Purification and physicochemical characterization of ovine β‐lactoglobulin and α‐lactalbumin

Ovine whey proteins were fractionated and studied by using different analytical techniques. Anion‐exchange chromatography and reversed‐phase high‐performance liquid chromatography (HPLC) showed the presence of two fractions of β‐lactoglobulin but only one of α‐lactalbumin. Gel permeation and sodium dodecyl sulfate (SDS)‐polyacrylamide gel electrophoresis allowed the calculation of the apparent molecular mass of each component, while HPLC coupled to electrospray ionisation‐mass spectrometry (ESI‐MS) technique, giving the exact molecular masses, demonstrated the presence of two variants A and B of ovine β‐lactoglobulin. Amino acid compositions of the two variants of β‐lactoglobulin differed only in their His and Tyr contents. Circular dichroism spectroscopy profiles showed pH conformation changes of each component. The thermograms of the different whey protein components showed a higher heat resistance of β‐lactoglobulin A compared to β‐lactoglobulin B at pH 2, and indicated high instability of ovine α‐lactalbumin at this pH.     

Suppression of immune responses to β‐lactoglobulin in mice by the oral administration of peptides representing dominant T cell epitopes

BACKGROUND: The significance of oral tolerance in the treatment of adverse immune reactions such as allergic and autoimmune diseases has been noted. In the present study, peptides that could effectively induce oral tolerance to bovine β‐lactoglobulin (BLG), a milk allergen, were investigated in a murine model. RESULTS: The oral administration of peptides corresponding to the T cell epitope regions of BLG, i.e. p42–56, p62–76 and p139–154, apparently down‐regulated T cell proliferation to BLG. The in vitro cytokine production by the lymph node cells from the peptide‐fed mice cultured in the presence of the antigen was also analysed. It was found that p62–76 and p139–154 feeding suppressed the production of both Th1 and Th2 types. Interestingly, p139–154 feeding suppressed both T cell and antibody responses to BLG. Additionally, p139–154 feeding diminished BLG‐specific IgE and IgG1 antibody responses. CONCLUSION: The unique tolerogen peptide p139–154 that could suppress both T and B cell responses to BLG in a murine model was identified. These findings can be useful for the selection of an optimum tolerogenic peptide to prevent and treat milk and other food allergies. Copyright © 2007 Society of Chemical Industry     

The initial stage of high‐pressure induced β‐lactoglobulin aggregation: the long‐run simulation

Research objective of this study was to clarify how the initial stage of high‐pressure induced aggregation of β‐lactoglobulin takes place. For this purpose a special simulation method was developed. Distinctive features of this approach are: the lowest resolution model of protein particles, the local interaction potential and the abandonment of the continuous simulation of particle trajectories. Relatively short molecular dynamics trajectories are used only in order to find the average time step between the collisions. Results of particle collisions that occur with some probability, are separately (‘statically’) modelled using a random variable. This allows the analysis of the process which takes place within 10²–10³ s real‐time, with an existing probability of successful collision of 10^?10–10^?11. Modelling results confirm that at the initial stage of aggregation of 0.5–2% solutions with a neutral pH‐value only dimers as well as trimers arise due to SH/S–S interaction. In addition it was shown that aggregation follows the general principles of the reaction‐limited aggregation of colloids. The proposed approach could further be used in research projects examining the aggregation of β‐lactoglobulin or similar systems.     

Protein stability function relations: native β‐lactoglobulin sulphhydryl–disulphide exchange with PDS

Intermolecular sulphhydryl–disulphide exchange with β‐lactoglobulin dimer occurs when this dissociates to form monomers exposing two SH groups. This notion is re‐evaluated in the light of recent structural data suggesting that the degree of SH group exposure in β‐lactoglobulin is unaffected by dissociation. β‐Lactoglobulin was treated with 2,2′‐dipyridyl disulphide (PDS). The rate of sulphhydryl–disulphide exchange was measured at sub‐denaturation temperatures of 25–60 ° C. Parallel studies were conducted by reacting PDS with reduced glutathione (GSH). The SH group of GSH was up to 31 000 times more reactive than β‐lactoglobulin. At pH 7 the reaction activation enthalpy (ΔH^#) and entropy (ΔS^#) was 26 kJ mol⁻¹ and −100 J mol⁻¹ K⁻¹ respectively for GSH. For β‐lactoglobulin, ΔH^# was 157.2 kJ mol⁻¹ and ΔS^# was 254 J mol⁻¹ K⁻¹. At pH 2.6, ΔH^# was 14.4 kJ mol⁻¹ and ΔS^# was −213 J mol⁻¹ K⁻¹ for GSH. The corresponding results for β‐lactoglobulin were 20.3 kJ mol⁻¹ and −147 J mol⁻¹ K⁻¹. These and other thermodynamic results are discussed in terms of the effects of β‐lactoglobulin conformational structure and stability on SH group reactivity. For native β‐lactoglobulin at neutral pH, intermolecular sulphhydryl–disulphide exchange appears to involve the dissociated monomer. SH group activation probably arises from the lower structural stability of the monomer relative to the dimer. At pH 2.6 the mechanism of SH–disulphide exchange does not require protein dissociation and probably involves breathing motions or localised changes in protein structure. © 2000 Society of Chemical Industry     

Oxidatively induced chemical changes and interactions of mixed myosin, β‐lactoglobulin and soy 7S globulin

The effects of oxidation on the chemical characteristics of myosin, β‐lactoglobulin and soy 7S globulin were investigated in a free radical‐generating system (FeCl₃/H₂O₂/ascorbate). Oxidised myosin exhibited a marked increase (>10‐fold) in carbonyls, a small increase in amines and conversion of some free sulphhydryls to disulphide bonds. Oxidised β‐lactoglobulin and 7S globulin also showed a major increase in the carbonyl content (five‐ and threefold respectively), but other chemical changes were relatively minor. In the oxidised myosin/β‐lactoglobulin composites, some cross‐linked aggregates were formed. Aggregation was also evidenced in the myosin/7S globulin composites exposed to the oxidising agents. The results indicated that oxidation enhanced interactions of the non‐muscle proteins with myosin apparently through the modification of amino acid side chains. These physicochemical changes may influence the functionality of processed muscle foods. © 2000 Society of Chemical Industry     

Thermal modifications of structure and codenaturation of α‐lactalbumin and β‐lactoglobulin induce changes of solubility and susceptibility to proteases

Study of heat denaturation of major whey proteins (β‐lactoglobulin or α‐lactalbumin) either in separated purified forms, or in forms present in fresh industrial whey or in recomposed mixture respecting whey proportions, indicated significant differences in their denaturation depending on pH, temperature of heating, presence or absence of other co‐denaturation partner, and of existence of a previous thermal pretreatment (industrial whey). α‐Lactalbumin, usually resistant to tryptic hydrolysis, aggregated after heating at ⪈85°C. After its denaturation, α‐lactalbumin was susceptible to tryptic hydrolysis probably because of exposure of its previously hidden tryptic cleavage sites (Lys‐X and Arg‐X bonds). Heating over 85°C of β‐lactoglobulin increased its aggregation and exposure of its peptic cleavage sites. The co‐denaturation of α‐lactalbumin with β‐lactoglobulin increased their aggregation and resulted in complete exposure of β‐lactoglobulin peptic cleavage sites and partial unveiling of α‐lactalbumin tryptic cleavage sites. The exposure of α‐lactalbumin tryptic cleavage sites was slightly enhanced when the α‐lactalbumin/β‐lactoglobulin mixture was heated at pH 7.5. Co‐denaturation of fresh whey by heating at 95°C and pH 4.5 and above produced aggregates stabilized mostly by covalent disulfide bonds easily reduced by β‐mercaptoethanol. The aggregates stabilized by covalent bonds other than disulfide arose from a same thermal treatment but performed at pH 3.5. Thermal treatment of whey at pH 7.5 considerably enhanced tryptic and peptic hydrolysis of both major proteins.     

Effect of different treatments on the stability of lysozyme,lactoferrin and β‐lactoglobulin in donkey's milk

The aim of this study was to investigate the effects of freezing and heat treatments at different temperatures on the stability of the main whey proteins of donkey milk in comparison with those obtained from colostrum and raw milk. Samples subjected to heat treatment at 85 °C showed greater loss of stability, with levels decreasing by 60% and 87% for lysozyme and β‐lactoglobulin, respectively. Lactoferrin completely disappeared at heat treatments higher than 65 °C. Colostrum contained the highest lactoferrin and β‐lactoglobulin concentrations, however, lysozyme was found to be present at similar concentrations in colostrum, raw, frozen and heat‐treated milk at temperatures lower than 85 °C.     

Studies on the interaction of ‐epigallocatechin‐3‐gallate from green tea with bovine β‐lactoglobulin by spectroscopic methods and docking

The binding interaction between‐epigallocatechin‐3‐gallate (EGCG) and bovine β‐lactoglobulin (βLG) was thoroughly studied by fluorescence, circular dichroism (CD) and protein–ligand docking. Fluorescence data revealed that the fluorescence quenching of βLG by EGCG was the result of the formation of a complex of βLG–EGCG. The binding constants and thermodynamic parameters at two different temperatures and the binding force were determined. The binding interaction between EGCG and βLG was mainly hydrophobic and the complex was stabilised by hydrogen bonding. The results suggested that βLG in complex with EGCG changes its native conformation. Furthermore, preheat treatment (90 °C, 120 °C) and emulsifier (sucrose fatty acid ester) all boosted the binding constants (K_a) and the binding site values (n) of the βLG‐EGCG complex. This study provided important insight into the mechanism of binding interactions of green tea flavonoids with milk protein.     

Thermal transitions and dynamic gelling properties of oxidatively modified myosin, β‐lactoglobulin,soy 7S globulin and their mixtures

Oxidative effects on myosin, β‐lactoglobulin and soy 7S globulin as well as their composites were studied by differential scanning calorimetry and dynamic rheological analysis. Myosin, oxidised with a free radical‐generating system (FeCl₃/H₂O₂/ascorbate), was destabilised, showing a marked decrease (>50%) in storage modulus during thermal gelation. On the other hand, oxidised β‐lactoglobulin and 7S globulin exhibited only minor changes in their thermal stability and gelation properties. In the non‐oxidised myosin/β‐lactoglobulin composite, β‐lactoglobulin affected the thermal denaturation and gelation properties of myosin through non‐covalent interactions. The nature and extent of the interactions were altered by oxidation. 7S globulin did not change the thermal stability but slightly enhanced the rheological properties of myosin, regardless of oxidative conditions. Hence, in muscle foods that contain whey or soy protein ingredients, all the protein components can be oxidatively modified, and the extent of the functionality changes in myosin will be influenced by the presence of the non‐muscle proteins. © 2000 Society of Chemical Industry     

Screening of β‐Glucosidase and β‐Xylosidase Activities in Four Non‐Saccharomyces Yeast Isolates

The finding of new isolates of non‐Saccharomyces yeasts, showing beneficial enzymes (such as β‐glucosidase and β‐xylosidase), can contribute to the production of quality wines. In a selection and characterization program, we have studied 114 isolates of non‐Saccharomyces yeasts. Four isolates were selected because of their both high β‐glucosidase and β‐xylosidase activities. The ribosomal D1/D2 regions were sequenced to identify them as Pichia membranifaciens Pm7, Hanseniaspora vineae Hv3, H. uvarum Hu8, and Wickerhamomyces anomalus Wa1. The induction process was optimized to be carried on YNB‐medium supplemented with 4% xylan, inoculated with 106 cfu/mL and incubated 48 h at 28 °C without agitation. Most of the strains had a pH optimum of 5.0 to 6.0 for both the β‐glucosidase and β‐xylosidase activities. The effect of sugars was different for each isolate and activity. Each isolate showed a characteristic set of inhibition, enhancement or null effect for β‐glucosidase and β‐xylosidase. The volatile compounds liberated from wine incubated with each of the 4 yeasts were also studied, showing an overall terpene increase (1.1 to 1.3‐folds) when wines were treated with non‐Saccharomyces isolates. In detail, terpineol, 4‐vinyl‐phenol and 2‐methoxy‐4‐vinylphenol increased after the addition of Hanseniaspora isolates. Wines treated with Hanseniaspora, Wickerhamomyces, or Pichia produced more 2‐phenyl ethanol than those inoculated with other yeasts.     

Maillard glycation of β‐lactoglobulin induces conformation changes

Glycation by the Maillard reaction is an ubiquitous reaction of condensation of a reducing sugar with amino groups of proteins, which products could improve the functional and/or biological properties for food and non‐food uses. It can induce structural modifications in proteins, modifying their properties. The aim of this work was to investigate the association behavior and the conformational changes of β‐lactoglobulin (BLG) after its glycation by the Maillard reaction with several alimentary sugars (arabinose, galactose, glucose, lactose, rhamnose and ribose). Protein samples were heated in the presence or in the absence (heated control) of different sugars during 3 days at 60°C. Glycation induced oligomerization of BLG monomers. Depending on the reactivity of the sugar, the population of produced oligomers showed smaller or greater heterogeneity in molecular masses. Analysis of modified BLG by circular dichroism and by its susceptibility to pepsinolysis showed that the conditions of heating used did not significantly alter the conformation of BLG. Heating of BLG in presence of sugars induced only minor structural modification, when using the less reactive sugars such as lactose and rhamnose. It was, however, at the origin of major three‐dimensional destructuring in the case of the more reactive sugars such as arabinose and ribose. Pepsinolysis of glycated BLG did not affect about 62 and 35% of the protein molecules modified with lactose or rhamnose, and arabinose or ribose, respectively. The increase of susceptibility of glycated BLG to pepsinolysis could be related to the alteration of the conformation of the protein when glycation was performed with highly reactive sugars, as observed by circular dichroism and calorimetry analysis.     

Characterization of the Supermolecular Structure of Polydatin/6‐O‐α‐Maltosyl‐β‐cyclodextrin Inclusion Complex

Polydatin is the main bioactive ingredient in many medicinal plants, such as Hu‐zhang (Polygonum cuspidatum), with many bioactivities. However, its poor aqueous solubility restricts its application in functional food. In this work, 6‐O‐α‐Maltosyl‐β‐cyclodextrin (Malt‐β‐CD), a new kind of β‐CD derivative was used to enhance the aqueous solubility and stability of polydatin by forming the inclusion complex. The phase solubility study showed that polydatin and Malt‐β‐CD could form the complex with the stoichiometric ratio of 1:1. The supermolecular structure of the polydatin/Malt‐β‐CD complex was characterized by ultraviolet–visible spectroscopy (UV), Fourier transform infrared spectroscopy (FT‐IR), X‐ray diffractometry (XRD), thermogravimetric/differential scanning calorimetry (TG/DSC), and proton nuclear magnetic resonance (¹H‐NMR) spectroscopy. The changes of the characteristic spectral and thermal properties of polydatin suggested that polydatin could entrap inside the cavity of Malt‐β‐CD. Furthermore, to reasonably understand the complexation mode, the supermolecular structure of polydatin/Malt‐β‐CD inclusion complex was postulated by a molecular docking method based on Autodock 4.2.3. It was clearly observed that the ring B of polydatin oriented toward the narrow rim of Malt‐β‐CD with ring A and glucosyl group practically exposed to the wide rim by hydrogen bonding, which was in a good agreement with the spectral data.