Participation of cysteine 30 residue in the folding process of ovalbumin evaluated in a refolding experiment using cysteine mutants.

To understand the role of cysteine (SH) residues in the folding of hen ovalbumin (OVA), SH-mutated OVAs, in which each SH residue was replaced by alanine (C11A, C30A, C367A, and C382A), were prepared. SDS-PAGE analysis under non-reducing conditions showed that the C11A and C30A mutants produced a disulfide (SS) isomer in addition to a protein with a native SS bond (Cys73-Cys120). The susceptibility to elastase digestion suggested that the Cys73 residue in the SS isomer participates as a counterpart of the SS bond. Upon refolding of the SH-mutated OVAs under the denatured and SS-reduced states, only C30A failed to refold into an intact form. This indicated that the Cys30 residue plays an important role in correct refolding. To confirm this, each of the four SH-mutated OVAs, in which the original SS-forming sites (C11/73/120A, C30/73/120A, C73/120/367A, and C73/120/382A) were deleted, was constructed and expressed. The C11/73/120A and C30/73/120A mutants formed no SS form, in contrast to C73/120A as a control. Thus, we concluded that Cys30 participates in the correct folding of OVA, and that its SS bond (Cys11-Cys30) is transiently generated during the early folding stage to avoid misfolding, and then the native SS form of OVA is regenerated through SH-SS exchanges.

The role of the disulfide bridge in the stability and structural integrity of ovalbumin evaluated by site-directed mutagenesis.

To provide a molecular explanation of the role of the disulfide (SS) bridge in the thermostability and structural integrity of ovalbumin (OVA), we prepared SS-mutated OVAs in which SS-forming residues were replaced by Ala or Ser (C73A, C73S, C120A, and C73/120A), and compared the conformation, thermostability, susceptibility to elastase, and formation of heat-stable OVA (S-OVA) with those of the wild-type. The circular dichroism (CD) and tryptophan fluorescence spectra revealed that the SS-mutated OVAs assumed a native-like conformation similar to the wild-type. The thermal denaturation temperature for the SS-mutated OVAs was significantly lower than that for the wild-type. C73S, C120A, and C73/120A mutants converted to S-OVA on alkaline treatment. Analyses for elastase digestion fragments showed that a non-native SS bridge was generated in all SS-mutated OVAs, but non-native SS-pairing did not contribute to thermostability. Hence, we concluded that the presence of the original SS bridge in OVA contributes to conformational stability but is not directly related to the conversion to S-OVA.

Thermostabilization of ovalbumin by alkaline treatment: Examination of the possible roles of D-serine residues.

It was revealed from the crystal structure analysis of S-ovalbumin (S-OVA) formed by alkaline treatment that Ser164, Ser236, and Ser320 take the D-amino acid residue configuration (Yamasaki et al., J Biol Chem 2003; 278:35524-35530). To address the implications of a D-configuration for these Ser residues in S-OVA formation, three mutant OVAs (S164A, S236A, and S320A) were generated to compare their thermostabilities before and after alkaline treatment. Following alkaline treatment, S236A showed a marked increase in melting temperature similar to the wild type (DeltaT(m), +9 degrees C) which corresponded to the formation of S-OVA, whereas the increment in T(m) for both S164A and S320A was only 4.5 degrees C. Furthermore, the T(m) value of the double mutant S164/320A remained unchanged after alkaline treatment, supporting the relevance of Ser164 and Ser320 for thermostabilization of OVA. As Arg142 was predicted to interact with D-Ser164 upon S-OVA formation, it was substituted to Ala to generate R142A. The resulting increment in T(m) of mutant R142A after alkaline treatment was 5.8 degrees C. The double mutant R142/S320A was therefore prepared to eliminate the participation of Ser320 in thermostabilization, and its T(m) value was compared before and after alkaline treatment. As expected, the increase in T(m) for the double mutant was only 1.2 degrees C. Taken together, the data suggest that D-configuration of Ser164 caused by alkaline treatment favors interaction with Arg142 through conformational changes of the side chain. These results strongly supported the participation of the configurational inversion of both Ser164 and Ser320 residues in the formation of S-OVA.

Importance of N-glycosylation positioning for secretion and folding of ovalbumin.

To investigate the role of the carbohydrate chain of hen egg ovalbumin (OVA), potential N-glycosylation site-deletion OVA mutants were expressed in yeast. The secretion level of the N292Q and N292/311Q mutants was greatly reduced compared with the wild-type OVA. Furthermore, secretion of the mutants without a carbohydrate chain on Asn-292 could hardly be detected in the culture medium, even if an additional N-glycosylation site was introduced to the OVA molecule. The reduction in secretion level seems to be due to incorrectly folded protein. Moreover, the secretion levels of the wild-type and N311Q mutant reduced in a similar extent as those of the mutants without a carbohydrate chain on Asn-292 in calnexin-disrupted yeast. These results indicate that the carbohydrate chain attached to Asn-292 of OVA has an important role for the secretion and folding in the cells.

Site-specific glycosylation at Asn-292 in ovalbumin is essential to efficient secretion in yeast.

Chicken ovalbumin (OVA) exists as mono-N-glycosylated form with a carbohydrate chain on Asn-292 in egg white, despite the possession of two potential N-glycosylation sites. To investigate the roles of N-glycosylation of OVA, we constructed a series of N-glycosylation mutants deleted N-glycosylation site and compared the secretion level of the mutants in Pichia pastoris. N292Q and N292/311Q mutants resulted in greater lowering of the secretion level as compared with wild-type, whereas N311Q mutant was secreted in approximately equal amounts to wild-type. However, secretion of wild-type and N311Q mutant was inhibited completely by tunicamycin treatment. All the N-glycosylation mutants have been expressed in the cells, as well as wild-type. Circular dichroism and fluorescence spectra of secreted N311Q mutant were almost identical to those of wild-type, while those of N292Q and N292/311Q mutants were different from wild-type; and, N292Q and N292/311Q mutants showed considerably lower denaturation temperature than wild-type. The results indicate that N-glycosylation at Asn-292 of OVA is required for the folding and secretion.

Preventive effect of egg yolk phosvitin on heat-insolubilization of egg white protein and its application to heat-induced egg white gel.

The effects of phosvitin (PV) on insolubilization of egg white protein (EWP) and ovotransferrin (OT) were examined by measuring turbidity after heating at 80 degrees C in a pH range of 5 to 8. PV showed preventive ability against heat-insolubilization of EWP, especially heat-labile OT. The preventive ability of PV was reduced by adding NaCl to a PV-OT mixture on heating. Native PAGE and gel filtration analyses showed that PV prevented an insolubilization of heat-denatured OT through ionic interactions. The preventive effects of PV on insolubilization of EWP and OT resulted in the formation of a firm, transparent gel from EWP in coexistence with PV on heating. The addition of PV might make possible the preparation of liquid egg white without insoluble products even on heat-treatment at high temperatures.

Phosphorylation of ovalbumin by dry-heating in the presence of pyrophosphate: effect on protein structure and some properties.

Ovalbumin (OVA) was phosphorylated by dry-heating in the presence of pyrophosphate at pH 4.0 and 85 degrees C for 1 and 5 days, and the physicochemical and structural properties of phosphorylated OVA were investigated. The phosphorus content of OVA increased to 1.01% by phosphorylation, and the electrophoretic mobility of PP-OVA also increased. Although the solubility of dry-heated OVA decreased, the decrease was slightly depressed by phosphorylation. The circular dichroism spectra showed that the change of the secondary structure in the OVA molecule, as measured by alpha-helix content, was mild by phosphorylation. The exchange reaction between the sulfhydryl and disulfide groups was enhanced and the surface hydrophobicity of OVA increased by phosphorylation. The tryptophan fluorescence intensity of OVA decreased by phosphorylation, suggesting that the conformational change occurred in the OVA molecule by phosphorylation. Although the differential scanning calorimetry thermograms of OVA showed a lowering of the denaturation temperature from 78.3 to 70.1 degrees C by phosphorylation, the stability of OVA against heat-induced insolubility at pH 7.0 was improved. The results indicated molten (partially unfolded) conformations of OVA formed by dry-heating in the presence of pyrophosphate.

Structural characteristics of hen egg ovalbumin expressed in yeast Pichia pastoris.

The recombinant ovalbumin (OVA) produced in yeast Pichia pastoris was purified from the culture medium by anion exchange chromatography, and its structural characteristics were compared with those of hen egg OVA, mainly from the point of view of posttranslational modification. The expressed OVA consisted of two molecular species immmunoreactive with antibody for hen egg OVA. The two molecular species, 45 and 47 kDa in molecular size, were thought to correspond to mono-glycosylated form and di-glycosylated form respectively. The non-glycosylated form was not produced in the system. The other posttranslational modifications (N-terminal acetylation and phosphorylation) observed in hen egg OVA were not detected in either of the molecular species. The two recombinant proteins displayed almost exactly the same circular dichroism and intrinsic tryptophan fluorescence spectra as hen egg OVA. The melting temperature, Tm, which was determined from the thermal unfolding curve, was almost identical in the two recombinant proteins, despite the difference in glycosylation levels, while it decreased by about 2.5 degrees C as compared with that of hen egg OVA (77.3 degrees C). These data indicate that the additional glycosylation to Asn-311 in the recombinant protein does not affect protein conformation or thermostability.

Ability of alphas-Casein to suppress the heat aggregation of ovotransferrin.

The effects of alphas-casein on heat aggregation of ovotransferrin (OT) were studied by heating at 80 degrees C for 20 min in 10 mM phosphate buffer, pH 7.0. The heat interactions between alphas-casein and OT were followed by turbidity development and polyacrylamide gel electrophoresis. We found that alphas-casein can effectively suppress the heat-induced aggregation of heat-labile OT. The suppressive ability of alphas-casein was reduced by the presence of NaCl on heating. Dephosphorylated alphas-casein had less ability to suppress the aggregation of OT than native alphas-casein. Our results indicate that alphas-casein interacts with the heat-denatured OT through its exposed hydrophobic surface and phosphoserine residue. Such interactions seem to be important in helping to suppress the aggregation of heated OT. The suppressive effects of alphas-casein on heat aggregation of OT would be partially ascribed to the formation of transparent gel from egg white by the addition of alphas-casein.

alpha-Casein improves the gel properties of dried egg white.

The effects of addition of alpha-casein (alpha-CN) to dried egg white (DEW) were investigated by measuring transparency, hardness, and water-holding capacity (WHC) of the heat-induced gels. A DEW concentration of 8% (w/w) was required for formation of a self-supporting gel following heating at 80 degrees C for 20 min at pH 7. Solutions of alpha-CN, even up to a protein concentration of 12% (w/w), did not gel under the same conditions. The addition of alpha-CN (0.5-4%) to 8% DEW caused the increase in gel hardness gels, as compared with DEW gels alone at a total amount of protein concentrations, and the mixed gels became transparent with the increase of added alpha-CN concentrations. The 10% mixed protein solutions of alpha-CN (3-6%) and DEW (4-7%) formed transparent gels, although each protein did not gel individually at their protein concentrations. Mixture with 2:8 mixing ratio of alpha-CN to DEW at a total protein concentration of 10% showed synergistic effects in improving DEW gel properties above pH 7 and below 25 mM NaCl. The improvements (hardness, transparency, and WHC) of DEW gel by alpha-CN seem to be caused mainly by the inhibition of alpha-CN against heat coagulation of DEW protein.

Improvement of gel properties of dried egg white by modification with galactomannan through the Maillard reaction.

The effects of Maillard reaction on gel properties of dried egg white (DEW) with galactomannan (GM) were investigated. Maillard-reacted DEW (MDEW) was prepared by dry-heating a mixture with a weight ratio of 1:4 of GM to DEW at 60 degrees C and 65% relative humidity. The modification of amino groups and polymerization of DEW proteins dry-heated with GM proceeded with increasing the dry-heating time. The covalent attachment of GM to DEW was confirmed from SDS-PAGE analysis. Gel strength and water-holding capacity of MDEW gels were higher than those of DEW dry-heated without GM (control DEW) and reached maximum after 3 days of dry-heating. The appearance of MDEW gels became transparent with increasing the dry-heating time, but control DEW gels were still turbid. MDEW dry-heated for 3 days was almost soluble even after heating of its solution at 90 degrees C, whereas control DEW proteins precipitated. The modification of DEW with GM through the Maillard reaction was an effective method to make a firm and transparent gel from DEW at broader range of pH and NaCl concentration of the medium.