proteolytic sites rather than to their accessibility to the proteinase. On the basis of our results the 106-116 fragment cannot be formed.

Caseins of various origins and biologically active casein peptides and oligosaccharides: structural and physiological aspects

The first part of the present review is focused on structural aspects concerning the so far studied casein fractions of various origins: they are compared to the four classical major bovine caseins (alpha s1-, alpha s2-, beta- and kappa). The calcium-sensitive casein fractions are always phosphorylated whereas kappa-caseins are glycosylated. The study of the casein genes showed that the calcium-sensitive caseins diverged from a common ancestral gene and during the evolution, intergenic and intragenic duplications occurred. The considerable conservation of the phosphorylation sites emphasizes the importance of phosphorylated residues for the function of caseins, i.e. the formation of micelles and the binding of Ca2+. In kappa-caseins all the prosthetic sugar groups are linked by O-glycosidic linkages: their number varies from 0 to 5 in bovine kappa-casein and up to 10 in human kappa-casein. The structures of the known kappa-casein carbohydrate moieties are described. Finally the milk clotting process (interaction kappa-casein/chymosin) is compared to the blood clotting process (interaction fibrinogen/thrombin): a large number of similarities could be noted between both clotting phenomena. The second part of the review is devoted to the study of short casein peptides endowed with various biological activities. Some of them behaved as immunomodulators or casomorphins or angiotensin I converting enzyme inhibitors; others demonstrated an effect on platelet functions. A 'strategic zone' containing immunostimulating and opioid peptides could be located in cow and human beta-caseins. Furthermore bitter peptides, emulsifying peptides, calcium absorption enhancing peptides, chymosin-inhibiting peptides, have also been described and several further properties have been attributed to the kappa-caseinoglycopeptide; two tetrasaccharides isolated from the latter possess blood group activities. In conclusion caseins, the main milk proteins, should not only be considered as a nutriment but as a possible source of biologically active components. If, in the future, some of the discussed active peptides cannot be characterized in vivo, they can all, nevertheless, be synthesized and used either as food additives or in pharmacology.

Analysis by fast protein liquid chromatography of variants of kappa-casein and their relevance to micellar structure and renneting

Fast protein liquid chromatography was used to study the kappa-casein fraction of casein micelles from bulk milk and from milk from individual animals homozygous for kappa-caseins A and B. The extent of glycosylation of the kappa-casein appeared to have no effect on its distribution in casein micelles of different sizes, nor did it affect the rate at which kappa-casein was destroyed during renneting. The rate of breakdown of kappa-casein during renneting was also almost independent of micellar size. The results may indicate a difference between methods which analyse for intact kappa-casein or for the product macropeptide during renneting.

Glycosylated kappa-caseins and the sizes of bovine casein micelles. Analysis of the different forms of kappa-casein

Fast protein liquid chromatography (FPLC) of the kappa-casein from bovine casein micelles of different sizes is used to demonstrate that the proportions of glycosylated and non-glycosylated forms of kappa-casein do not vary with micellar size. The results suggest that glycosylated kappa-casein is distributed similarly to unglycosylated kappa-casein within the micellar structure.

Localization of glycosylated kappa-casein on thin sections of casein micelles by lectin-labelled gold markers

The location of the glycosylated part of kappa-casein in bovine casein micelles was investigated using gold particles (6 nm in diameter) labelled with Ricinus communis lectin and Limulus polyphemus lectin. The pattern of marking of thin sections of micelles was similar with both lectins. Glycosylated kappa-casein was distributed uniformly throughout most micelles of all sizes. Peripheral location of glycosylated kappa-casein was observed only occasionally in some of the largest micelles. Quantitative data indicated that the concentration of the glycosylated protein was constant in micelles of increasing sizes. As larger micelles contain less total kappa-casein than smaller ones, these data indicated that a greater proportion of their kappa-casein is glycosylated. These results support models for casein micelle structure where kappa-casein is distributed throughout the micelles. They do not agree with "coat-core" structures.

Localization of kappa-casein on thin sections of casein micelles by the gold method

The ultrastructural location of kappa-casein in bovine casein micelles was investigated by the protein A-gold method. Casein micelles, fixed in glutaraldehyde, were embedded at low temperature to enhance immunocytochemical marking of thin sections. kappa-Casein was found distributed throughout the micelles of all sizes with a higher concentration in the smaller micelles. No peripheral location of kappa-casein was observed, even in the larger micelles. These results do not agree with "coat-core" structures proposed for casein micelles. However they favor models where kappa-casein is distributed uniformly throughout the micelles.

Cow kappa-casein: structure of the carbohydrate portion

The detailed sugar sequences of the two main carbohydrate portions of cow kappa-casein were established by enzymic and chemical methods and by mass spectrometry. The sugar sequences correspond to widespread sugar parts occurring in many glycoproteins.

Glycosylation of kappa-casein. I. Localization and characterization of sialyltransferase in bovine mammary gland

A sialyltransferase (CMP-N-acetylneuraminate:D-galactosyl-glycoprotein N-acetylneuraminyltransferase, EC 2.4.99.1) which attaches N-acetylneuraminic acid to the terminal end of the carbohydrate chain of kappa-casein was found to be concentrated in Golgi apparatus-enriched fractions of bovine mammary gland. Maximum sialyltransferase activity was obtained at pH 5.5 and 37 degrees C in the presence of 1 mM dithiothreitol and Triton X-100. A Km of 0.19 mg asialo-kappa-casein/ml (0.01 mM) was obtained for the sialyltransferase. Native kappa-casein also served as acceptor for N-acetylneuraminic acid transferase of Golgi apparatus-enriched fractions although at a slower rate than did asialo-kappa-casein. The sialyltransferase has a divalent cation requirement for maximum activity which was best satisfied by the presence of 10 mM Mn2+.

Fractionation by size of casein micelles on controlled-pore glass

Casein micelles have been separated from skim milk by chromatography on CPG-10 3000 glass beads. Fractionation of the micelles according to size has been demonstrated. Polyacrylamide gel electrophoresis of urea treated micelles reveals that different relative amounts of the major casein components occur in the various micelle fractions. No discernible dissociation of the micelles into monomeric caseins has been observed.

Structural aspects of the milk clotting process. Comparative features with the blood clotting process

The enzyme chymosin and its substrate, a casein fraction called k-casein, are involved in the milk clotting process. Recent data concerning the structure (peptide and sugar moieties) of various k-caseins and their role in casein micelles formation and stabilization are presented. The molecular events occurring during the primary phase of chymosin action on k-casein are discussed. Finally some structural features concerning more particularly the caseinoglycopeptides and the fibrinopeptides as well as the action of chymosin and thrombin involved in the milk and blood clotting processes are compared. Three examples of sequences of portions of k-caseins and fibrinogen presenting homology are presented.

The role of beta-lactoglobulin in the primary phase of rennin action on heated casein micelles and heated milk

It has been shown that the inhibition caused by heat treatment, of the primary phase of rennin action on casein micelles, is dependent on the presence of β-lactoglobulin. The degree of inhibition increased with increasing amounts of added β-lactoglobulin for both heated casein micelles and heated skim-milk to a constant value. The results are fully consistent with the hypothesis that the inhibition is caused by complex formation between β-lactoglobulin and κ-casein when milk is heated.