Casein digestion by Debaryomyces hansenii isolated from cheese

To understand the possible proteolytic contribution of yeast during cheese ripening, Debaryomyces hansenii 212 was isolated from commercial blue-veined cheese and incubated in a medium containing casein. Growth and casein degradation were recognized at the cheese-ripening temperature. Proteolytic activity was found in the intracellular fraction, and the enzyme, which was attached to the cell wall, primarily acted on beta-casein. The cytosol contained more than 90% of the total proteolytic activity which was responsible for the degradation of both alpha(s)- and beta-casein. These results suggest that the contribution of yeast to cheese ripening would depend on the susceptibility to cell lysis in addition to its proteolytic activity.     

Acid Protease of Bovine Milk

Occurrence of milk acid protease in bovine casein in addition to alkaline protease was found and purification of this enzyme was achieved. The enzyme had a pH optimum at 4.0 and was most stable at pH 3.5. The molecular weight of the enzyme was 36,000 and no inhibition was observed by diisopropyl-fluorophosphate, EDTA etc. This enzyme is considered to be similar to cathepsin D.

Milk acid protease mainly hydrolyzed α_s-casein and similar change was observed in autolysis of casein at pH 5.5. It is suggested that milk acid protease may have some significance in cheese ripening.     

Partial Isolation and Degradation of Caseins by Cell Wall Proteinase(s) of Streptococcus cremoris HP

The cell wall proteinase fraction of Streptococcus cremoris HP has been isolated. This preparation did not exhibit any activity due to either specific peptidases known to be located near the outside surface of and in the membrane or intracellular proteolytic enzymes. By using thin-layer chromatography for the detection of relatively small hydrolysis products which remain soluble at pH 4.6, it was shown that β-casein is preferentially attacked by the cell wall proteinase. This was also the case when whole casein or micelles were used as the substrate. κ-casein hydrolysis is a relatively slow process, and α_s-casein degradation appeared to proceed at an extremely low rate. These results could be confirmed by using ¹⁴CH₃-labeled caseins. A relatively fast and linear initial progress of ¹⁴CH₃-labeled β-casein degradation is not inhibited by α_s-casein and only slightly by κ-casein at concentrations of these components which reflect their stoichiometry in the micelles. Possible implications of β-casein degradation for growth of the organism in milk are discussed.     

Membrane interactions and lipid binding of casein oligomers and early aggregates

Caseins constitute the main protein components in mammalian milk and have critical functions in calcium transport and prevention of protein aggregation. Fibrillation and aggregation of κ-casein, a phenomenon which has only recently been detected, might be associated with malfunctions of milk secretion and amyloidosis phenomena in the mammary glands. This study employs a newly-designed chromatic biomimetic vesicle assay to investigate the occurrence and the parameters affecting membrane interactions of casein aggregates and the contribution of individual casein members to membrane binding. We show that physiological casein colloids exhibit membrane activity, as well as early globular aggregates of κ-casein, a prominent casein isoform. Furthermore, inhibition of κ-casein fibrillation through complexation with α_S-casein and β-casein, respectively, was found to go hand in hand with induction of enhanced membrane binding; these data are important in the context of casein biology since in secreted milk κ-casein is found only in assemblies containing also α_S-casein and β-casein. The chromatic experiments, complemented by transmission electron microscopy analysis and fluorescence quenching assays, also revealed significantly higher affinity early spherical aggregates of k-casein to anionic phosphatidylglycerol-lipids, as compared to zwitterionic phospholipids. Overall, this study suggests that lipid interactions play important roles in maintaining the essential physiological functions of caseins in mammalian milk.     

Caseinolysis in cheese by Enterobacteriaceae strains of dairy origin

AIMS: To study the effect of Enterobacteriaceae strains of dairy origin on caseins under cheese manufacture and ripening conditions. METHODS AND RESULTS: Strains belonging to the genera Enterobacter, Escherichia, Hafnia and Serratia were isolated from fresh raw milk cheeses. Residual caseins in cheeses made from milk individually inoculated with 10 strains of Enterobacteriaceae were determined by capillary electrophoresis. Hierarchical cluster analysis of strains based on data of residual caseins grouped together strains from the same genus, excepting Hafnia strains, which were separated into two groups. Serratia was the most proteolytic genus in our study. Preferences for degradation of casein fractions differed among the four genera studied. CONCLUSIONS: Enterobacteriaceae strains posses proteolytic systems active on all casein fractions under cheese manufacture and ripening conditions. The effects on caseins were similar for strains belonging to the same genus. SIGNIFICANCE AND IMPACT OF THE STUDY: The presence of Enterobacteriaceae in cheeses may affect proteolysis during ripening. Assays of Enterobacteriaceae proteolytic activity on milk agar plates may underestimate their caseinolytic activity in cheese.     

Growth and aroma contribution of <Emphasis Type="Italic">Microbacterium foliorum</Emphasis>, <Emphasis Type="Italic">Proteus vulgaris</Emphasis> and <Emphasis Type="Italic">Psychrobacter</Emphasis> sp. during ripening in a cheese model medium

The growth and aroma contribution of Microbacterium foliorum, Proteus vulgaris and Psychrobacter sp., some common but rarely mentioned cheese bacteria, were investigated in a cheese model deacidified by Debaryomyces hansenii during the ripening process. Our results show that these bacteria had distinct growth and cheese flavour production patterns during the ripening process. P. vulgaris had the greatest capacity to produce not only the widest variety but also the highest quantities of volatile compounds with low olfactive thresholds, e.g. volatile sulphur compounds and branched-chain alcohols. Such compounds produced by P. vulgaris increased after 21 days of ripening and reached a maximum at 41 days. The three bacteria studied exhibited various degrees of caseinolytic, aminopeptidase and deaminase activities. Moreover, P. vulgaris had a greater capacity for hydrolysing casein and higher deaminase activity. Our results show that P. vulgaris, a Gram-negative bacterium naturally present on the surface of ripened cheeses, could produce high concentrations of flavour compounds from amino acid degradation during the ripening process. Its flavouring role in cheese cannot be neglected. Moreover, it could be a useful organism for producing natural flavours as dairy ingredients.     

Purification and characterization of two extracellular proteinases from Arthrobacter nicotianae 9458

Two extracellular serine proteinases with molecular masses of about 53–55 and 70–72 kDa, were purified from Arthrobacter nicotianae 9458 and characterized. The enzymes differed with respect to temperature optimum, 55–60 and 37°C, respectively, tolerance to low values of pH and temperature, heat stability, sensitivity to EDTA and sulfhydryl blocking agents, and hydrophobicity. Both proteinases were optimally active in the pH range of 9.0 and 9.5, had considerable activity at pH 6.0 on α_s1- and β-caseins, and tolerated NaCl over 5%. Specificity on casein fractions was generally similar and β-casein was more susceptible to hydrolysis than α_s1-casein. The proteinases of Arthrobacter spp. may play a significant role in ripening of the smear surface-ripened cheeses.     

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.     

Phosphorylation of casein by cyclic AMP-dependent protein kinase.

The catalytic subunit of rabbit muscle cyclic AMP-dependent protein kinase (EC 2.7.1.37; ATP:protein transferase) has been tested on a variety of caseins. The B variant of β-casein was phosphorylated at a much greater rate than other β-caseins, α_s1-caseins, and κ-caseins. Whole casein homozygous for β-casein B was phosphorylated at 2.5 times the rate of commercial whole casein. Gel electrophoresis experiments indicate that β-casein is the predominant component phosphorylated in commerical casein. It is therefore suggested that phosphorylation of whole casein depends on its content of the specific genetic variant, β-casein B.     

Direct Effect of Sodium Nitrite on Extracted Histones

Irpex lacteus milk-clotting enzyme hydrolyzed the Phe(105)-Met(106) bond of κ-casein, causing the precipitation of para-κ-casein along with other casein fractions in the presence of calcium ions, with a mechanism similar to other milk-clotting enzymes. Furhtermore, Irpex enzyme hydrolyzed at the positions Leu(79)-Ser(80) and Tyr(30)-Val(31) of para-κ-casein.

Degradation patterns of β-casein by Irpex and Mucor miehei enzymes were almost the same by polyacrylamide gel electrophoresis, but Endothia parasitica enzyme showed a different degradation pattern. Under the conditions employed, β-casein appeared to be scarcely hydrolyzed by chymosin.

Comparing the specificity of Irpex enzyme on β-casein with that of chymosin, the common cleaving points were Leu(165)-Ser(166), Ala(189)-Phe(190), and Tyr(192)-Glu(193). The difference in the specificity between the enzymes was exhibited in the cleavage at the Leu(139)-Leu(140) bond by chymosin and of the Ser(142)-Trp(143) bond by Irpex enzyme. Although the cleaving points of β-casein by both enzymes resembled each other, each enzyme exhibited different degradation patterns of β-casein because of thier different order of cleavage.     

Biosynthesis of flavors by Penicillium roqueforti

The development of the unique flavor of blue type cheese depends on the concerted action of numerous enzymes of Penicillium roqueforti involved in protein and lipid metabolism. Protease(s) by degrading casein modify the texture and background flavor of the ripening cheese. Lipase by hydrolyzing milk triglycerides provides flavorful fatty acids and precursors of methyl ketones. The enzyme complex involved in the partial oxidation of free fatty acids and the properties of β-ketoacyl decarboxylase which generates the major flavor components of blue cheese are discussed. Fermentation of P. roqueforti for the rapid production of methyl ketones is briefly reviewed.     

Amino acids content and electrophoretic profile of camel milk casein from different camel breeds in Saudi Arabia

This study aimed to evaluate amino acids content and the electrophoretic profile of camel milk casein from different camel breeds. Milk from three different camel breeds (Majaheim, Wadah and Safrah) as well as cow milk were used in this study.Results showed that ash and moisture contents were significantly higher in camel milk casein of all breeds compared to that of cow milk. On the other hand, casein protein of cow milk was significantly higher compared to that of all camel milk breeds. Molecular weights of casein patterns of camel milk breeds were higher compared to that of cow milk.Essential (Phe, Lys and His) and non-essential amino acids content was significantly higher in cow milk casein compared to the casein of all camel milk breeds. However, there was no significant difference for the other essential amino acids between cow casein and the casein of Safrah breed and their quantities in cow and Safrah casein were significantly higher compared to the other two breeds. Non-essential amino acids except Arg and the essential amino acids (Met, Ile, Lue and Phe) were also significantly higher in cow milk α-casein compared to α-casein from all camel breeds. Moreover, essential amino acids (Val, Phe and His) and the non-essential amino acids (Gly and Ser) content was significantly higher in cow milk β-casein compared to the β-casein of all camel milk breeds and the opposite was true for Lys, Thr, Met and Ile. However, Met, Ile, Phe and His were significantly higher for β-casein of Majaheim compared to the other two milk breeds. The non-essential amino acids (Gly, Tyr, Ala and Asp) and the essential amino acids (Thr, Val and Ile) were significantly higher in cow milk κ-casein compared to that for all camel milk breeds. There was no significant difference among all camel milk breeds in their κ-casein content of most essential amino acids.Relative migration of casein bands of camel milk casein was not identical. The relative migration of α_s-, β- and κ-casein of camel casein was slower than those of cow casein. The molecular weights of α_s-, β- and κ-casein of camel caseins were 27.6, 23.8 and 22.4 KDa, respectively. More studies are needed to elucidate the structure of camel milk.     

Enzymatic Cross-Linking of Casein Facilitates Gel Structure Weakening Induced by Overacidification

Casein (α_S1, α_S2, β, κ) is the major protein fraction in milk and, together with heat denatured whey proteins, responsible for gel network formation induced by acidification. Rheological measurements during gelation typically reveal a maximum storage modulus (G') at a pH close to the isoelectric point (pI) of casein (~4.6). With further decreasing pH gel stiffness decreases because of increased electrostatic repulsion, which is referred to as overacidification. In this study we investigated the effect of casein cross-linking with microbial transglutaminase on gel structure weakening induced by acidification to pH below the pI. Although enzymatic cross-linking increased the maximum stiffness (G' _MAX ) of casein gels the reduction of G' during overacidification, expressed as ratio of the plateau value (G' _FINAL ) to G' _MAX , was more pronounced. Almost no soluble protein was detected in the serum of gels from cross-linked casein, whereas considerable amounts of α_S- and κ-casein were released from reference gels below the pI. This suggests that covalent cross-linking of casein retains charged molecules within the gel network and therefore causes a higher reduction of protein-protein interactions because of higher electrostatic repulsion. Furthermore, higher amounts of uncross-linked β-casein, which was the only casein type not found in the serum, resulted in higher G' _FINAL to G' _MAX ratios, underlining the important contribution of β-casein to acid gel formation and prevention of gel structure weakening.     

Interaction of Calcium Ion with Bovine Caseins

In order to clarify the interaction of calcium ion with casein, the volume change associated with the interaction was measured by dilatometric procedures. When CaCl₂ was added to the casein solutions at neutral pH, a volume increase occurred and reached a constant saturated value of about 700 ml per 10⁶ g protein with increasing CaCl₂ concentrations for whole-, α_s- and β-casein solutions, but there was no volume change for κ-casein solution. On the other hand, the binding of calcium ion to the casein fractions was determined by a gel filtration procedure at pH 6.0 to 9.0. The number of Ca²⁺ ions bound to the caseins increased with the CaCl₂ concentration and pH value, and the relative order of binding capacities for the caseins was: α_s-casein > whole-casein > β-casein > κ-casein.

It was found that the volume changes obtained by the dilatometry were smaller than the calculated volume increases based on the assumption that these are caused by the binding of Ca²⁺ ion to the caseins. Therefore it is necessary to introduce another factor which reduces the volume increase due to the Ca²⁺ ion binding in order to reasonably explain the measured volume changes. At present it is presumed that there occurs the unfolding of peptide chain of casein molecule on Ca²⁺ ion binding, which has been known to decrease the volume of the protein solution.     

The Primary Structure of Water Buffalo αs1- and β-Casein: Identification of Phosphorylation Sites and Characterization of a Novel β-Casein Variant

The primary structure of water buffalo α_s1-casein and of β-casein A and B variants has been determined using a combination of mass spectrometry and Edman degradation procedures. The phosphorylated residues were localized on the tryptic phosphopeptides after performing a β-elimination/thiol derivatization. Water buffalo α_s1-casein, resolved in three discrete bands by isoelectric focusing, was found to consist of a single protein containing eight, seven, or six phosphate groups. Compared to bovine α_s1-casein C variant, the water buffalo α_s1-casein presented ten amino acid substitutions, seven of which involved charged amino acid residues. With respect to bovine βA₂-casein variant, the two water buffalo β-casein variants A and B presented four and five amino acid substitutions, respectively. In addition to the phosphoserines, a phosphothreonine residue was identified in variant A. From the phylogenetic point of view, both water buffalo β-casein variants seem to be homologous to bovine βA₂-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.     

Photolysis of Aryl Glycosides with Ultraviolet Irradiation

Bovine casein components (α_sl-, β-, and κ-caseins) were chemically phosphorylated and the properties of the modified components were compared with those of the native to clarify the function of the intrinsic phosphate groups of casein components in casein micelle formation. The calcium binding ability of casein components increased after chemical phosphorylation. The concentrations of calcium chloride required to precipitate modified α_sl- and β-caseins were higher than those for native components. However, phosphorylation of α_sl- and β-caseins did not affect their properties of forming micelles through interaction with κ-casein. The stabilizing ability of κ-casein for α_sl- and β caseins was impaired by its phosphorylation, but the stability was recovered by treating phosphorylated κ-casein with phosphoprotein phosphatase. The results show that the phosphate content of κ-casein must be low to form a stable casein micelle. The results also explain why the specific phosphorylation of casein components in the mammary gland is required.     

Reconstitution of Human Casein Micelle and Its Properties

Human casein micelles were reconstituted from isolated κ- and β-caseins and calcium ions. Micelle formation was recognized in the presence of calcium chloride even at the low concentration of 5mM. At pH levels ranging from 5.5 to 8.0, the re-formed micelles were quite stable so that precipitation of β-casein was not observed. The large micelles were constituted by a higher ratio of β-casein to κ-casein (16:1 by weight) than the small micelles (3: 1). The κ-casein in the small micelles contained carbohydrates to about 43% (w/w) in the molecule, whereas that in the large micelles was only about 25%. When the casein micelles were re-formed from κ-easein and fractionated β-casein components, the extent of phosphorylation of the β-casein component was found to influence the micelle formation; i.e., the β-casein component with no phosphate (the 0-P form) was disadvantageous to form micelles, but the component with 5 phosphates (the 5-P form) formed micelles most easily.     

Interaction between Casein and Carboxymethyl Cellulose in the Acidic Condition

The stabilizing action of carboxymethyl cellulose (CMC-1 and CMC-2) on caseins was studied in the acidic pH region. CMC-1 stabilized 1% whole, α-, α_S- and β-casein at pH 4.6 and 5.0, and at 5°C. But CMC-2 could not completely stabilize these caseins at pH 5.0. Interaction between κ-casein and CMC-1 commenced when pH was adjusted to 6.3, but CMC-2 interacted with κ-casein below pH 5.6. An α_S- and κ-casein mixture (4 : 1) with CMC-2 was destabilized by the addition of 0.02 m NaCl or NaH₂PO₄ at pH 5.0. The α_S/κ ratio of the precipitated casein was about 10. But the same system with CMC-1 was not destabilized by the salts.