Studies on the Interaction between αs1- and β-Caseins

The interaction of α_s1-casein with β-, dephosphorylated β-,γ- and R-caseins was studied. It was proved by the sedimentation velocity experiments that α_s1-casein formed a complex with each of these components at 25±C in the presence of 3 mm CaCl₂.

In the presence of 10 mm CaCl₂, β- and dephosphorylated β-casein prevented the precipitation of α_s1-casein and gave micelle-like turbid solutions. However, γ- and R-caseins, fragments of β-casein, did not stabilize α_s1-casein. It was concluded from these results that α-casein interacted with α_s1-casein through its hydropholic region corresponding to R-casein and that hydrophilic region of β-casein was responsible for the stabilization of α_s1-casein.     

Mixed Function Oxidase Inhibitors Protect Plants from Ozone Injury

κ-Casein and α_s1-κ-casein complex with a weight ratio of unity were dissolved in 50mm cacodylate-HCl-70 mm KC1 buffer containing 0.02% of sodium azide (pH 7.1), and their size and shape in the absence and/or presence of calcium ions were observed with the electron microscope. In the absence of calcium ions, both κ-casein and α_s1-κ-casein complex were spherical particles. However, the mean length of α_s1-κ-casein complex (12 nm) was smaller than that of κ-casein (17 nm), which suggested that complex formation led to dissociation of the κ-casein polymer. The addition of calcium ions to the complex led to the formation of bent chains, though micelle-like aggregates were not observed even at 20 nm calcium. Comparison of the frequency distributions of α_s1-κ-casein complex at 0, 5, 10, 15 and 20 mm of calcium with the calculated probability distributions suggested that most α_s1-κ-casein complexes had two binding sites above 10 mm of calcium, which seemed to be essential for the stability of casein micelle.     

Isolation of Dehydro-ipomeamarone,a New Sesqui-terpenoid from the Black-rot Fungus Infected Sweet Potato Root Tissue and Its Relation to the Biosynthesis of Ipomeamarone

α_s1-Casein was dissolved in 50 mm cacodylate-HCl-70 mm KC1 buffer containing 0.02% of sodium azide (pH 7.1), and the size and shape of α_s1-caseins in the absence and presence of calcium ions were observed with the electron microscope. In the absence of calcium ions, most α_s1-caseins existed as spherical particles of which the smallest diameter was 5~6 nm. The particles were polymerized into bent chains by adding 3 mm calcium. It seemed that the smallest particles were the polymerizing units. The mean length of α_s1-casein in the absence of calcium was 8.7 nm, and it increased as the calcium concentration increased. From these results, it was speculated that α_s1-casein in the absence of calcium had one binding site and the calcium-induced conformational changes produced a second binding site. The probability distributions were calculated with the above speculation, and compared with the frequency distributions obtained from electron micrographs. It was suggested from the comparisons that the second binding site produced in α_s1-casein might be responsible for the calcium-induced aggregation.     

Amino Acid Sequence of Tremerogen A–10, a Peptidal Hormone,Inducing Conjugation Tube Formation in Tremella mesenterica Fr.

κ-Casein components having various carbohydrate contents were prepared by diethylaminoethyl-cellulose chromatography and the interactions of each κ-casein component both with α_s1-casein and with β-casein were examined by Sepharose 4B gel chromatography, ultra-centrifugal experiments and viscosity measurements. Each κ-casein component could form complex with α_s1- and β-casein in the absence and presence of CaCl₂. Molecular weight of complexes of unfractionated κ-casein both with α_s1-casein and with κ-casein were about 70 × 10⁴ at 37°C in the absence of CaCl₂, while those of complexes of each κ-casein component with α_s1 and β-casein were about 50 × 10⁴. Stokes radii of complexes increased with increasing calcium ion. While sedimentation coefficient at 37°C of complex with β-casein had almost the same value, those of complexes with α_s1-casein decreased with increase of carbohydrate content of κ-casein components. Intrinsic viscosity of complex of κ-casein component having much carbohydrate was almost the same among tested temperatures. It is suggested that heterogeneity of κ-casein is necessary to form large complex and that the carbohydrate moiety of κ-casein contributes the stability of casein complex.     

Human αS1-casein induces IL-8 secretion by binding to the ecto-domain of the TLR4/MD2 receptor complex

Background

The milk protein α_S1-casein was recently reported to induce secretion of proinflammatory cytokines via Toll-like receptor 4 (TLR4). In this study, α_S1-casein was identified as binder of theTLR4 ecto domain.

Molecular weight distribution of interacting proteins calculated by multiple regression analysis from sedimentation equilibrium data: an interpretation of alpha s1-kappa-casein interaction.

Multiple regression analysis in four series with exponentially spaced molecular weight scales shifted by a factor of $\text{2}{}^{\mathrm{<mtext>1</mtext><mtext>4</mtext>}}$ between series was applied to sedimentation equilibrium data for determination of the molecular weight distribution of synthesized model systems consisting of up to three components which represented heterogeneous associating systems. Negative weight fractions of the components which were frequently encountered during multiple regression analysis were forced to zero by successively eliminating from the regression matrix the corresponding molecular weights in order of the magnitude of negative t values. The simplex optimization technique in conjunction with a prohibit-trespassing routine was used to maximize F values obtained from multiple regression analysis in search of the best fit values of component molecular weights. The quantitative information relating molecular weights and relative concentrations obtained by simplex optimization supplemented the regression matrix for calculation of the molecular weight distribution to improve the resolution of the molecular weight distribution patterns. This multiple regression method when carried out in conjunction with the simplex optimization provided a better fit to the data than the linear programming method of Scholte. When applied to mixtures of three standard proteins, the simplex optimization routine yielded values of molecular weights and relative concentrations of the component proteins which were in good agreement with the known values of the original mixtures. The molecular weight distribution calculated from sedimentation equilibrium data of α_s1-κ-casein mixtures using a uv scanner indicated that κ-casein readily dissociated to an oligomer, probably up to trimer, and interacted with the monomer or dimer of α_s1-casein forming a complex of approximately 400,000 molecular weight. This dissociation of κ-casein was promoted in the presence of ovalbumin, a nonmilk protein.     

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.     

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.     

The use of light-scattering and turbidity measurements to study the kinetics of extensively aggregating proteins: αs-Casein

The Ca²⁺-induced association of α_s-casein has been studied using the methods of stopped-flow light-scattering and stopped-flow turbidity. The methods used are described, and the analysis of the results to give plots of M _w against time in the time-scale 0–15 sec is demonstrated. The validity of the method is discussed, and it is shown to be applicable to the association kinetics of aggregating proteins whose molecular-weight averages lie between 10⁷ and 10⁹. The method was used to study the association of bovine α_s-casein in the presence of Ca²⁺, and results obtained are briefly discussed in terms of possible association mechanisms, and a mechanism for the overall reaction of α_s-casein with Ca²⁺, and the subsequent precipitation of the caseinate is proposed.     

Crystallization and amino acid composition of cathepsin B from rat liver lysosomes

Cathepsin B (EC 3.4.22.1) from rat liver was crystallized and its amino acid composition was determined. The purified enzyme formed spindle-shaped crystals and its homogeneity was proved by ultracentrifugical analysis. Its S_{20, W} value was 2.5 S and its molecular weight was calculated to be 24,000 from the result of sedimentation equilibrium analysis. Amino acid analysis showed that it contained glucosamine and galactosamine. The activity of the protease was maximal at pH 6.0 with α-N-benzoyl-DL-arginine p-nitroanilide as substrate. The apparent Kms for α-N-benzoyl-DL-arginine p-nitroanilide and α-N-benzoyl-DL-arginine-2-naphthylamide were 1.4 × 10^?2 M and 2.0 × 10^?3 M, respectively     

Studies on κ-Casein of Bovine Milk

κ-Caseins were prepared by the calciurn-ethanol method, the Sephadex method and the urea-sulfuric acid method. Some important properties of κ-caseins were investigated using isoelectric focusing, starch gel electrophoresis, ultracentrifugation, chemical analysis, stabilization test of α_s-casein, and rennin treatment. Isoelectric focusing established that κ-casein had its isoelectric point near pH 6.0 in 6 m urea, usually accompanied by a second peak around pH 5.6. Ultracentrifugation, however, showed a single peak having a s_20,w value of 2.6 ~ 3.8 in the presence of 6 m urea and of 14.4 in the absence of such dispersing reagents. Normal contents of hexose, sialic acid, phosphorus, and nitrogen were about 1.5, 0.8, 0.2, and 14%, respectively. Relative patterns of amino acid composition were similar in all of the κ-caseins. In addition, amino acid composition in intact κ-casein and in the further purified κ-casein which formed the second peak in DEAE cellulose chromatography were almost identical, indicating that the κ-casein of the first peak is not an impurity but is one of the components which formed the original κ-casein complexes. The ability of κ-caseins to stabilize α_s-casein in the presence of calcium increased when purified by DEAE cellulose chromatography.     

Studies on Molecular Properties of αs1-κ-Casein Complex by the Hydrodynamical Methods

Some molecular properties of α_s1-κ-casein complex, α_s1- and κ-casein polymers were examined by gel filtration, ultracentrifugation, and viscometry at pH 7.1. The Stoke’s radii of α_s1-κ-casein complex, α_s1- and κ-casein polymers were 99, 44 and 108 Å, respectively. The molecular weight of the above proteins were approximately 45 × 10⁴, 10 × 10⁴ and 80 × 10⁴, respectively. The stokes radius of α_s1-κ casein complex reduced compared with that of κ-casein polymer and the molecular weight of the complex was about half that of κ-casein polymer. These results suggest that κ-casein polymer dissociates into 4 smaller particles when α_s1-κ-casein complex is formed. The frictional coefficient and Scheraga-Mandelkern constants for each protein suggest that the molecular shape of α_s1-casein polymer is globular and that of α_s1-κ-casein complex and κ-casein polymer is rod-like.     

Purification and properties of a β-N-acetylaminoglucohydrolase from malted barley

β-N-Acetylaminoglucohydrolase (β-2-acetylamino-2-deoxy-D-glucoside acetylaminodeoxyglucohydrolase, EC 3.2.1.30) was extracted from malted barley and purified. The partially purified preparation was free from α-and β-glucosidase, α- and β-galactosidase, α-mannosidase and β-mannosidase. This preparation was free from α-mannosidase only after affinity chromatography with p-amino-N-acetyl-β-D-glucosaminidine coupled to Sepharose. The enzyme was active between pH 3 and 6.5 and had a pH optimum at pH 5. A MW of 92000 was obtained by sodium dodecyl sulfate-acrylamide gel electrophoresis and a sedimentation coefficient of 4.65 was obtained from sedimentation velocity experiments. β-N-Acetylaminoglucohydrolase had a K_m of 2.5 × 10^?4 M using the p-nitrophenyl N-acetyl β-D-glucosaminidine as the substrate.     

Structure of Bovine αs-Casein

The secondary structure of bovine α_s-casein and chemically modified α_s-casein in various solvents was investigated by infrared absorption spectrum and optical rotatory dispersion measurements. Amino groups of α_s-casein were either succinylated or acetylated, and carboxyl groups were either methylated or ethylated. Acetylated- and ethylated-α_s-caseins are insoluble in water. Water-soluble samples have unordered structure in water. In organic solvents, such as 2-chloroethanol and ethylene glycol, they have about 50% α-helical fraction. On the other hand, it was found that methylated-α_s-casein had two infrared absorption peaks centered at 1625 and 1643 cm^?1 in D₂O-CH₃OD mixed solvent. This fact may be connected with the presence of β-structure. In the case of solid film of this sample, cast from solution containing CH₃OH, the presence of β-structure was indicated, too. The authors attempted to explain the formation of β-structure in methylated-α_s-casein in terms of the electrostatic interactions due to the differences in the net charge between methylated and unmodified α_s-caseins.     

Thermodynamics of the Interaction between αs1- and κ-Caseins

Pyrenebutyrate-conjugated α_s1-casein was prepared and the complex formation between α_s1- and κ-casein polymers was investigated by fluorescence polarization. The complex formation was also investigated by a microcalorimetric technique. The positive enthalpy and entropy changes and endothermic nature suggested the hydrophobic interaction between α_s1- and κ-casein polymers.

The degree of polarization of κ-casein polymer decreased with the addition of 1-anilino-8-naphthalenesulfonate (ANS), while that of α_s1-casein polymer and α_s1-κ-casein complex was invariant. Moreover the reaction of κ-casein polymer and ANS was exothermic. These facts suggested that the intermolecular hydrophobic regions in κ-casein polymer were disrupted by the adsorption of ANS. The rotational relaxation time of pyrenebutyrate conjugated complex between cyanoethyl-κ-casein and α_s1-casein polymer was smaller than that of cyanoethyl-κ-casein alone. From these results, it was postulated that the dissociation of κ-casein polymer by the complex formation with α_s1-casein polymer might be caused by the disruption of the intermolecular hydrophobic bonds in κ-casein polymer.     

Purification and Characterization of UDP-N-Acetylgalactosamine: κ-Casein Polypeptide N-Acetylgalactosaminyltransferase from Mammary Gland of Lactating Cow

UDP-N-acetyl-d-galactosamine: κ-casein polypeptide N-acetylgalactosaminyltransferase was purified from a crude Golgi apparatus of lactating bovine mammary gland after solubilization with Triton X-100. Through chromatography on DEAE-Sephadex A-50, apomucin-Sepharose 4B, FPLC mono S, and Sephacryl S-200, and then electrofocusing, the enzyme was purified up to 7500-fold from the homogenate.

The molecular weight of the enzyme was estimated at 200,000 from gel filtration. The pI value of the enzyme was 6.4 on electrofocusing. The purified enzyme transferred GalNAc from UDP-GalNAc, not to the carbohydrate chains but to the polypeptide chains of the substrates, κ-casein and mucin. The enzyme required Mn²⁺, DTT, and Triton X-100 for maximal activity. The Km value for UDP-GalNAc was 16.2μm. Km values for K-subcomponents 1 and 7, and apomucin were 1.15, 5.10, and 0.192mg/ml, and V_max values were 254, 259, and 581 nmol/hr/mg, respectively. Thermal stability and the effects of pH, milk components, lectins, and nucleotides were examined.

α_s1-Casein strongly inhibited GalNAc transfer to κ-casein. The inhibitory effect of α_s1-casein was canceled by the addition of Ca²⁺, which causes casein micelle formation. This means that the glycosylation of κ-casein occurs after casein micelle formation triggered by the accumulation of Ca²⁺ in vivo.     

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.     

Flavonoids in Poncirus Hybrids

α_sl-Casein can be made either soluble or insoluble by adjusting the concentration of coexisting calcium ions. In this study, we tried to make a soluble-insoluble interconvertible enzyme through the formation of a conjugate of an enzyme and α_sl-casein using a heterobifunctional crosslinking reagent, N-succinimidyl 3-(2-pyridyldithio)propionate. The conjugate of phosphoglyceromutase and native α_s1-casein did not exhibit sufficient calcium-dependent precipitation. However, conjugates of enzymes (phosphoglyceromutase, enolase or peroxidase) and α_sl-casein polymerized by transglutaminase precipitated almost completely in the presence of more than 50 mM CaCl₂. Most of the enzyme conjugates precipitated as calcium caseinates could be solubilized reversibly with EDTA, without a significant loss of activity. A mixture of the enzyme ? polymerized α_s1-casein conjugates prepared with phosphoglyceromutase, enolase and pyruvate kinase could catalyze sequential reactions which convert d-3-phosphoglycerate into pyruvate with the same efficiency as a mixture of free enzymes. These results indicate that conjugates of enzymes and polymerized α_s1-casein can be useful as soluble-insoluble interconvertible enzymes.     

Kinetics of aggregation of αs1 -casein/ca2+ mixtures: charge and temperature effects

Time-dependent light-scattering studies have been made on mixtures of α_s1 -casein and Ca²⁺ at fixed temperature over a range of [Ca²⁺] and [α_s1 -casein], and also as functions of temperature- Measurements were also made of the extent of precipitate formation in the casein/Ca²⁺ mixtures, using centrifugation. The results are analysed in terms of a monomeroctamer equilibrium between calcium caseinate particles followed by a Smoluchowski aggregation in which only the octamers can participate. The equilibrium constant is dependent upon the charge on the protein/Ca²⁺ particles, and hence can be related to the extent of binding of Ca²⁺ to the α_s1 -casein. The Smoluchowski constant is likewise shown to be charge-dependent. The variation of the reaction rate with temperature can be ascribed solely to the changing charge of the α_s1 -casein/Ca²⁺ complex caused by changed binding of Ca²⁺ at different temperatures.     

Purification and characterization of a propanol-tolerant neutral protease from Bacillus sp. ZG20

Abstract

A propanol-tolerant neutral protease was purified and characterized from Bacillus sp. ZG20 in this study. This protease was purified to homogeneity with a specific activity of 26,655?U/mg. The recovery rate and purification fold of the protease were 13.7% and 31.5, respectively. The SDS-PAGE results showed that the molecular weight of the protease was about 29?kDa. The optimal temperature and pH of the protease were 45?°C and 7.0, respectively. The protease exhibited a good thermal- and pH stability, and was tolerant to 50% propanol. Mg²⁺, Zn²⁺, K⁺, Na⁺ and Tween-80 could improve its activity. The calculated K_m and V_max values of the protease towards α-casein were 12.74?mg/mL and 28.57?µg/(min mL), respectively. This study lays a good foundation for the future use of the neutral protease from Bacillus sp. ZG20.