Detection in milk of a 60,000 Mr mouse and a 68,000 Mr human phosphorylated glycoprotein by histochemical analysis on polyacrylamide gels

Proteins in colostrum and skimmed milk from humans and mice were separated by electrophoresis on polyacrylamide gels and stained with Coomassie blue (CB), Ethyl-Stains-all (ESA), and periodic acid-Schiff (PAS) to investigate changes that may occur in milks throughout lactation. In mouse colostrum but not in mature mouse milk, a PAS-positive protein of apparent molecular weight of 60,000 stained prominently blue with ESA. A protein in human milk with a molecular weight of 68,000 stained similarly but was present throughout lactation. The intensity of blue staining of these minor proteins in milk approached that obtained with casein phosphoproteins. The metachromatic dye ESA stains phosphoproteins and sialic acid-rich glycoproteins blue to blue-green. Removal of phosphorus from the former and sialic acid from the latter results in those proteins staining red with ESA. The intensity of blue staining of the 60,000 and 68,000 Mr proteins was diminished but not lost following treatment with phosphatase. It was eliminated following neuraminidase digestion of the mouse protein and mild acid hydrolysis of the human protein. Coomassie blue staining of the proteins was not affected by these procedures. Following electrophoresis of milk and milk fractions in a non-sodium dodecyl sulfate-containing system, the proteins were identified by their characteristic staining properties with ESA and isolated.     

Isolation and properties of human kappa-casein

Human kappa-casein was isolated from human whole casein by gel filtration with Sephadex G-200 and hydroxylapatite chromatography in the presence of sodium dodecyl sulfate (SDS). The kappa-casein was calcium-insensitive and did stabilize human beta-casein and bovine alpha s1-casein against precipitation by calcium ions. Formation of micelles from human beta- and kappa-caseins, and calcium ions was confirmed by electron microscopic observation. On SDS-polyacrylamide gel electrophoresis (SDS-PAGE), a single band was obtained. The formation of para-kappa-caseins by chymosin was confirmed by SDS-PAGE. Two para-kappa-caseins with apparent molecular weights of 13,000 and 11,000 appeared. The molecular weight of intact human kappa-casein was estimated to be approximately 33,000. The human kappa-casein contained about 40% carbohydrate (15% galactose, 3% fucose, 15% hexosamines, and 5% sialic acid) and 0.10% (1 mol/mol) phosphorus. Its amino acid composition was similar to that of bovine kappa-casein except for serine, glutamic acid, and lysine contents.     

Comparison of casein of cynomolgus monkey (Macaca fascicularis) with human casein

Casein of cynomolgus monkey was compared with those from human and bovine milk. Cynomolgus monkey casein showed similar electrophoretical patterns to those of human casein on Disc- and SDS-electrophoresis. It consisted of beta- and kappa-casein-like components. The component corresponding to bovine alpha s1-casein was not detected. The beta-casein-like fraction of cynomolgus monkey showed 9 bands on Disc-PAGE. These were suggested to be the same protein binding different levels of phosphorus by dephosphorylation experiment using an acid phosphatase. The kappa-casein-like component of cynomolgus monkey was highly glycosylated (about 50% carbohydrate) similarly as human kappa-casein and the constituent carbohydrates were same as those detected in human kappa-casein (galactose, fucose, N-acetylgalactosamine, N-acetylglucosamine, and sialic acid). Amino acid composition of cynomolgus monkey kappa-casein bore a resemblance to those of both human and bovine kappa-caseins. Amino acid composition of cynomolgus monkey beta-casein was also similar to those of human and bovine beta-caseins.     

Isolation and some effects of functional, low-phenylalanine kappa-casein expressed in the milk of transgenic rabbits

Patients suffering certain metabolic diseases (e.g. phenylketonuria) need a low-phenylalanine diet throughout their lives. Transgenic rabbits were created to express low-phenylalanine kappa-casein in their milk. The aim was to demonstrate for the first time the feasibility of producing a modified milk protein in addition to normal milk proteins. A gene construct containing the coding region of the rabbit kappa-casein gene was modified by site-specific oligonucleotide directed mutagenesis. Four of the five phenylalanine amino acids present in the mature protein were mutated and the gene construct was used to create two transgenic rabbit lines. The transgenic rabbits produced the recombinant kappa-casein at a high level in their milk causing a reduction in the average size of the casein micelles. The low-phenylalanine kappa-casein was digestible with chymosin and it was separated from its native counterpart and from the other milk proteins by a one-step HPLC method on a reversed-phase column. In the future, low-phenylalanine casein produced in transgenic animals could be used as dietary replacements to meet the special requirements of certain consumer groups.     

Chemical and immunochemical characterization of caseins and the major whey proteins of rabbit milk.

Caseins were separated from whey proteins by acid precipitation of skimmed rabbit milk. Whole casein was resolved by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis into three major bands with apparent relative molecular masses (Mr of 31 000, 29 000 and 25 000. On agarose/urea-gel electrophoresis whole casein gave three bands with electrophoretic mobilities alpha, beta and gamma. The three components were purified by DEAE-cellulose chromatography under denaturing and reducing conditions. Each was shown to have a different amino acid, hexose and phosphorus content, as well as non-identical peptide fragments after proteinase digestion. The 31 000 Da (dalton) protein, of alpha-electrophoretic mobility, had a high phosphorus content (4.38%, w/w); the 29 000 Da peptide, of gamma-mobility, had the highest hexose content (2.2%, w/w), contained 0.8 cysteine residue per 100 amino acid residues and was susceptible to chymosin digestion corresponding thus to kappa-casein; the 25 000 Da protein migrated to the beta-position. The rabbit casein complex is composed of at least three caseins, two of which (alpha- and kappa-caseins) are analogous to the caseins from ruminants. Although caseins are poor immunogens, specific antibodies were raised against total and purified polypeptides. The antiserum directed against whole casein recognized each polypeptide, each casein corresponding to a distinct precipitation line. The antisera directed against each casein polypeptide reacted exclusively with the corresponding casein and no antiserum cross-reaction occurred between the three polypeptides. From whey, several proteins were isolated, characterized and used as antigens to raise specific antibodies. An iron-binding protein with an apparent Mr of 80 000 was shown to be immunologically and structurally identical with serum transferrin.     

Characterization of recombinant camel chymosin reveals superior properties for the coagulation of bovine and camel milk

Enzymatic milk coagulation for cheese manufacturing involves the cleavage of the scissile bond in kappa-casein by an aspartic acid protease. Bovine chymosin is the preferred enzyme, combining a strong clotting activity with a low general proteolytic activity. In the present study, we report expression and enzymatic properties of recombinant camel chymosin expressed in Aspergillus niger. Camel chymosin was shown to have different characteristics than bovine chymosin. Camel chymosin exhibits a 70% higher clotting activity for bovine milk and has only 20% of the unspecific protease activity for bovine chymosin. This results in a sevenfold higher ratio of clotting to general proteolytic activity. The enzyme is more thermostable than bovine chymosin. Kinetic analysis showed that half-saturation is achieved with less than 50% of the substrate required for bovine chymosin and turnover rates are lower. While raw camel milk cannot be clotted with bovine chymosin, a high clotting activity was found with camel chymosin.     

Calcium-ion and calmodulin-dependent kappa-casein kinase in rat mammary acini.

A Ca2+- and calmodulin-dependent casein kinase specific for dephosphorylated bovine kappa-casein was identified in a microsomal fraction of mammary acini prepared from rats in late lactation. This phosphorylation has an absolute requirement for Mg2+ for either the basal or the Ca2+- and calmodulin-dependent activity. One-half of the maximal stimulation is achieved at a calmodulin concentration of 204nM in the presence of Ca2+. The Ca2+- and calmodulin-dependent kinase activity (but not the basal activity) is inhibited by trifluoperazine. The casein kinase is associated with a microsomal fraction enriched in markers for plasma membrane and Golgi (5'-nucleotidase and galactosyltransferase respectively). The activity of this casein kinase remains relatively constant throughout lactation, but declines dramatically in 24h when rats are removed from their pups. This activity may represent the physiological activity responsible in part or whole for kappa-casein phosphorylation occurring before micelle formation and milk secretion.     

Amyloid fibril formation by bovine milk kappa-casein and its inhibition by the molecular chaperones alphaS- and beta-casein

Caseins are a unique and diverse group of proteins present in bovine milk. While their function is presumed to be primarily nutritional, caseins have a remarkable ability to stabilize proteins, i.e., to inhibit protein aggregation and precipitation, that is comparable to molecular chaperones of the small heat-shock protein (sHsp) family. Additionally, sHsps have been shown to inhibit the formation of amyloid fibrils. This study investigated (i) the fibril-forming propensities of casein proteins and their mixture, sodium caseinate, and (ii) the ability of caseins to prevent in vitro fibril formation by kappa-casein. Transmission electron microscopy (TEM) and X-ray fiber diffraction data demonstrated that kappa-casein readily forms amyloid fibrils at 37 degrees C particularly following reduction of its disulfide bonds. The time-dependent increase in thioflavin T fluorescence observed for reduced and nonreduced kappa-casein at 37 degrees C was suppressed by stoichiometric amounts of alphaS- and beta-casein and by the hydrophobic dye 8-anilino-1-naphthalene sulfonate; the inhibition of kappa-casein fibril formation under these conditions was verified by TEM. Our findings suggest that alphaS- and beta-casein are potent inhibitors of kappa-casein fibril formation and may prevent large-scale fibril formation in vivo. Casein proteins may therefore play a preventative role in the development of corpora amylacea, a disorder associated with the accumulation of amyloid deposits in mammary tissue.     

Nutritional value of proteins from edible seaweed Palmaria palmata (dulse)

Palmaria palmata (Dulse) is a red seaweed that may be a potential protein source in the human diet. Its protein content, amino acid composition, and protein digestibility were studied with algae collected every month over a 1-year period. Significant variations in protein content were observed according to the season: The highest protein content (21.9 +/- 3.5%) was found in the winter-spring period and the lowest (11.9 +/- 2.0%) in the summer-early autumn period. Most of the essential amino acids were present throughout the year. After 6-hour in vitro digestion in a cell dialysis using porcine pepsin and porcine pancreatin, the digestibility of proteins from Palmaria palmata crude powder, represented by dialyzed nitrogen, was estimated at 29.52 +/- 1.47%. Relative digestibility was 56%, using casein hydrolysis as 100% reference digestibility. In vitro digestibility of proteins extracted in water was analyzed by sodium dodecylsulfate polyacrylamide gel electrophoresis using either bovine trypsin, bovine chymotrypsin, pronase from Streptomyces griseus, or human intestinal juice. Dulse proteins were hydrolyzed to a limited extent, which confirmed a rather low digestibility. Hydrolysis rate was higher with trypsin and lower with chymotrypsin compared with the two other enzymatic systems, pronase and intestinal juice, respectively. The association of algal powder and protein extract to casein and bovine serum albumin, respectively, produced a significant decrease in the hydrolysis rate of the standard proteins. In conclusion, the digestibility of Palmaria palmata proteins seems to be limited by the algae non-proteic fraction.     

Kinetic study of the action of bovine chymosin and pepsin A on bovine kappa-casein

A study was carried out to determine the Michaelian parameters relative to the action of chymosin and pepsin A on bond Phe105-Met106 of bovine kappa0-casein (carbohydrate-free fraction in micellar state). The reaction was performed in citrate buffer, pH 6.2, at 30 degrees C. The reaction mixture was analysed by reverse phase HPLC. Dosages of peptide 106-169 (caseino macropeptide) at different reaction times from recordings of its absorbance at 220 nm gave the initial rates of reaction at each substrate concentration. From these values the following parameters were determined: kcat = 68.5 s-1, Km = 0.048 mM, kcat/Km = 1,413 mM-1 s-1 for chymosin, and kcat = 45 s-1, Km = 0.018 mM, kcat/Km = 2,439 mM-1 s-1 for pepsin A. For chymosin they are similar to those obtained previously in dimethyl glutarate buffer, pH 6.6, at 30 degrees C, using fragment 98-111 of kappa-casein as substrate. It can thus be concluded that neither the micellar state nor the presence of the whole peptide chain of kappa-casein (our conditions) significantly affect the action of chymosin on fragment 98-111, which seems to contain all information that makes bond 105-106 highly sensitive to chymosin. For pepsin A, only the information contained in fragment 103-108 appears to be required.     

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.     

A comprehensive study of the relationship between size and protein composition in natural bovine casein micelles

Casein micelles of bovine skimmed milk were fractionated by permeation chromatography on porous glass (CPG-10, 50 nm followed by CPG-10, 300 nm) at 30 degrees C. Micelles were pooled in eight eluant fractions and their size distribution was determined by electron microscopy. The composition of casein in the eight fractions was determined by quantitative hydroxyapatite chromatography. Micelle size decreased progressively with increasing elution volume, and volume-to-surface average diameter ranged from 154 nm in fraction 1 to 62 nm in fraction 8. Concurrently there was a decrease in relative proportions of alpha s- and beta-caseins and a large enrichment of kappa-casein, which changed from 4.1% total casein in fraction 1 to 12.1% total casein in fraction 8. At least half the decrease in alpha s-casein proportions was attributed to the alpha s1-casein component, but the data also suggested a decline in proportions of alpha s2-casein in the smallest micelle fractions. A plot of kappa-casein fractional content versus micelle surface-to-volume ratio gave a straight line (correlation coefficient from linear regression 0.98) from which an average kappa-casein surface coverage of 1.5 m2/mg or 47.3 nm2/molecule was obtained. If a constant surface coverage for kappa-casein is assumed, the parameters of the linear equation predict that micelle voluminosity is inversely related to micelle diameter, being approximately 30% larger in fraction 8 compared to fraction 1.     

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.     

On the effect of mutations in bovine or camel chymosin on the thermodynamics of binding κ‐caseins

Bovine and camel chymosins are aspartic proteases that are used in dairy food manufacturing. Both enzymes catalyze proteolysis of a milk protein, κ‐casein, which helps to initiate milk coagulation. Surprisingly, camel chymosin shows a 70% higher clotting activity than bovine chymosin for bovine milk, while exhibiting only 20% of the unspecific proteolytic activity. By contrast, bovine chymosin is a poor coagulant for camel milk. Although both enzymes are marketed commercially, the disparity in their catalytic activity is not yet well understood at a molecular level, due in part to a lack of atomistic resolution data about the chymosin—κ‐casein complexes. Here, we report computational alanine scanning calculations of all four chymosin—κ‐casein complexes, allowing us to elucidate the influence that individual residues have on binding thermodynamics. Of the 12 sequence differences in the binding sites of bovine and camel chymosin, eight are shown to be particularly important for understanding differences in the binding thermodynamics (Asp112Glu, Lys221Val, Gln242Arg, Gln278Lys. Glu290Asp, His292Asn, Gln294Glu, and Lys295Leu. Residue in bovine chymosin written first). The relative binding free energies of single‐point mutants of chymosin are calculated using the molecular mechanics three dimensional reference interaction site model (MM‐3DRISM). Visualization of the solvent density functions calculated by 3DRISM reveals the difference in solvation of the binding sites of chymosin mutants.     

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.     

Two physiological substrate-specific casein kinases are present in the bovine mammary gland

Two species of casein kinase from lactating bovine mammary gland have been identified; a Ca2+- and CM-independent casein kinase and a Ca2+- and CM-dependent casein kinase. The Ca2+- and CM-independent casein kinase phosphorylates previously dephosphorylated alpha s1-, beta- or kappa-casein while the Ca2+- and CM-dependent casein kinase prefers previously dephosphorylated beta- or kappa-casein as substrates. Two activities are indicated by their substrate specificity, sensitivity to Ca2+ and CM, pH maxima, and differential solubilization by anionic detergents. The presence of a regulated casein kinase in the lactating mammary gland suggests that casein phosphorylation may be a regulator of micelle formation or secretion.     

Expression of kappa-casein in normal and neoplastic rat mammary gland is under the control of prolactin

An 820-nucleotide-long cDNA clone for the kappa-casein (the casein micelle-stabilizing protein) from rat mammary gland was isolated, and its nucleotide sequence was determined. The deduced amino acid sequence from the nucleotide sequence revealed a signal peptide, 21 amino acids long, and a mature protein of 157 amino acids. The signal peptide of rat kappa-casein was highly homologous to that of the precursor to ovine kappa-casein. However, little homology was apparent when the mature kappa-casein protein sequences from ovine or bovine sources were compared with rat kappa-casein. The kappa-casein mRNA content of the mammary tissue was found to increase during its functional differentiation. Prolactin appears to modulate the production of kappa-casein mRNA. Mammary glands of virgin females had no detectable kappa-casein mRNA; however, a marked induction of kappa-casein mRNA was obtained by intravenous infusion of prolactin. Mammary carcinomas did not follow the same pattern. 7,12-Dimethylbenz[a]anthracene-induced mammary carcinomas had normally low levels of kappa-casein mRNA, but intravenous prolactin infusion increased the levels by 2-fold. The MTW9 mammary carcinoma that grows only in the presence of high levels of mammotropic hormones had kappa-casein mRNA content equivalent to that in 10-day lactating rat mammary gland. Continuous venous infusion of prolactin to MTW9 mammary carcinoma did not modify the kappa-casein mRNA levels. Nitrosomethylurea-induced mammary carcinomas had no detectable kappa-casein mRNA, and intravenous prolactin infusion was unable to induce it.     

Detection of the cholera toxin-binding activity of kappa-casein macropeptide and optimization of its production by the response surface methodology

The cholera toxin (CT)-binding activity of purified kappa-casein macropeptide (CMP) from bovine kappa-casein was detected. In addition, a statistical model was developed to optimize the production of CMP. CMP was prepared by chymosin hydrolysis of kappa-casein and a subsequent 3% trichloroacetic acid treatment. CMP was further fractionated in an ion-exchange column by FPLC. CT binding activity was eluted at 0.18 M NaCl and was a single 8.9 kDa peptide without tyrosine and arginine residues. The CT binding activity was rapidly lost by a carbohydrase treatment. The conditions for CMP production with chymosin were optimized by using the response surface methodology (RSM). The estimated optimum levels of the factors were as follows: reaction temperature, 38.5 degrees C; pH, 6.44; and time, 35.9 min. A validation experiment was performed in which CMP was prepared under the predicted parameters, and it was ascertained that the estimated optimum conditions gave better production of CMP than any other conditions.     

Primary structure of the casein macropeptide of kappa casein of buffalo]

The complete amino acid sequence of Italian water buffalo (Bubalus arnee) caseinomacropeptide, the C-terminal fragment released from kappa-casein by chymosin, has been determined. It contains 64 amino acid residues including one phosphoserine and differs from its bovine (Bos taurus) B counterpart by 10 amino acid substitutions. The sequence of the last 11 amino acid residues of para-kappa-casein is also reported. In relation to the Ala148/Asp substitution which is responsible for the different electrophoretic behaviour of bovine kappa-caseins B and A, water buffalo kappa-casein is homologous to the bovine variant B. It is suggested that a variant Thr136-Ala148 might be the wild type of the Bos genus.     

The involvement of one of the three histidine residues of cow kappa-casein in the chymosin-initiated milk clotting process.

Cow kappa-casein has been modified by photo-oxidation in the presence of rose bengal and by the chemical reagents diethyl pyrocarbonate, 2-hydroxy-5-nitro-benzyl bromide and iodoacetic acid. Photo-oxidation resulted in the destruction of histidine and tryptophan residues and all of the histidines could be ethoxy-formylated by treatment with diethyl pyrocarbonate. Both procedures caused a loss in the susceptibility of the Phe-Met linkage of kappa-casein to chymosin hydrolysis. Treatment of kappa-casein with 2-hydroxy-5-nitrobenzyl bromide and iodoacetic acid caused the loss of tryptophan and methionine residues respectively but, in both cases, the susceptibility of the modified protein to chymosin hydrolysis remained unaffected. Of the amino acids examined it is concluded that only the histidine residues of cow kappa-casein are important for the hydrolytic action of chymosin and, furthermore, the treatment with diethyl pyrocarbonate suggests that only one of the three histidines plays an essential role.