Effect of Sorbed Water on the Thermal Stability of Soybean Protein

A soybean protein isolate (SPI), and its β-conglycinin and glycinin componets were obtained from defatted soybean flour by applying dissolution and precipitation based on the difference in their solubility depending on each isoelectric point. The purity evaluated by SDS–PAGE of the β-conglycinin and glycinin preparations was about 84% and 80%, respectively, resulting in a clear difference in the pH dependence on solubility. A BET plot derived from the water sorption isotherm at 25 °C showed that the amount of the monolayer adsorption of these preparations was about 6–9%, the value for the β-conglycinin preparation being about 1.5 times higher than that for the glycinin preparation. The β-conglycinin and glycinin preparations were respectively denatured at around 75 °C and 86 °C in the presence of excess water, whereas the denaturation temperature of both preparations was markedly increased by decreasing sorbed water content below 40%, corresponding well with the unfrozen water content.     

Novel method using phytase for separating soybean beta-conglycinin and glycinin

A novel method for separating soybean beta-conglycinin and glycinin from defatted soymilk by a phytase treatment was developed. Phytase was added to defatted soymilk (1000FYT/100 g of protein) at pH 6.0, and the mixture incubated for 1 h at 40 degrees C. This procedure separated beta-conglycinin and glycinin without needing a reducing agent or cooling into the soluble and insoluble fractions, respectively. Simultaneously, most of the phytate in both proteins was removed.     

Disappearance of immunoreactive glycinin and beta-conglycinin in the digestive tract of piglets

Soybean allergy represents a health threat to human and animals. Glycinin and beta-conglycinin, the main storage proteins in soybean, have been identified as major food/ feed allergens. The present study was conducted to investigate the disappearance of immunoreactive glycinin and beta-conglycinin in the digestive processes of piglets. Twelve crossbred piglets, weaned at 21 days of age, were allocated to three dietary treatments in a complete block design, each treatment with four replicates (female/male = 1:1). From day 22-28, the control group was fed diets without leguminous products, while the two treatment groups received diets containing 2.2% purified glycinin or beta-conglycinin. All piglets were slaughtered at 29 days of age and digesta was sampled from stomach, middle jejunum, caecum and colon. Results indicated that immunoreactive glycinin and beta-conglycinin decreased as the digesta descended down the digestive tract to 0.12% and 0.47%, respectively. Little immunoreactive glycinin was found in the digesta of caecum and colon, while immunoreactive beta-conglycinin was detected in the colon. Along the whole digestive tract the disappearance of immunoreactive glycinin was significantly higher than beta-conglycinin (p < 0.05).     

Carbon dioxide induced soybean protein precipitation: protein fractionation, particle aggregation, and continuous operation

A novel protein fractionation technique using a volatile electrolyte has been developed. Carbon dioxide was used to isoelectrically precipitate 80% and 95% pure glycinin and beta-conglycinin fractions from soybean isolate. The protein fractions precipitated as primary particles 0.2-0.3 microm in diameter, which under optimum conditions may be recovered as aggregates up to 500 microm in diameter. The dependency of protein fractionation efficiency on aggregate settling rates has been demonstrated. The isoelectric points of the two main soybean fractions, glycinin and beta-conglycinin, were calculated to be pH 5.2 and 4.95, respectively. Solution pH was accurately controlled by pressure in the isoelectric pH range of the different soybean protein fractions, and a pH "overshoot" was eliminated. Volatile electrolyte technology was also applied to a continuous process in order to eliminate the particle recovery concerns associated with batch precipitation and to demonstrate the potential for scale-up. Glycinin was effectively recovered on-line (94% glycinin recovery) with a purity approaching that of the batch process (95%).     

Accumulation of high levels of free amino acids in soybean seeds through integration of mutations conferring seed protein deficiency

Soybean ( Glycine max [L.] Merr.) seeds are rich in protein, most of which is contributed by the major storage proteins glycinin (11S globulin) and beta-conglycinin (7S globulin). Null mutations for each of the subunits of these storage proteins were integrated by crossbreeding to yield a soybean line that lacks both glycinin and beta-conglycinin components. In spite of the absence of these two major storage proteins, the mutant line grew and reproduced normally, and the nitrogen content of its dry seed was similar to that for wild-type cultivars. However, protein bodies appeared underdeveloped in the cotyledons of the integrated mutant line. Furthermore, whereas free amino acids contribute only 0.3-0.8% of the seed nitrogen content of wild-type varieties, they constituted 4.5-8.2% of the seed nitrogen content in the integrated mutant line, with arginine (Arg) being especially enriched in the mutant seeds. Seeds of the integrated mutant line thus appeared to compensate for the reduced nitrogen content in the form of glycinin and beta-conglycinin by accumulating free amino acids as well as by increasing the expression of certain other seed proteins. These results indicate that soybean seeds are able to store nitrogen mostly in the form of either proteins or free amino acids.     

Purification and characterization of mRNA from soybean seeds. Identification of glycinin and beta-conglycinin precursors

Poly(A)-rich RNA was isolated from developing soybean seeds (Glycine max (L.) Merr.) and fractionated on linear log sucrose gradients. Two major fractions sedimenting at 18 S and 20 S were separated and then purified by further sucrose gradient fractionation. Both fractions were active as messengers when added to a rabbit reticulocyte lysate protein synthesis system. The 18 S fraction caused proteins migrating primarily to the 60,000-dalton region of a sodium dodecyl sulfate gel to be produced, while translation of the 20 S fraction preferentially directed the synthesis of polypeptides similar in size to the alpha and alpha' subunits of beta-conglycinin. Evidence that many of the 60,000-dalton polypeptides were related to glycinin and the high molecular weight 20 S translation products were related to beta-conglycinin was obtained by immunoprecipitation using monospecific antibodies against glycinin and beta-conglycinin, respectively. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the immunoprecipitated products revealed that the glycinin precursor region contained at least three different size components and that the family of glycinin precursors had larger apparent molecular weight (58,000-63,000) than the disulfide-linked complexes between acidic and basic glycinin subunits (57,000). Unlike the disulfide-linked glycinin complexes which were cleaved by disulfide reduction, glycinin precursors were insensitive to reducing agents. The alpha and alpha' subunits synthesized in vitro also had slightly larger apparent molecular weights than purified alpha and alpha' standards.     

Occurrence of mRNA for storage protein in dry soybean seeds

Poly(A)-containing RNA has been isolated from the cotyledons of soybean seeds by adsorption on a poly(U)-Sepharose column. Approximately 0.15% of the total soybean RNA applied bound to the column. The bound RNA (poly(A)-containing RNA) was shown to be mRNA by its ability to serve as template in a cell-free system derived from wheat germ. Poly(A)-containing RNA was polydisperse, migrating from approximately 50,000 to 700,000 daltons with a mean of 150,000 daltons in polyacrylamide gel electrophoresis. The size of the poly(A) portion of this RNA was in the range of 55 to 290 nucleotides. The adenylic acid content of the presumed poly(A) fragment was about 95%. The radioactive products of translation directed by the poly(A)-containing RNA in the wheat germ cell-free system were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by immunoprecipitation using antisera against beta-conglycinin and glycinin. The results of this investigation show that mRNAs for the subunit proteins of the major components of a soybean storage protein exist in the poly(A)-containing RNA preparation obtained from the cotyledons of dry soybean seeds.     

Proteome rebalancing in soybean seeds can be exploited to enhance foreign protein accumulation

Seeds possess a high intrinsic capacity for protein production that makes them a desirable bioreactor platform for the manufacture of transgenic products. One strategy to enhance foreign protein production involves exchanging the capacity to produce intrinsic proteins for the capacity to produce a high level of foreign proteins. Suppression of the alpha/alpha' subunit of beta-conglycinin storage protein synthesis in soybean has been shown previously to result in an increase in the accumulation of the glycinin storage protein, some of which is sequestered as proglycinin into de novo endoplasmic reticulum (ER)-derived protein bodies. The exchange of glycinin for conglycinin is quantitative, with the remodelled soybeans possessing a normal protein content with an altered proteome. The green fluorescent protein (GFP)-kdel reporter was transferred in a construct using the glycinin promoter and terminator to mimic glycinin gene expression. When expressed in soybean seeds, GFP-kdel accreted to form ER-derived protein bodies. The introgression of GFP-kdel into the alpha/alpha' subunit of the beta-conglycinin suppression background resulted in a fourfold enhancement of GFP-kdel accumulation to > 7% (w/w) of the total protein in soybean seeds. The resulting seeds accumulated a single population of ER membrane-bound protein bodies that contained both GFP-kdel and glycinin. Thus, the collateral proteome rebalancing that occurs with the suppression of intrinsic proteins in soybean can be exploited to produce an enhanced level of foreign proteins.     

The effect of pH on heat denaturation and gel forming properties of soy proteins

This study is focussed on the influence of pH on the gel forming properties of soy protein isolate and purified glycinin in relation to denaturation and aggregation. At pH 7.6 more fine-stranded gels were formed characterised by low G' values, and a smooth, slightly turbid appearance, whereas at pH 3.8 coarse gels were obtained with a high stiffness and a granulated, white appearance. Low G' values, as found at pH 7.6, correlate with a high solubility of glycinin and soy protein isolate (ca. 50%) after heating at low protein concentration. At pH 3.8 all protein precipitated upon heating, which correlates with relatively high G' values. The role of beta-conglycinin during gelation of SPI seems to be minor at pH 7.6, which is indicated by the fact that, in contrast to pH 3.8, notable gel formation did not start upon heat denaturation of beta-conglycinin. Furthermore, the mechanism of gel formation seems to be affected by pH, because at pH 7.6, in contrast to pH 3.8, the disulphide bridge between the acidic and the basic polypeptide of glycinin is broken upon heating.     

Cosuppression of the alpha subunits of beta-conglycinin in transgenic soybean seeds induces the formation of endoplasmic reticulum-derived protein bodies

The expression of the alpha and alpha' subunits of beta-conglycinin was suppressed by sequence-mediated gene silencing in transgenic soybean seed. The resulting seeds had similar total oil and protein content and ratio compared with the parent line. The decrease in beta-conglycinin protein was apparently compensated by an increased accumulation of glycinin. In addition, proglycinin, the precursor of glycinin, was detected as a prominent polypeptide band in the protein profile of the transgenic seed extract. Electron microscopic analysis and immunocytochemistry of maturing transgenic soybean seeds indicated that the process of storage protein accumulation was altered in the transgenic line. In normal soybeans, the storage proteins are deposited in pre-existing vacuoles by Golgi-derived vesicles. In contrast, in transgenic seed with reduced beta-conglycinin levels, endoplasmic reticulum (ER)-derived vesicles were observed that resembled precursor accumulating-vesicles of pumpkin seeds and the protein bodies accumulated by cereal seeds. Their ER-derived membrane of the novel vesicles did not contain the protein storage vacuole tonoplast-specific protein alpha-TIP, and the sequestered polypeptides did not contain complex glycans, indicating a preGolgi and nonvacuolar nature. Glycinin was identified as a major component of these novel protein bodies and its diversion from normal storage protein trafficking appears to be related to the proglycinin buildup in the transgenic seed. The stable accumulation of proteins in a protein body compartment instead of vacuolar accumulation of proteins may provide an alternative intracellular site to sequester proteins when soybeans are used as protein factories.     

Identification of marker proteins for the adulteration of meat products with soybean proteins by multidimensional liquid chromatography-tandem mass spectrometry

Soybean proteins are frequently added to processed meat products for economic reasons and to improve their functional properties. Monitoring of the addition of soybean protein to meat products is of high interest due to the existence of regulations forbidding or limiting the amount of soybean proteins that can be added during the processing of meat products. We have used chromatographic prefractionation on the protein level by perfusion liquid chromatography to isolate peaks of interest from extracts of soybean protein isolate (SPI) and of meat products containing SPI. After enzymatic digestion using trypsin, the collected fractions were analyzed by nanoflow liquid chromatography-tandem mass spectrometry. Several variants and subunits of the major seed proteins, glycinin and beta-conglycinin, were identified in SPI, along with two other proteins. In soybean-protein-containing meat samples, different glycinin A subunits could be identified from the peak discriminating between samples with and without soybean proteins added. Among those, glycinin G4 subunit A4 was consistently found in all samples. Consequently, this protein (subunit) can be used as a target for new analytical techniques in the course of identifying the addition of soybean protein to meat products.     

Improved isolation method and some properties of soybean gamma-conglycinin

Soybean gamma-conglycinin was isolated by isoelectric precipitation and ammonium sulphate fractionation. The crude protein was purified by ion-exchange chromatography on DEAE-Sepharose CL-6B and gel filtration on Sepharose CL-6B. The purified gamma-conglycinin was homogeneous on two kinds of gel electrophoresis and an ultracentrifugal analysis. A subunit band, distinguishable from other subunit bands of beta-conglycinin and glycinin, was detected by sodium dodecyl sulphate electrophoresis. Amino acid composition was similar to those of the other storage proteins of soybean. Some physical properties were also studied.     

Molecular and structural analysis of electrophoretic variants of soybean seed storage proteins

Soybean (Glycine max L.) storage proteins are composed mainly of two major components, beta-conglycinin and glycinin. Electrophoretic variants of the beta subunit of beta-conglycinin and the A3 polypeptide of glycinin were detected on SDS-PAGE, and designated them as beta* and A3*, respectively. beta* and A3* exhibited higher and lower mobilities, respectively, than the common beta subunit and A3 polypeptide. The N-terminal nine and 10 amino acid sequences of beta* and A3* were completely identical to the previously reported sequences of the beta subunit and the A3 polypeptide, respectively. Analysis using concanavalin A-horseradish peroxidase and treatment with N-glycosidase indicated that glycans were not responsible for the difference in electrophoretic mobility of beta* or A3*. Furthermore, five clones of beta* or beta and three clones of A3*, respectively, were sequenced but we could not detect deletions and insertions except for a single or a few amino acid substitutions as compared with the common beta subunit and A3 polypeptide. These results indicate that a single or a few amino acid substitution affects the electrophoretic mobilities of beta* and A3*.     

The effects of different inactivating agents on the potency, toxicity and stability of pertussis vaccine

The effect of heat (56 degrees C for 10 min), formaldehyde (0.1% at 37 degrees for 24h), glutaraldehyde (0.05% at room temperature for 10 min), thimerosal (0.02% at 37 degrees C for 24h), acetone-I (three treatments at room temperature) and acetone-II (three treatments at room temperature and fourth treatment at 37 degrees C), when used as inactivating agents in the preparation of pertussis suspension, was studied with regard to potency, toxicity and stability. Five batches each of Bordetella pertussis strains 134 and 509 were used for the study. The thimerosal inactivated pertussis (TIP) preparation was 1.5-2 times more potent than the heat inactivated pertussis (HIP) preparation. The potency values of the formaldehyde inactivated pertussis (TIP) and glutaraldehyde inactivated pertussis (GIP) preparations were similar to those of the HIP preparation, while the potencies of the acetone-I treated pertussis (A(I)TP) and acetone-II treated pertussis (A(II)TP) preparations were about half those of the HIP preparation. The FIP preparation was the least toxic showing maximum weight gain in the mouse weight-gain test (MGWT), while the TIP preparation did not pass the MWGT. The weight gains shown the GIP, A(I)TP and A(II)TP preparations were greater than those shown by the HIP preparation. The potency of pertussis component in the adsorbed diphtheria-pertussis-tetanus (DPT) vaccine was stable at 4-8 degrees C and 25 degrees C for three months for all types of pertussis vaccine. There was about 54-65% loss in the potency of the samples after three months at 35 degrees C. The inactivating agents used in the manufacture of pertussis preparations had no effect on the stability of the vaccine.     

Processing and assembly in vitro of engineered soybean beta-conglycinin subunits with the asparagine-glycine proteolytic cleavage site of 11S globulins

A short interdomain sequence between the N- and C-terminal domains of beta-conglycinin, the major 7S seed storage protein of soybean, was selected as a target for insertion of amino acid residues specifically cleaved by an asparaginyl endopeptidase that processes globulins into acidic and basic chains. Modified beta-conglycinin subunits containing the proteolytic cleavage site self-assembled into trimers in vitro at an efficiency similar to that of the unmodified subunit. In contrast to the absence of cleavage of the unmodified subunits, however, the modified beta-conglycinin trimers were processed by purified soybean asparaginyl endopeptidase into two polypeptides, each the size expected for the beta-conglycinin N- and C-terminal domains, respectively. The cleavage did not alter the assembly of mutant beta-conglycinins and the cleaved mutant trimers remained stable to further proteolytic attack. To examine the possibility of coassembly between the cleaved 11S and 7S subunits, in vitro processed mutant beta-conglycinin subunits were mixed with native dissociated 11S globulin preparations. Reassembly at a high ionic condition did not induce the 7S subunits to interact with 11S subunits to form hexameric complexes. Thus, cleavage of 7S globulin subunits into acidic and basic domains may not be sufficient for hexamer assembly to occur. Biotechnological implications of the engineered proteins are discussed.     

Purification and reconstitution of the proton-pumping ATPase of fungal and plant plasma membranes

The 11S storage protein (glycinin) of soybean [Glycine max (L.) Merr., cv. Raiden] was studied by polyacrylamide gel electrophoresis and amino acid sequence analysis. It contained the following subunits composed of acidic (A) and basic (B) polypeptides: A1aB2, A1bB1b, A2B1a, and A3B4. However, it lacked polypeptides A4, A5, and B3 which are present in many other cultivars. A new acidic polypeptide called A6 was present in a low amount and was characterized by amino acid sequence analysis. It was homologous to A4, although of a smaller apparent molecular weight. Since Raiden has an average protein content of about 40% and its glycinin fraction can be purified as a 350,000 D complex which is typical of other cultivars, the results imply polymorphism with respect to glycinin subunit composition. Because there is a wide variation in the methionine content of the various subunits, these findings suggest the possibility of genetically manipulating the nutritional quality of soybean seed protein by altering glycinin subunit composition.     

Thermal Versus High Hydrostatic Pressure Treatments on Calcium-added Soybean Proteins. Protein Solubility,Colloidal Stability and Cold-set Gelation

The effects of thermal treatment (TT) and high hydrostatic pressure treatment (HHPT) on calcium-added soybean protein 1% (w/w) aqueous dispersions at pH 7.0 were compared. High hydrostatic pressure, but not thermal treatment, improved protein solubility and colloidal stability. Despite the fact that the glycinin solubility is more affected by calcium than that of β-conglycinin, glycinin could remain in dispersion in the presence of calcium when denatured by HHPT (calcium added before or after treatment), but not when denatured by TT or without denaturing treatment. Thus, polypeptide composition of soluble aggregates depended on type of treatment. Colloidal stability and molecular weight of soluble aggregates depended on the order of application of calcium and denaturing treatment: when calcium was present during either HHPT or TT, the dispersions had higher stability and higher proportion of soluble aggregates with high molecular weight than when calcium was added after treatments. After freeze drying and re-dispersing at higher protein content (10% w/w) calcium-added dispersions subjected to HHPT formed cold-set gels that were transparent and exhibited excellent water holding capacity. Our results provide the basis for the development of ready-to-use functional ingredients.

     

Characterization of Blue-Green Fluorescence in the Mesophyll of Sugar Beet (Beta vulgaris L.) Leaves Affected by Iron Deficiency

Protease C1, an enzyme from soybean (Glycine max [L.] Merrill cv Amsoy 71) seedling cotyledons, was previously determined to be the enzyme responsible for the initial degradation of the alpha' and alpha subunits, but not the beta subunit, of beta-conglycinin storage protein. The sizes of the proteolytic products generated by the action of protease C1 suggest that the cleavage sites on the alpha' and alpha subunits of beta-conglycinin may be located in their N-terminal domain, which is not found in the beta subunit of beta-conglycinin. To check this hypothesis, storage proteins from other plant species that are homologous to either the alpha'/alpha or the beta subunit of beta-conglycinin were tested as substrates. As expected, the convicilin from pea (Pisum sativum), a protein homologous to the alpha' and alpha subunits of beta-conglycinin, was digested by protease C1. The vicilins from pea as well as vicilins from adzuki bean (Vigna angularis), garden bean (Phaseolus vulgaris), black-eyed pea (Vigna unguiculata), and mung bean (Vigna radiata), storage proteins that are homologous to the beta subunit of soybean beta-conglycinin, were not degraded by protease C1. Degradation of soybean beta-conglycinin involves a sequential attack of the alpha subunit at multiple sites, culminating in the formation of a stable intermediate of 53.5 kD and a final product of 48.0 kD. The cleavage sites resulting in this formation of the intermediates and final product were determined by N-terminal analysis. These were compared to the known amino acid sequences of the three beta-conglycinin subunits. Results showed these two polypeptides to be generated by proteolysis of the alpha subunit at regions bearing long strings of acidic amino acid residues.     

A new <Emphasis Type="Italic">Bacillus licheniformis</Emphasis> mutant strain producing serine protease efficient for hydrolysis of soy meal proteins

Induced mutagenesis with γ-irradiation of the industrial strain Bacillus licheniformis-60 VKM B-2366 D was used to obtain a new highly active producer of an extracellular serine protease, Bacillus licheniformis-145. Samples of dry concentrated preparations of serine protease produced by the original and mutant strains were obtained, and identity of their protein composition was established. Alkaline serine protease subtilisin DY was the main component of the preparations. The biochemical and physicochemical properties of the Protolicheterm-145 enzyme preparation obtained from the mutant strain were studied. It exhibited proteolytic activity (1.5 times higher than the preparation from the initial strain) within broad ranges of pH (5–11) and temperature (30–70°C). Efficient hydrolysis of extruded soybean meal protein at high concentrations (20 to 50%) in the reaction mixture was the main advantage of the Protolicheterm-145 preparation. Compared to the preparation obtained using the initial strain, the new preparation with increased proteolytic activity provided for more complete hydrolysis of the main non-nutritious anti-nutritional soy proteins (glycinin and β-conglycinin) with the yield of soluble protein increased by 19–28%, which decreased the cost of bioconversion of the proteinaceous material and indicated promise of the new preparation in resource-saving technologies for processing soybean meals and cakes.