Influence of maltodextrins with different dextrose equivalent on the thermodynamic properties of legumin in a bulk and at the air–water interface

This paper presents the influence of the potato maltodextrins with different dextrose equivalent (DE 2, 6 and 10) on the legumin thermodynamic properties in the bulk aqueous medium and at the air–water interface both in the simple mixed solutions and under the covalent complex (conjugate) formation (by the Maillard reaction), at pH 7.0 and ionic strength of 0.05 mol dm⁻³. The weak net attractive interaction between legumin and maltodextrin has been found in an aqueous medium by both the light scattering and the mixing calorimetry methods. On the basis of both the mixing and differential scanning calorimetry data a hydrogen bonding is supposed to be fundamental for this interaction. It was found that these attractive interactions produced an increase in the protein hydrophilicity and consequently a decrease in the protein surface activity. The effect was more pronounced for the maltodextrin with the largest dextrose equivalent (DE 10). The covalent complexation between legumin and maltodextrin induced the change of the fine hydrophobic–hydrophilic balance in the protein globule due to both addition of the hydrophilicity of the covalently attached polysaccharide and the partial protein unfolding as a result of the such kind of attachment. The combined data of tensiometry, light scattering, mixing and differential scanning calorimetry demonstrated the importance of the maltodextrin polymerization (DE) in controlling both the protein hydrophilicity (thermodynamic affinity for the aqueous phase) and surface activity.     

Heterologous Expression of Legumin Gene in <Emphasis Type="Italic">E. coli</Emphasis> Isolated from cDNA Clones of Immature Seeds of Pigeonpea (<Emphasis Type="Italic">Cajanus cajan</Emphasis> L.)

Proteins are one of the targets for improving the nutritional quality, and attempts are being made through manipulation of its native gene(s). Pigeonpea (Cajanus cajan L.) is one of the nutritionally important legumes of tropical and subtropical regions of the world, and studies of the structure of seed storage proteins and their interactions have been limited by the difficulty of isolating single-protein subunits in large amounts from a complex mixture of the seed endosperm. One way to overcome this problem is the expression of seed storage protein-encoded gene(s) in heterologous systems that have additional advantages wherein specific gene modifications can be made and the new gene constructs can quickly be expressed. Legumin protein was extracted from pigeonpea seeds of different developmental stages (5th to 25th day after flowering [DAF]) and characterized. The legumin gene (leg) of size 1.482 kb was screened, using the deoxygenin-labeled legumin probe, from the complementary deoxyribonucleic acid (cDNA) library, constructed from 18-day-old (DAF) immature seeds of pigeonpea and sequenced (accession no. AF3555403). The legumin gene was further characterized by DNA blotting, and its probable secondary structure was predicted using online ExPASy server. Significant Protein Data Bank (PDB) alignment of the deduced legumin protein by BLASTP was observed with proglycinin of soybean. Comparative 3D structural homology was predicted by Cn3D software, and the legumin protein showed the 3D structure alignment and interaction homology with proglycinin chain 1FXZA (PDB no. 1FXZ). The legumin gene was subcloned in vector pET-24a driven by the bacterial promoter, and its expression was detected in Escherichia coli by immunoblotting using polyclonal antibodies, raised against the purified legumin protein.     

Effect of small molecule surfactants on molecular parameters and thermodynamic properties of legumin in a bulk and at the air–water interface depending on a protein structure in an aqueous medium

This paper presents the effect of fatty acid salts, namely, Na-caprate and Na-palmitate on the legumin (11S globulin of Vicia Faba broad beans) molecular and thermodynamic properties in the bulk aqueous medium and at the air–water interface under different molecular states of the protein. That are the native state of the protein globule (pH 7.2, ionic strength of 0.05 mol dm⁻³), as well as the acidic denatured (pH 3.0, ionic strength of 0.01 mol dm⁻³) and the heat denatured ones (after heating at 90°C for 30 min, pH 7.2, ionic strength of 0.05 mol dm⁻³). In turn, an importance of the state of the small molecule surfactants in a solution in reference to the critical concentrations of micelle formation (CMC), for their effect on the protein properties, was also under our studying. The peculiarities of the legumin structure in the aqueous medium appeared in the different nature of the interactions between the protein and the fatty acid salts, as was indicated by the mixing calorimetry data. So, the hydrophobic contacts provided a basis for interactions between both the native and heat denatured legumin with the fatty acid salts. At the same time, the electrostatic interactions between the oppositely charged functional groups of the fatty acid salts and the acidic denatured protein formed principally a basis of their interactions in an aqueous medium. In response to interactions of the fatty acid salts with legumin the essential changes in the protein conformational stability, depending on both the protein molecular state and concentration of the fatty acid salts, were found using differential scanning calorimetry (DSC). The rather high level of the protein association was observed by light scattering in the bulk aqueous medium in the presence of the fatty acid salts. As this takes place, the surface hydrophilicity of the protein increased under the formation of the associates. The combined data of mixing calorimetry, differential scanning calorimetry and light scattering suggested the complex formation between legumin and the fatty acid salts. The interactions of the fatty acid salts with the protein produced a change in the surface activity for the mixture of the protein with the fatty acid salts. That is a decrease in the protein surface tension at the air–water interface for the mixed solutions in comparison with ones for both the protein and small molecule surfactant alone in the case of Na-caprate, and those are the intermediate values of the surface tension in the case of Na-palmitate. These results were observed independently of the protein state (native or acidic/heat denatured) in an aqueous medium. As this took place, the most dramatic increase in the surface activity was found for the mixtures of the acidic denatured protein with Na-caprate as if the most hydrophobic species were formed in this case. The combined data of mixing calorimetry, DSC, light scattering and tensiometry showed that the effect of the fatty acid salts on the legumin thermodynamic properties in a bulk and at interfaces is governed by a number of the key factors such as: a structure of both the protein and fatty acid salt (a length of the hydrocarbon chain); a degree of the protein association in the bulk aqueous phase (as a result of the interactions with the small molecule surfactants); a change in the protein conformational stability (flexibility) under the influence of the small molecule surfactants; as well as by the nature (hydrophobic, electrostatic) of the protein–small molecule surfactant interactions, determining ultimately the hydrophilic–lipophilic balance of the protein surface.