C. Bertrand-Harb scite author profile

The secondary structure transformation of beta-lactoglobulin from a predominantly beta-structure into a predominantly alpha-helical one, under the influence of solvent polarity changes is reversible. Independent of the alcohol used--methanol, ethanol, or 2-propanol--the midpoints of the observed structural transformation occur around dielectric constant epsilon approximately 60. The structural change destroying the hydrophobic core formed by the beta-barrel structure leads, at room temperature, to the dissociation of the retinol/beta-lactoglobulin complex in the neighborhood of dielectric constant epsilon approximately 50. However, when the dielectric constant of the medium is raised back to epsilon approximately 70 by the decrease of the temperature, both the refolding of BLG into a beta-structure and the reassociation of the retinol/beta-lactoglobulin complex are observed. The esterification of beta-lactoglobulin carboxyl groups has two effects: on the one hand it accelerates the beta-strand<==>alpha-helix transition induced by alcohols. On the other hand, the esterification of beta-lactoglobulin strengthens its interaction with retinol as it may be deduced from the smaller apparent dissociation constant of retinol/methylated beta-lactoglobulin complex. The binding of retinol to modified or unmodified beta-lactoglobulin has no influence (stabilizing or destabilizing) on the folding changes induced by alcohol.

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

Bertrand-Harb

Baday

Dalgalarrondo

et al. 2002

Nahrung

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Study of heat denaturation of major whey proteins (beta-lactoglobulin or alpha-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 codenaturation partner, and of existence of a previous thermal pretreatment (industrial whey). alpha-Lactalbumin, usually resistant to tryptic hydrolysis, aggregated after heating at > or = 85 degrees C. After its denaturation, alpha-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 degrees C of beta-lactoglobulin increased its aggregation and exposure of its peptic cleavage sites. The co-denaturation of alpha-lactalbumin with beta-lactoglobulin increased their aggregation and resulted in complete exposure of beta-lactoglobulin peptic cleavage sites and partial unveiling of alpha-lactalbumin tryptic cleavage sites. The exposure of alpha-lactalbumin tryptic cleavage sites was slightly enhanced when the alpha-lactalbumin/beta-lactoglobulin mixture was heated at pH 7.5. Co-denaturation of fresh whey by heating at 95 degrees C and pH 4.5 and above produced aggregates stabilized mostly by covalent disulfide bonds easily reduced by beta-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.

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C. Bertrand-Harb

Solubility and emulsifying properties of caseins and whey proteins modified enzymically by trypsin

Proteolysis of β-lactoglobulin and β-casein by pepsin in ethanolic media

Evolution of β-lactoglobulin and α-lactalbumin content during yoghurt fermentation

Reversible effects of medium dielectric constant on structural transformation of β‐lactoglobulin and its retinol binding

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

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