Saı̈d Bouhallab scite author profile

The extent of the early stage of the Maillard-type reaction that impaired functional properties of whey proteins was evaluated by electrospray ionization mass spectrometry. Under conditions of mild heat treatment (63 degrees C for 20 s) applied to milk before whey separation at room temperature 23 degrees C), a modification of the relative molecular mass of beta-lactoglobulin (beta-LG) was observed that differed from that of the native form by 324. This specific modification of beta-LG occurred in acidified whey as well as in sweet whey and increased with the extent of the heat treatment. Incubation of purified beta-LG dissolved in milk ultrafiltration permeate or in lactose solution at 50 to 80 degrees C demonstrated the presence of a lactosyl residue that was covalently bound to beta-LG; beta-casein, used as a control, showed no mass modification. Studies of kinetics showed that a maximum of 35% of the beta-LG was lactosyl-beta-LG conjugate after heat treatment at 70 degrees C for 1 h. This study provides the first direct evidence of specific lactosylation of beta-LG during the initial stage of the Maillard reaction. One of the first lactose-binding sites was identified as a Lys47 by protease mapping and analysis by means of on-line liquid chromatography combined with mass spectrometry. In addition, collision-activated dissociation performed on the lactosylated peptide beta-LG (f 46-51) showed the rearrangement reactions occurring during the fragmentation process by electrospray. A mechanism is proposed.

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The structure of infant formulas impacts their lipolysis, proteolysis and disintegration during in vitro gastric digestion

Bourlieu-Lacanal¹,

Ménard²,

Chevasnerie³

et al. 2015

Food Chemistry

178

100

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Nonenzymatic Lactosylation of Bovine β-Lactoglobulin under Mild Heat Treatment Leads to Structural Heterogeneity of the Glycoforms

Morgan

Léonil

Mollé

et al. 1997

Biochemical and Biophysical Research Communications

103

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Bovine β-lactoglobulin/fatty acid complexes: binding, structural, and biological properties

Maux

Bouhallab

Giblin

et al. 2014

Dairy Sci. & Technol.

117

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Ligand-binding properties of β-lactoglobulin (β-lg) are well documented, but the subsequent biological functions are still unclear. Focusing on fatty acids/β-lg complexes, the structure-function relationships are reviewed in the light of the structural state of the protein (native versus non-native aggregated proteins). After a brief description of β-lg native structure, the review takes an interest in the binding properties of native β-lg (localization of binding sites, stoichiometry, and affinity) and the way the interaction affects the biological properties of the protein and the ligand. The binding properties of non-native aggregated forms of β-lg that are classically generated during industrial processing are also related. Structural changes modify the stoichiometry and the affinity of β-lg for fatty acids and consequently the biological functions of the complex. Finally, the fatty acid-binding properties of other whey proteins (α-lactalbumin, bovine serum albumin) and some biological properties of the complexes are also addressed. These proteins affect β-lg/fatty acids complex in whey given their competition with β-lg for fatty acids.

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Heating and glycation of β-lactoglobulin and β-casein: Aggregation and in vitro digestion

Pinto¹,

Léonil²,

Henry³

et al. 2014

Food Research International

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Stable monomeric intermediate with exposed Cys-119 is formed during heat denaturation of β-lactoglobulin

Croguennec

Bouhallab

Mollé

et al. 2003

Biochemical and Biophysical Research Communications

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The role of the free sulfhydryl group of beta-lactoglobulin in the formation of a stable non-native monomer during heat-treatment of beta-lactoglobulin solutions was investigated. Two concomitant events occurred at the earlier stage of heating: unfolding of native globular monomer and intramolecular sulfhydryl/disulfide exchange reaction. Thus, two denatured monomeric species were formed: a non-native monomer with exposed Cys-121 (Mcys121) which became reversible after cooling, and a stable non-native monomer with exposed Cys-119 (Mcys119) which exhibited both a larger hydrodynamic conformation than native monomer and low solubility at pH 4.7. The results also show that the formation of these monomeric species throughout heat-induced denaturation of native beta-lg monomers is faster than their subsequent aggregation. A mechanism describing the behavior of beta-lg denaturation/aggregation during heat-treatment under selected conditions (5.8 mg/ml, low ionic strength, pH 6.6, 85 degrees C) is presented.

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Modification of Bovine β-Lactoglobulin by Glycation in a Powdered State or in an Aqueous Solution: Effect on Association Behavior and Protein Conformation

Morgan

Léonil

Mollé

et al. 1998

J. Agric. Food Chem.

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The effect of glycation with lactose on the association behavior and conformational state of bovine beta-lactoglobulin (beta-LG) was studied, using size exclusion chromatography, polyacrylamide gel electrophoresis, proteolytic susceptibility, and binding of a fluorescent probe. Two modification treatments were used, i.e., aqueous solution glycation and dry-way glycation. The results showed that the latter treatment did not significantly alter the nativelike behavior of the protein while the former treatment led to important structural changes. These changes resulted in a specific denatured beta-LG monomer, which covalently associated via the free thiol group. The homodimers thus formed and the expanded monomers underwent subsequent aggregation into a high molecular weight species, via noncovalent interactions. The association behavior of glycated beta-LG is discussed with respect to the known multistep denaturation/aggregation process of nonmodified beta-LG.

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Milk proteins as encapsulation devices and delivery vehicles: Applications and trends

Tavares

Croguennec

Carvalho

et al. 2014

Trends in Food Science & Technology

169

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Increasing the shelf-life of sensitive substances and targeting the release of nutritional/bioactive molecules are among the great challenges for the food industry. The development of food products with embedded encapsulation devices used to reach these objectives, constitutes a growing market. Milk proteins are biopolymers that are chemically and structurally versatile and are well adapted to several encapsulation purposes. Therefore, in this paper, the strategies, techniques, advantages and trends associated with the use of milk proteins as encapsulating device are reviewed. Special attention is given to the novel potential of reversibly co-assembled protein structures as encapsulating devices.

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Saı̈d Bouhallab

Characterization by Ionization Mass Spectrometry of Lactosyl β-Lactoglobulin Conjugates Formed During Heat Treatment of Milk and Whey and Identification of One Lactose-Binding Site

The structure of infant formulas impacts their lipolysis, proteolysis and disintegration during in vitro gastric digestion

Nonenzymatic Lactosylation of Bovine β-Lactoglobulin under Mild Heat Treatment Leads to Structural Heterogeneity of the Glycoforms

Bovine β-lactoglobulin/fatty acid complexes: binding, structural, and biological properties

Heating and glycation of β-lactoglobulin and β-casein: Aggregation and in vitro digestion

Stable monomeric intermediate with exposed Cys-119 is formed during heat denaturation of β-lactoglobulin

Modification of Bovine β-Lactoglobulin by Glycation in a Powdered State or in an Aqueous Solution: Effect on Association Behavior and Protein Conformation

Milk proteins as encapsulation devices and delivery vehicles: Applications and trends

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