Appraisal of casein's inhibitory effects on aggregation accompanying carbonic anhydrase refolding and heat-induced ovalbumin fibrillogenesis

It is well accepted that whole casein and its purified major components, due to their chaperone-like activity, are able to suppress the thermal and chemical aggregation of several substrate proteins. In this study, we set out to determine whether whole and β-casein are able to prevent (or attenuate) aggregation accompanying refolding of chemically denatured carbonic anhydrase or to recover lost biological activity after its denaturation. Additionally, we showed attenuated heat-induced fibrillar aggregation of egg white ovalbumin in the presence of these commonly occurring unfolded proteins, as molecular chaperones. Also, the extent, rate and order of aggregation, in the presence and absence of aggregation suppressors, were compared. Although β-casein did not prevent aggregation as strong as whole casein, both chaperones were efficient not only in suppressing the aggregation extent of denatured carbonic anhydrase, but also in delaying elongation process of amyloid fibril formation with no effect on nucleation phase.     

High pressure-induced changes in bovine milk proteins: a review

High pressure (HP)-induced changes in the proteins of bovine milk have become an area of considerable research interest in recent years; as a result, there is now a detailed understanding of the effects of HP on casein micelles and whey proteins. HP treatment at pressures >400 or >100 MPa denatures the two most abundant whey proteins, alpha-lactalbumin (alpha-la) and beta-lactoglobulin (beta-lg), respectively. The majority of denatured beta-lg in HP-treated milk associates with the casein micelles, although some denatured beta-lg remains in the serum phase or is attached to the milk fat globule membrane; HP-denatured alpha-la is also associated with the milk fat globules. Casein micelles are disrupted on treatment at pressures >200 MPa; the rate and extent of micellar disruption increases with pressure and is probably due to the increased solubility of calcium phosphate with increasing pressure. On prolonged treatment at 250-300 MPa, reassociation of micellar fragments occurs through hydrophobic bonding; this process does not occur at a pressure >300 MPa, leading to considerably smaller micelles in such milk. As a result of HP-induced changes, the size, number, hydration, composition and light-scattering properties of casein micelles in HP-treated milk differ considerably from those in untreated milk.     

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.     

Influence of Molecular Weight of Chitosan on Interaction with Casein

The process of complex formation of casein from skimmed milk and purified casein with chitosan of different molecular weights was studied. It was shown that at pH 6.3 casein micelles and parts of whey proteins coagulated with positively charged chitosan molecules with molecular weights of 45.3, 25.4, 7.7 and 1.5 kDa. As a result of ionic interaction of chitosan with skimmed milk proteins the yield of target product reached 90–92%. It consisted of all forms of casein: α-casein, β-casein, κ-casein and small amount of whey proteins.     

The chaperone action of bovine milk αS1- and αS2-caseins and their associated form αS-casein

α_S-Casein, the major milk protein, comprises α_S1- and α_S2-casein and acts as a molecular chaperone, stabilizing an array of stressed target proteins against precipitation. Here, we report that α_S-casein acts in a similar manner to the unrelated small heat-shock proteins (sHsps) and clusterin in that it does not preserve the activity of stressed target enzymes. However, in contrast to sHsps and clusterin, α-casein does not bind target proteins in a state that facilitates refolding by Hsp70. α_S-Casein was also separated into α- and α-casein, and the chaperone abilities of each of these proteins were assessed with amorphously aggregating and fibril-forming target proteins. Under reduction stress, all α-casein species exhibited similar chaperone ability, whereas under heat stress, α-casein was a poorer chaperone. Conversely, α_S2-casein was less effective at preventing fibril formation by modified κ-casein, whereas α- and α_S1-casein were comparably potent inhibitors. In the presence of added salt and heat stress, α_S1-, α- and α_S-casein were all significantly less effective. We conclude that α_S1- and α-casein stabilise each other to facilitate optimal chaperone activity of α_S-casein. This work highlights the interdependency of casein proteins for their structural stability.     

Isolation of Tremerogen a-13, a Peptidal Sex Hormone of Tremella mesenterica

Bovine casein micelles were fractionated on controlled pore granule (CPG-10/3000) chromatography by size and the chemical properties of the fractionated micelles were compared. The results indicated the presence of two types of micelles distinguishable as large and small micelles. In skim milk, 72.7% of casein was calculated to be in the form of small micelles, 13.6% in the form of large micelles and 13.8% in non-micellar casein form.

The α_s1-casein content decreased, but β- and κ-casein content increased as the micelle size became smaller. κ-Casein in large micelles had a much higher sialic acid content than in small micelles. It was found that this difference in sialic acid content was due to the presence of non-glycosylated κ-casein in small micelles. In large micelles, non-glycosylated κ-casein was almost undetectable.

The addition of wheat germ lectin to micelles resulted in the formation of aggregates through intermicellar bridges between the carbohydrate chains of κ-casein located on the surface of the micelles. Both large and small micelles formed aggregates after the addition of wheat germ lectin. Large micelles were more sensitive to wheat germ lectin than small ones.     

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.     

Comparison of the Chaperoning Action of Glycerol and β-Casein on Aggregation of Proteins in the Presence of Crowding Agent

β-Casein is one of the major components of the milk micelles of most mammals and has been shown to exhibit in vitro chaperone-like activity. Glycerol is a chemical chaperone belonging to the polyol family, which increases protein stability and inhibits protein aggregation. These prompted us to compare the chaperone-like activity of β-casein and glycerol. In this study, the effect of β-casein and glycerol on folding of the target proteins (ovotransferrin, insulin and α-lactalbumin) in the presence of dextran, as a macromolecular crowding agent, is examined using visible absorption spectroscopy, intrinsic fluorescence spectroscopy, 1-anilino-8-naphthalene sulfonic acid fluorescence binding and near CD spectroscopy. In the presence of dextran, the rate and extent of aggregation of target proteins was enhanced and β-casein was less effective in preventing the aggregation and precipitation of target proteins. These data support the hypothesis that β-casein interacts more effectively with slowly aggregating rather than rapidly aggregating target proteins. It is proposed that dextran-induced changes to protein conformation and the rate of intermolecular association are in a kinetic competition with the chaperoning action of β-casein; however our results demonstrated the higher activity of glycerol, as a chemical chaperone, than β-casein on the folding of target proteins, especially in the presence of dextran. This is likely due to the stabilizing effect of glycerol on protein structure and environment. The implications for the in vivo functions of β-casein and glycerol, based on their exhibiting such in vitro chaperone-like activities, are discussed.     

A lactational study of the composition and integrity of casein micelles from the milk of the tammar wallaby (Macropus eugenii)

The amount of casein found in the milk of the tammar wallaby increases as lactation progresses. The increase is due to increasing amounts of β-casein; the α-casein remains largely constant. The α-casein is the more highly phosphorylated; the most abundant form is the 10-P, throughout lactation. The level of phosphorylation of β-casein shifts to lower average values in late lactation, possibly indicating the enzymatic reaction is overloaded by the increasing amounts of β-casein. Unlike bovine casein micelles, the wallaby micelles are not completely disrupted at pH 7.0 by sequestration of their calcium content with ethylene diamine tetraacetic acid (EDTA). Complete disruption only follows the addition of sodium dodecyl sulphate, indicating considerably greater importance for hydrophobic bonds in maintaining their integrity. This micellar behaviour indicates that, despite the evolutionary divergence of marsupials millennia ago, the caseins of wallaby milk assemble into micelles in much the same fashion as in bovine milk.     

Chaperone-like activity of beta-casein

The caseins are major components of milk for most mammals and are secreted as large colloidal aggregates termed micelles. They have less ordered secondary and tertiary structures in comparison with typical globular proteins. In this work, beta-casein, a member of the casein family, has been demonstrated to exhibit chaperone-like activity, being able to suppress the thermal and chemical aggregation of such substrate proteins as insulin, lysozyme, alcohol dehydrogenase, and catalase by forming stable complexes with the denaturing substrate proteins. Meanwhile, beta-casein was found to not only prevent aggregation of the substrate proteins, but also solubilize the protein aggregates already formed. Data also show that beta-casein exhibits a higher chaperone-like activity than alpha-casein, likely due to the difference in the number of proline residues present and/or in the extent of exposed hydrophobic surfaces. The implications for their in vivo functions of the caseins, based on their exhibiting such in vitro chaperone-like activities, are discussed.     

Protein refolding by reversed micelles utilizing solid-liquid extraction technique

This article reports that a reversed micellar solution is useful for refolding proteins directly from a solid source. The solubilization of denatured RNase A, which had been prepared by reprecipitation from the denaturant protein solution, into reversed micelles formulated with sodium di-2-ethylhexyl sulfosuccinate (AOT) has been investigated by a solid-liquid extraction system. This method is an alternative to the ordinary protein extraction in reversed micelles based on the liquid-liquid extraction. The solid-liquid extraction method was found to facilitate the solubilization of denatured proteins more efficiently in the reversed micellar media than the ordinary phase transfer method of liquid extraction. The refolding of denatured RNase A entrapped in reversed micelles was attained by adding a redox reagent (reduced and oxidized glutathion). Enzymatic activity of RNase A was gradually recovered with time in the reversed micelles. The denatured RNase A was completely refolded within 30 h. In addition, the efficiency of protein refolding was enhanced when reversed micelles were applied to denatured RNase A containing a higher protein concentration that, in the case of aqueous media, would lead to protein aggregation. The solid-liquid extraction technique using reversed micelles affords better scale-up advantages in the direct refolding process of insoluble protein aggregates.     

Rennet-Induced Aggregation and Curd Formation from Skimmed Milk Powders Prepared under Different Sterilizing Conditions

Heat treatment during the production of skimmed milk powder causes denaturation of proteins, thereby affecting the physicochemical properties of the skimmed milk powder. To understand the effects of heat treatment on the sensitivity of the casein micelles in skimmed milk powders, low heating type (L), normal heating type (N), high heating type (H), and super-high heating type (SH), to reaction with rennet, rennet-induced curd formation was investigated. A well-developed network structure with wide spaces was observed only in the curd derived from the solution of type L skimmed milk powder. SDS–PAGE suggested that there was no difference in the amount of glycomacropeptide generated from κ-casein in the four types of skimmed milk powder, but casein micelles in the solution of type L skimmed milk powder formed aggregates most effectively. These results are discussed with respect to the thermal denaturation of proteins in skimmed milk powder.     

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.     

α-casein micelles-membranes interaction: Flower-like lipid protein coaggregates formation

BackgroundEnvironmental conditions regulate the association/aggregation states of proteins and their action in cellular compartments. Analysing protein behaviour in presence of lipid membranes is fundamental for the comprehension of many functional and dysfunctional processes. Here, we present an experimental study on the interaction between model membranes and α-casein. α-casein is the major component of milk proteins and it is recognised to play a key role in performing biological functions. The conformational properties of this protein and its capability to form supramolecular structures, like micelles or irreversible aggregates, are key effectors in functional and pathological effects.MethodsBy means of quantitative fluorescence imaging and complementary spectroscopic methods, we were able to characterise α-casein association state and the course of events induced by pH changes, which regulate the interaction of this molecule with membranes.ResultsThe study of these complex dynamic events revealed that the initial conformation of the protein critically regulates the fate of α-casein, size and structure of the newly formed aggregates and their effect on membrane structures. Disassembly of micelles due to modification in electrostatic interactions results in increased membrane structure rigidity which accompanies the formation of protein lipid flower-like co-aggregates with protein molecules localised in the external part.General significanceThese results may contribute to the comprehension of how the initial state of a protein establishes the course of events that occur upon changes in the molecular environment. These events which may occur in cells may be essential to functional, pathological or therapeutical properties specifically associated to casein proteins.     

Studies on the Proteolytic Action of Dairy Lactic Acid Bacteria

Streptococcus cremoris was cultivated for 7 days at 30°C in sterilized skim milk or in the sterilized 10% solution of dry skim milk. This skim milk culture was divided into precipitate and supernatant by centrifugation. The absorbancy at 280 mμ of the supernatant prepared from the skim milk culture of S. cremoris was higher than that of the control supernatant.

Casein prepared from the skim milk culture of S. cremoris was less hydrolyzed by rennet than control casein at pH 7.0.

According to the free boundary electrophoretic analysis of the treated casein in m/10 veronal buffer of pH 8.5 containing urea, α-casein seemed to be hydrolyzed by S. cremoris but β-casein did with more difficulty.     

κ-Casein terminates casein micelle build-up by its “soft” secondary structure

In our previous paper (Nagy et?al. in J Biol Chem 285:38811–38817, 2010) by using a multilayered model system, we showed that, from α-casein, aggregates (similar to natural casein micelles) can be built up step by step if Ca-phosphate nanocluster incorporation is ensured between the protein adsorption steps. It remained, however, an open question whether the growth of the aggregates can be terminated, similarly to in nature with casein micelles. Here, we show that, in the presence of Ca-phosphate nanoclusters, upon adsorbing onto earlier α-casein surfaces, the secondary structure of α-casein remains practically unaffected, but κ-casein exhibits considerable changes in its secondary structure as manifested by a shift toward having more β-structures. In the absence of Ca-phosphate, only κ-casein can still adsorb onto the underlying casein surface; this κ-casein also expresses considerable shift toward β-structures. In addition, this κ-casein cover terminates casein aggregation; no further adsorption of either α- or κ-casein can be achieved. These results, while obtained on a model system, may show that the Ca-insensitive κ-casein can, indeed, be the outer layer of the casein micelles, not only because of its “hairy” extrusion into the water phase, but because of its “softer” secondary structure, which can “occlude” the interacting motifs serving casein aggregation. We think that the revealed nature of the molecular interactions, and the growth mechanism found here, might be useful to understand the aggregation process of casein micelles also in?vivo.     

Enrichment of n-Alkane Assimilation-Deficient Mutants of Candida Yeast by Synergistic Effect of Nystatin and Pyrrolnitrin

In order to clarify further the relationship between the heat stability of casein micelles and the formation of soluble casein upon heating concentrated milk, the effect of formaldehyde was examined. The addition of formaldehyde up to 20 mM markedly increased the heat stability of both concentrated skim milk and concentrated whey protein-free (WPF) milk. The stabilizing effect of formaldehyde was greater for concentrated skim milk than for concentrated WPF milk. The addition of formaldehyde depressed the formation of soluble casein upon heating concentrated milk. No soluble casein was formed on the addition of 20 mM formaldehyde. It was confirmed by Sephadex G-200 gel filtration in the presence of 6.6 M urea that cross-links among the casein components were formed in heated concentrated WPF milk containing formaldehyde. These facts suggest that formaldehyde may introduce cross-links among the casein components and prevent the formation of soluble casein accompanying the release of K-casein from micelles, thus stabilizing the casein micelles.     

Gram scale separation of casein proteins from whole casein on a Source 30Q anion-exchange resin column utilizing fast protein liquid chromatography (FPLC)

Casein is used as an additive in binders or paints and as such exhibits unique properties which might be based on the properties of certain subproteins in the complex whole casein mixture. Therefore, the separation of whole casein (CN) from cow milk was performed on a gram scale in order to yield sufficient amounts of the protein subfractions α-, β-, and κ-casein for further testing utilizing fast protein liquid chromatography (FPLC) and preceding enrichment in the case of κ-casein. Construction chemical grade casein, which differs in quality from dairy grade casein, was used for separation because of our interest in the proteins responsible for plastification of cementitious systems such as mortar. The solubilized proteins were separated chromatographically via ion exchange chromatography (IEX) and the subsequently desalted protein fractions were tested for purity by isoelectric focusing (IEF).     

Binding of a denatured heme protein and ATP to erythroid spectrin

Spectrin is a large, worm-like cytoskeletal protein that is abundant in all cell types. The denatured heme enzyme, horseradish peroxidase showed significant decrease in the reactivation yield, after 30 min of refolding, in presence of increasing concentrations of spectrin from that in the absence. This indicated that spectrin could bind denatured HRP and inhibit their refolding. In presence of 1 mM ATP and 10 mM MgCl(2) the spectrin binding of denatured HRP is abolished. This activity of decreasing the reactivation yield was found to be ATP-dependent and the denatured enzyme after 30 min refolding in the presence of spectrin, pretreated with Mg/ATP, showed about 40% increase in the reactivation yield compared to the same in absence of spectrin. Fluorescence spectroscopic studies indicated binding of ATP to native spectrin showing concentration-dependent quenching of tryptophan fluorescence by ATP. The apparent dissociation constant of binding of ATP to spectrin was estimated to be 1.1 mM. A high affinity binding of spectrin with denatured HRP has been characterized (K(d) = 16 nM). Since these properties are similar to those of established molecular chaperone proteins, these data indicate that spectrin might have a chaperone-like function in erythrocytes.