Net charge affects morphology and visual properties of ovalbumin aggregates.

The effect of ovalbumin net charge on aggregate morphology and visual properties was investigated using chromatography, electrophoresis, electron microscopy, and turbidity measurements. A range of differently charged ovalbumin variants (net charge ranging from -1 to -26 at pH 7) was produced using chemical engineering. With increasing net charge, the degree of branching and flexibility of the aggregates decreased. The turbidity of the solutions reflected the aggregate morphology that was observed with transmission electron microscopy. Increasing the stiffness of the aggregates transformed the solutions from turbid to transparent. Artificially shielding the introduced net charge by introducing salt in the solution resulted in an aggregate morphology that was similar to that for low-net-charge variants. The morphology of heat-induced aggregates and the visual appearance of the solutions were significantly affected by net charge. We also found that the morphology of ovalbumin aggregates can be rapidly probed by high-throughput turbidity experiments.

Effect of protein charge on the generation of aggregation-prone conformers.

This study describes how charge modification affects aggregation of ovalbumin, thereby distinguishing the role of conformational and electrostatic stability in the process. Ovalbumin variants were engineered using chemical methylation or succinylation to obtain a range of protein net charge from -1 to -26. Charge modification significantly affected the denaturation temperature. From urea-induced equilibrium denaturation studies, it followed that unfolding proceeded via an intermediate state. However, the heat-induced denaturation process could still be described as a two-state irreversible unfolding transition, suggesting that the occurrence of an intermediate has no influence on the kinetics of unfolding. By monitoring the aggregation kinetics, the net charge was found not to be discriminative in the process. It is concluded that the dominant factor determining ovalbumin aggregation propensity is the rate of denaturation and not electrostatic repulsive forces.

Acid-induced cold gelation of globular proteins: effects of protein aggregate characteristics and disulfide bonding on rheological properties.

The process of cold gelation of ovalbumin and the properties of the resulting cold-set gels were compared to those of whey protein isolate. Under the chosen heating conditions, most protein was organized in aggregates. For both protein preparations, the aggregates consisted of covalently linked monomers. Both types of protein aggregates had comparable numbers of thiol groups exposed at their surfaces but had clearly different shapes. During acid-induced gelation, the characteristic ordering caused by the repulsive character disappeared and was replaced by a random distribution. This process did not depend on aggregate characteristics and probably applies to any type of protein aggregate. Covalent bonds are the main determinants of the gel hardness. The formation of additional disulfide bonds during gelation depended on the number and accessibility of thiol groups and disulfide bonds in the molecule and was found to clearly differ between the proteins studied. However, upon blocking of the thiol groups, long fibrillar structures of ovalbumin contribute significantly to gel hardness, demonstrating the importance of aggregate shape.

Heat-induced denaturation and aggregation of ovalbumin at neutral pH described by irreversible first-order kinetics.

The heat-induced denaturation kinetics of two different sources of ovalbumin at pH 7 was studied by chromatography and differential scanning calorimetry. The kinetics was found to be independent of protein concentration and salt concentration, but was strongly dependent on temperature. For highly pure ovalbumin, the decrease in nondenatured native protein showed first-order dependence. The activation energy obtained with different techniques varied between 430 and 490 kJ*mole(-1). First-order behavior was studied in detail using differential scanning calorimetry. The calorimetric traces were irreversible and highly scan rate-dependent. The shape of the thermograms as well as the scan rate dependence can be explained by assuming that the thermal denaturation takes place according to a simplified kinetic process where N is the native state, D is denatured (or another final state) and k a first-order kinetic constant that changes with temperature, according to the Arrhenius equation. A kinetic model for the temperature-induced denaturation and aggregation of ovalbumin is presented. Commercially obtained ovalbumin was found to contain an intermediate-stable fraction (IS) of about 20% that was unable to form aggregates. The denaturation of this fraction did not satisfy first-order kinetics.