K-Casein Suppresses Melanogenesis in Cultured Pigment Cells

The effects of bovine milk proteins on melanogenesis in B16 cells were examined. Both whey protein isolate and casein exhibited depigmenting properties. Among the major protein components of milk—including β-lactoglobulin, α-lactalbumin, α-, β-, and k-casein—only K-casein exhibited the depigmenting effect. However, the carboxyl terminal peptide of K-casein, glycomacropeptide, did not show this activity. Also, K-casein promoted the proliferation of the cells and inhibited the activity of tyrosinase in the cells. These results indicate that K-casein acts as a melanogenesis-suppressing modulator.     

Improvement of the Surface Functional Properties of β-Lactoglobulin and α-Lactalbumin by Heating in a Dry State

Controlled heating in a dry state greatly improved the surface functional properties of whey proteins (β-lactoglobulin and α-lactalbumin). Although whey proteins were completely insolubilized by heating at 80°C in an aqueous solution, their solubility was kept even after heating at 80°C in a dry state (7.5% moisture content) for 5 days. The surface hydrophobicity of α-lactalbumin was increased during the dry-heating, while that of β-lactoglobulin was decreased. In addition, the fluorescence spectra excited at 280 nm of dry-heated whey proteins suggested the significant conformational changes. High-performance gel chromatography showed that a considerable amount of soluble aggregates was formed in the dry-heated β-lactoglobulin, while a small amount of soluble aggregate was observed in the dry-heated α-lactalbumin. The foaming properties of dry-heated whey proteins were increased to about 3 times that of untreated proteins. The emulsifying properties of dry-heated whey proteins were also increased, compared to untreated proteins, although a slight decrease in the emulsion stability was observed in dry-heated β-lactoglobulin. The improvement of the surface properties seemed to come from the partial unfolding suitable for the formation of foam film and the entrapment of oil droplets.     

Computer analyses of characteristic infrared bands of globular proteins.

Infrared spectra of myoglobin, ribonuclease, lysozyme, α-chymotrypsin, α-lactalbumin, and β-lactoglobulin A were obtained in deuterium oxide solution in units of absorbance versus wavenumber from 1340 to 1750 cm^?1. The spectra were resolved into Gaussian components by means of an iterative computer program. Resolved characteristic absorption peaks for the two infrared active amide I′ components of antiparallel chain-pleated sheets (β-structure) were obtained. The characteristic amide I′ peaks of α-helical regions and apparently unordered regions overlap in D₂O solution. Absorptivity values for the resolved β-structure peak around 1630 cm^?1 were estimated on the basis of the known structure of ribonuclease, lysozyme, and β-chymotrypsin. The β-structure content of β-lactoglobulin was estimated to be ca. 48% of α-lactalbumin ca. 18%, and of α_s-casein close to zero. The results are in general agreement with conclusions drawn from circular dichroism and optical rotatory dispersion studies.     

Interaction of Bovine β-Lactoglobulin and Other Bovine and Human Whey Proteins with Retinol and Fatty Acids

The interaction of bovine and human whey proteins with retinol and palmitic acid has been studied. Using gel filtration it was found that bovine β-lactoglobulin and α-lactalbumin and serum albumin from both species bind retinol in vitro while the ability to bind palmitic acid is restricted to bovine β-lactoglobulin and bovine and human serum albumin. Using equilibrium dialysis, β-lactoglobulin was found to display two binding sites for retinol per dimeric molecule with an association constant of 1.5 × 10⁴m^-1. Competition experiments showed that when the concentration ratio between total fatty acids and retinol is similar to that found in milk, palmitic acid competes with the binding of retinol to β-lactoglobulin.     

Escherichia coli Heat-Labile Enterotoxin Binds to Glycosylated Proteins with Lactose by Amino Carbonyl Reaction

The binding of Escherichia coli heat-labile enterotoxin (LT) type I to glycosylated proteins with lactose (Galβ1-4Glc) by amino carbonyl reaction was studied by the Western blot assay and by the microtiter well binding assay. LT bound to a lactose-α-lactalbumin amino carbonyl product (Lac-LA), whereas cholera toxin did not. The binding ability of Lac-LA was abolished by β-galactosidase treatment, indicating that the terminal galactose is essential for the binding of LT. The binding of LT to Lac-LA was inhibited by galactose and lactose, and most effectively inhibited by lactulose (Galβ1-4Fru), which is a structural analog of the Amadori rearrangement product of the amino carbonyl reaction between lactose and an ε-amino group of a lysine residue (lactuloselysine). The results suggest that LT recognizes the portion of lactuloselysine in Lac-LA. LT also bound to a melibiose (Galα1-6Glc)-α-lactalbumin amino carbonyl product (Mel-LA), but the binding ability of Mel-LA was weaker than that of Lac-LA, suggesting that the β1-4 linked terminal galactose is dispensable but preferable for the binding. Furthermore, LT bound to the amino carbonyl products of lactose with β-lactoglobulin, caseins, bovine serum albumin, and ovalbumin. These results indicate that LT binds to the amino carbonyl products between proteins and sugars containing the terminal galactose, such as lactose.     

Role of Tyrosine Residues in Interactions between Casein Components

It was indicated from ultraviolet difference spectra and ultracentrifugal experiments that associations occurred between two casein components (α_s- and κ-caseins, β- and κ-caseins and α_s- and β-caseins) at lower CaCl₂ concentrations (2~3 mm) and that aromatic amino acid residues participated in the associations. Chemical modification studies with 2-hydroxy-5-nitrobenzylbromide indicated that tryptophane residues of each casein component were not essential for these associations. It was also demonstrated by nitration of tyrosine residues with tetranitromethane that tyrosine residues of κ-casein were essential for α_s·κ-association and for β·κ-association and that tyrosine residues of α_s-casein were important to α_s·β-association.

Interactions between casein components were also studied at higher CaCl₂ concentration (10 mm) which is enough for micelle formation. It was found that tyrosine residues of κ- casein played an important role for the stabilization of α_s- and β-caseins. Properties of the nitrated-β-casein were almost the same as that of the native β-casein except the absorption spectrum. α_s·β-Interaction in the presence of 10 mm CaCl₂ was investigated by use of the nitrated-β-casein instead of the native β-casein. It was proved that α_s-casein was stabilized by the nitrated-β-casein and that precipitation of the nitrated-β-casein increased in the presence of α_s-casein.

The mechanism of interactions between casein components at higher CaCl₂ concentration (10 mm) are discussed in connection with the associations at lower CaCl₂ concentrations (2~3 mm).     

Effect of 1-Anilino-8-naphthalenesulfonate on Properties and Associations of αs-, β- and κ-Caseins

It was indicated from fluorescence spectra and fluorescence titration that a hydrophobic probe, 1-anilino-8-naphthalenesulfonate (ANS), binds to casein components (α_s-, β- and κ-caseins). Fluorescence intensity and affinity of ANS-κ-casein complex were larger than that of ANS-α_s- and ANS-β-casein complexes. Enhancements of fluorescence intensity of complexes of casein components were observed by the addition of KCI or CaCl₂. Reason for the enhancement was postulated to be the increase of the quantum yield of the ANS fluorescence caused by the environmental change of ANS binding region of the casein components.

Marked increase of sedimentation coefficient of β-casein in the presence of KCl or CaCl₂ at 10°C was caused by the addition of ANS. This may be responsible for the stimulation of the Ca-dependent precipitation of β-casein by the addition of ANS.

It was found that α_s · κ-association was prevented by ANS and that hydrophobic interaction have an important role for α_s · κ-association.     

Solubility and reactivity of caseins and β-lactoglobulin in protic solvents

The study of the solubility of unstructured proteins (α_S1-, β-, and κ-casein) and well-structured globulin (β-lactoglobulin) in low water binary solvent systems demonstrated the crucial importance of solvent polarity and neutralization of protein polar functions on the final outcome of solubility experiments. The solubilities up to 38, 56, and 96% in CHCl₃/CH₃OH (1/1, v/v) acidified with HCl and up to 5, 10, and 25% in CHCl₃/CH₃OH (1/1, v/v) in the presence of triethylamine (TEA) were obtained for κ-, α_S1-, and β-casein, respectively. The importance of protein charge neutralization was apparent when the solubilization was performed in basified CHCl₃/CH₃OH media, giving the optimal results when the studied proteins were brought before to their isoionic point. The maximum solubility of β-casein at its pI in 30–70% methanol in CHCl₃ was reaching 50–60% with triethylamine (TEA) added. β-lactoglobulin could be solubilized up to 70% in CHCl₃/CH₃OH (7/3, v/v) acidified with HCl and up to 40% in CHCl₃/CH₃OH (3/7, v/v) in the presence of TEA. The observed yield of reductive alkylation of β-lactoglobulin was much higher (98%) when performed in studied solvent system than in aqueous conditions (75%). Apparently, steric hindrance of the well-folded β-barrel (in aqueous conditions) structure masks the portion of ε-NH₂ groups. In the case of unstructured aqueous media β-casein, 90% alkylation yields were obained in organic and aqueous conditions.     

Differential Thermal Analysis of Milk Proteins

Differential thermal analysis (DTA) was used for study of milk protein denaturation. Protein solutions produced an endothermic peak of characteristic shape and temperature of peak minimum. The peak minimum is considered the coagulation temperature of the protein.

The influence of pH and additives such as sugars and NaCl was clearly observed on the thermograms of β-lactoglobulin solution. Addition of κ-casein to β-lactoglobulin solution showed an inhibitory effect on the heat coagulation.

Solid proteins produced two-stage exothermic peaks between 200°C and 400°C.

DTA was a useful method in the study of heat denaturation and degradation of protein.     

Milk Protein Synthesis, Gene Expression, and Hormonal Responsiveness in Primary Cultures of Mammary Cells from Lactating Sheep

A ruminant mammary cell culture that accurately reproduces mammary function in vitro would be a valuable tool in studies of ruminant lactation, With this in mind, we have examined milk protein synthesis and secretion, milk protein mRNA abundance, and hormonal responsiveness in primary cultures of mammary acini from lecturing sheep. α- and β-casein protein synthesis, β-lactoglobulin synthesis, and α-casein, β-casein, and β-lactoglobulin secretion are maintained at high levels for 8 h in culture, but then decline to approximately 25% of maximal rates between 8 and 24 h in culture, whereas synthesis of other proteins remains unaltered. The relative abundance of α-S₁-casein, β-lactoglobulin, and α-lactalbumin mRNAs similarly decline between 8 and 24 h in culture. Extracellular labeled α-casein is increased fourfold in the presence of fetal calf serum (FCS). In total, FCS alters the abundance of 47 of 68 secreted proteins detected by two-dimensional electrophoresis. However, FCS and lactogenic/galactopoietic hormones had no effect on the rate of decline of mammary function and did not promote any regaining of function when present for up to 9 days in culture. These results suggest that providing its limitations are recognized, this primary cell culture system may be useful in studying some aspects of ruminant mammary function in vitro.     

Studies on the Proteolytic Action of Dairy Lactic Acid Bacteria

Intracellular protease (IPLB) of Streptococcus cremoris was extracted from the cells, which were cultivated in liquid media, by momentarily disrupting between two disks by high pressure.

The hydrolyzing modes of α_s-, crude k-, β-, and whole casein by IPLB of Str. cremoris or rennet were observed through the released amounts of tyrosine, sialic acid, NPN, and calcium insensitive substance. Relative specific turbidity of casein solution and dissymmetry coefficient of casein were measured. Particle weight and UV absorption spectrum of each high molecular hydrolyzate of whole casein were also determined.

Among four kinds of casein fractions, α_s- or crude k-casein was most easily hydrolyzed by IPLB of Str. cremoris or rennet. Relative specific turbidity of crude k-casein solution was remarkably, but those of α_s-, β-, and whole casein slightly increased by the action of IPLB of Str. cremoris or of rennet. Changes of dissymmetry coefficients were negligibly induced by these two enzymes. Absorption spectrum of IPLB-Str. cremoris-casein showed some conformational change.

It was recognized that intracellular protease (IPLB) of L. bulgaricus, L. helveticus or Str. lactis, all together, more easily hydrolyzed α_s-casein than crude k-, β-, and whole casein. By the actions of three IPLBs, relative specific turbidity of crude k-casein solution remarkably but those of α_s-, β-, and whole casein slightly increased, and dissymmetry coefficients of these casein fractions changed negligibly.

Particle weight of whole casein hydrolyzed by each IPLB for five days was larger than that of control casein. UV absorption of each whole casein hydrolyzed by a IPLB increased at the wave length range of 280~250 mμ.     

Properties of Acid Casein and Casein Micelles from Milk Destabilized by Frozen Storage

No difference was found in calcium sensitivity, electrophoretic and optical properties between acid caseins prepared from skimmilk before and after frozen storage (up to 180 days at ?7°C).

Destabilization of casein micelles can not be explained either by the reduction of solvation of the micelles or by the liberation of κ-casein from the micelles. However, when storage period was extended (about six months), splitting of a part of κ- and β-casein from the micelles to soluble form was observed, suggesting a drastic change of structure of the destabilized casein micelles.     

The potential inhibitory effect of β-casein on the aggregation and deposition of Aβ1-42 fibrils in Alzheimer’s disease: insight from in-vitro and in-silico studies

Aβ_1-40 and Aβ_1-42 have been shown to be the main components of the amyloid plaques found in the extracellular environment of neurons in Alzheimer’s disease. β-Casein, a milk protein, has been shown to display a remarkable chaperone ability in preventing the aggregation of proteins. In this study, the ability of β-casein to suppress the amyloid fibril formation of Aβ_1-42 has been examined through in vitro studies and molecular docking simulation. The results demonstrate the inhibitory effect of β-casein on fibril formation in Aβ_1-42, in a concentration dependent manner, suggesting that the chaperone binds to the Aβ_1-42 and prevents amyloid fibril formation. Molecular docking results show that the inhibitory effect of the β-casein may be due to binding of the chaperone with the aggregation-prone region of the Aβ_1-42 mainly via hydrophobic interactions. β-Casein probably binds to the CHC and C-terminal domain of the Aβ_1-42, and stabilizes proteins by inhibiting the conversion of monomeric Aβ_1-42 into fibrils. Thus our data suggests that the hydrophobic interactions between β-casein and Aβ_1-42 play an important role in the burial of the hydrophobic part of the Aβ_1-42. This means that β-casein maybe considered for use in preventing amyloid fibril formation in degenerative diseases such as Alzheimer.     

A Further Separation and Some Properties of β-Lactamase I

A carbohydrate binding protein was found in mid-lactating rat mammary gland. This rat mammary gland lectin agglutinated trypsinized rabbit erythrocytes and the hemagglutination was inhibited by the addition of β-d-galactosides such as lactose, melibiose, UDP-galactose and thio-d-galactoside. The lectin was partially purified by affinity chromatography on a column of Sepharose 4B to which asialo-fetuin had been covalently linked. Rat mammary gland lectin is a glycoprotein with a molecular weight of 14,800, estimated from SDS-PAGE, or 16,800 from gel filtration.

The occurrence of two glycoproteins, C4-casein and α-lactalbumin, is known in rat milk. Bovine κ-casein is a well-characterized glycoprotein. These glycoproteins were found to be bound by the rat mammary gland lectin, when they were desialylated by the action of neuraminidase. Neuraminidase-untreated α-lactalbumin also bound to the lectin but to a lesser extent. The level of the lectin in rat mammary gland was greatly reduced during regression of the gland after weaning.     

Relations between divalent cation binding and ATPase activity in coupling factor from chloroplast.

Although 150 individual samples of milk from Italian water buffalo (Bubalus arnee) were examined by acid and alkaline gel electrophoresis, no polymorphism was observed for α-lactalbumin and β-lactoglobulin. After isolation and purification of these two proteins their amino acid compositions were determined and compared with those of the corresponding bovine proteins. The sequence alignments of 36 and 17 amino-acids from the N-terminal ends and 2 amino-acids from the C-terminal ends of buffalo α-lactalbumin and β-lactoglobulin, respectively, have been established. Our results indicate that buffalo α-lactalbumin differs from its cow B counterpart by a substitution Asn/Gly at position 17 and by another substitution, likely Glu/Gln or Asp/Asn, at an unknown position. Buffalo β-lactoglobulin is homologous to the bovine B variant. Three substitutions differentiate the two proteins: Ile/Leu and Val/Ile at positions 1 and 162 respectively; a further one, Gln/Ile, has not yet been located. According to these results the B variant of bovine β-lactoglobulin might be the wild type of the Bos genus.     

Antigenic Reactivity of Dephosphorylated αs1-Casein,Phosphopeptide from β-Casein and O-Phospho-l-serine towards the Antibody to Native αs1 -Casein

To study whether the phosphoserine residue is associated with the antigenicity of bovine α_s1- casein, we examined the antigenic reactivity of dephosphorylated α_s1-casein, peptide 1~25 from bovine β-casein and three chemical reagents with IgG antibody specific to native α_s1-casein by an enzyme-linked immunosorbent assay.

The reaction between native α_s1-casein and its IgG antibody was inhibited more strongly by native α_s1-casein than by dephosphorylated α_s1-casein. Peptide 1~25, having a phosphoserine residue-concentrated region from bovine β-casein, noticeably inhibited the reaction between native α_s1 -casein and its antibody. Furthermore, the O-phospho-l-serine residue inhibited the reaction of peptide 61~123 with anti-native α_s1-casein antibody, although l-serine and sodium phosphate showed no measurable inhibition.

These results suggest that the phosphoserine residue associated with part of an antigenic site in bovine α_sl-casein.     

Determination of Acidic Component of Konjac Mannan

mRNA was isolated from mammary glands of lactating cow by affinity chromatography on poly(U)-Sepharose. The mRNA was heterogeneous on 3% agarose gel electrophoresis in the presence of 6m urea. The molecular weight of the main peak was estimated to be 3.3 x 10⁵. The mRNA was translated in a cell-free protein synthesizing system derived from wheat germ extract, and the translation products were analysed by the indirect immunoprecipitation method using specific antisera for casein components. About 50% of the total protein directed by this mRNA was casein. The relative amounts of α_s1-, β-,and k-casein in the translation products were nearly the same as those in bovine milk. The immunoprecipitates were analysed on sodium dodecyl sulfatepolyacrylamide gradient gel (15~20%) electrophoresis, and their mobilities were compared with those of dephosphorylated and non-glycosylated casein as standard, α_s1- and k Casein synthesized in vitro migrated more slowly than standard caseins, while synthesized β-casein migrated slightly faster than the standard β-casein.     

In vivo digestomics of milk proteins in human milk and infant formula using a suckling rat pup model

Human milk is the optimal mode of infant feeding for the first several months of life, and infant formulas serve as an alternative when breast-feeding is not possible. Milk proteins have a balanced amino acid composition and some of them provide beneficial bioactivities in their intact forms. They also encrypt a variety of bioactive peptides, possibly contributing to infant health and growth. However, there is limited knowledge of how milk proteins are digested in the gastrointestinal tract and bioactive peptides are released in infants. A peptidomic analysis was conducted to identify peptides released from milk proteins in human milk and infant formula, using a suckling rat pup model. Among the major milk proteins targeted, α-lactalbumin and β-casein in human milk, and β-lactoglobulin and β-casein in infant formula were the main sources of peptides, and these peptides covered large parts of the parental proteins’ sequences. Release of peptides was concentrated to specific regions, such as residues 70–92 of β-casein in human milk, residues 39–55 of β-lactoglobulin in infant formula, and residues 57–96 and 145–161 of β-CN in infant formula, where resistance to gastrointestinal digestion was suggested. In the context of bioactive peptides, release of fragments containing known bioactive peptides was confirmed, such as β-CN-derived opioid and antihypertensive peptides. It is therefore likely that these fragments are of biological significance in neonatal health and development.     

Evolution of Functional Genes in Cetaceans Driven by Natural Selection on a Phylogenetic and Population Level

Cetaceans represent an evolutionary lineage marked by drastic morphological and physiological changes during their adaptation to an exclusively marine existence. In addition, several cetacean species exhibit geographical ranges that encompass different marine environments, with genetic breaks being sometimes consistent with environmental breaks. As such, genes that underwent adaptation during the land-sea transition can also be potential candidates for adaptation to different oceanic environments. In this study, we analysed 3 milk protein genes (β-casein, κ-casein, and α-lactalbumin) and 2 immunity related genes (MHC DQβ1 and γ-fibrinogen) for selection based on available phylogenetic datasets of both mammals and cetaceans, and used the results from this analysis to assess adaptation to different environments on a population level in the European common dolphin (Delphinus delphis). We found that evidence for positive selection could be detected in all genes in the phylogenetic analyses, with β-casein showing a further increase in selective pressure in the cetacean lineage. At the population level, both the immune system locus DQβ1 and β-casein genes showed patterns of variation consistent with divergent selection, and in each case the same populations showed differentiation. One of these populations was also differentiated at neutral markers, while the other was not. We discuss possible inference, and the potential for the further development of these ideas using genomic technologies.