Precursors to Nitrosopyrrolidine and Nitrosopiperidine in Black Pepper Treated with Nitrous Acid

The following properties of food proteins polymerized by guinea pig liver transglutaminase were investigated: (1) solubility, (2) emulsifying activity and emulsion stability, and (3) unfrozen water content by pulsed NMR. Several food proteins (α_sl- and k-caseins, and soybean 7S and 11S globulins) were polymerized by this enzyme. Solubility and emulsifying activity of polymerized α_sl-casein were higher than those of the native protein in the range of pH 4~6. Unfrozen water contents of polymerized soybean globulins were much higher than those of the native proteins. These results suggest that transglutaminase treatment may be used for the production of new food protein material with higher hydration ability.     

The Role of Copper in Protein Foams

Chefs have known that whipping egg white proteins (EWP) in a copper bowl will improve foam stability. The improved stability is attributed to a copper–conalbumin complex or alteration of sulfhydryl reactivity. Whey proteins bind copper and show copper-induced changes in disulfide bonds; therefore, they may also be responsive to whipping in a copper bowl. EWP and whey protein isolate (WPI) solutions were whipped in the presence of 1 mM CuSO₄ or in a copper bowl with and without sugar followed by overrun and yield stress measurements and angel food cake formation. Dilational elasticity and surface tension were also measured for WPI solutions. Whipping in a copper bowl or adding 1 mM CuSO₄ significantly improved stability of EWP foams while having no effect on WPI foams. Copper caused disulfide-linked dimer formation of β-lactoglobulin and decreased dilational elasticity and surface tension, but these modifications were insufficient to change the bulk properties of foams. The addition of 10 mM CuSO₄ to WPI solutions was sufficient to increase foam stability to levels similar to EWP; however, the more stable foams formed less stable cakes. It was concluded that the effect of whipping in a copper bowl on foam properties is mainly dependent on the specific proteins forming the foam. Paper no. FSR-07-29 of the Journal Series of the Department of Food Science, North Carolina State University, Raleigh, NC 27695-7624. Presented at the 2nd International Symposium: Delivery of Functionality in Complex Food Systems: Physically-inspired Approaches From Nanoscale to Microscale, October 8–10, 2007.     

Physicochemical Properties and Specific Structural Features of Protein–Lipid Composites of Increased Nutritive Value

Fractional and component compositions of protein–lipid composites with increased nutritive value (compared to the protein preparations from which they were produced) were studied based on solubility and electrophoretic behavior. Differences in the fractional compositions of proteins and the amounts of hydrogen, ionic, and hydrophobic bonds were found. It was demonstrated that the water-, salt-, and alkali-soluble fractions of proteins changed during the manufacturing of the composites with soybean and wheat bran flour; the water- and alkali-soluble fractions, with protein concentrate from bran. Heterogeneity of the compositions and specific conformational features of composite proteins resulting from disulfide bonds were found. It was demonstrated that, during the manufacturing of composites, proteins of soybean flour aggregated (with the involvement of disulfide bonds), whereas protein products from wheat bran disaggregated. Breaks of interchain (wheat) or intrachain (concentrate) disulphide bonds accompanied the disaggregation. Overall the properties and specific structural features of the protein–lipid composites studied depended on the nature of the protein (soybean or wheat), type of initial preparations (flour or concentrate), and method of their production (emulsifying or drying).     

Physicochemical properties and specific structural features of protein-lipid composites of increased nutritive value

Fractional and component compositions of protein-lipid composites with increased nutritive value (compared to the protein preparations from which they were produced) were studied based on solubility and electrophoretic behavior. Differences in the fractional compositions of proteins and the amounts of hydrogen, ionic, and hydrophobic bonds were found. It was demonstrated that the water-, salt-, and alkali-soluble fractions of proteins changed during the manufacturing of the composites with soybean and wheat bran flour; the water- and alkali-soluble fractions, with protein concentrate from bran. Heterogeneity of the compositions and specific conformational features of composite proteins resulting from disulfide bonds were found. It was demonstrated that, during the manufacturing of composites, proteins of soybean flour aggregated (with the involvement of disulfide bonds), whereas protein products from wheat bran disaggregated. Breaks of interchain (wheat) or intrachain (concentrate) disulphide bonds accompanied the disaggregation. Overall the properties and specific structural features of the protein-lipid composites studied depended on the nature of the protein (soybean or wheat), type of initial preparations (flour or concentrate), and method of their production (emulsifying or drying).     

Evaluation of physicochemical and antioxidant properties of peanut protein hydrolysate

Peanut protein and its hydrolysate were compared with a view to their use as food additives. The effects of pH, temperature and protein concentration on some of their key physicochemical properties were investigated. Compared with peanut protein, peanut peptides exhibited a significantly higher solubility and significantly lower turbidity at pH values 2-12 and temperature between 30 and 80°C. Peanut peptide showed better emulsifying capacity, foam capacity and foam stability, but had lower water holding and fat adsorption capacities over a wide range of protein concentrations (2-5 g/100 ml) than peanut protein isolate. In addition, peanut peptide exhibited in vitro antioxidant properties measured in terms of reducing power, scavenging of hydroxyl radical, and scavenging of DPPH radical. These results suggest that peanut peptide appeared to have better functional and antioxidant properties and hence has a good potential as a food additive.     

The influence of kosmotropic and chaotropic salts on the functional properties of Mucuna pruriens protein isolate

The influence of chaotropic and kosmotropic salts on Mucuna pruriens protein isolates was investigated. Protein solubility profile indicated that solubility was minimal at the isoelectric point of the protein isolate (4.0) while the solubility was maximal at pH 10.0 in all salt solutions. Chaotropes (I(-), ClO(4)(-) and SCN(-)) exhibit better protein solubility than the kosmotropes (SO(4)(2-), Cl(-) and Br(-)). Increase in protein solubility follows the Hofmeister series: NaSO(4)相似文献   

Effect of the application of selenium on selenium content of soybean and its products

Two experiments were conducted to study the effect of the application of selenium on the selenium content of soybean and its products in two counties with selenium-deficient soil. Selenium-enriched soybean was produced by the application of sodium selenite and Se-enriched fertilizer. The selenium contents of soybeans, soybean protein and okra were determined by hydride-generation atomic fluorescence spectrometry. The results showed that the selenium contents of soybean, soybean protein, and okra were significantly increased by the application of sodium selenite and selenium-enriched fertilizer. Foliar application of selenium provided a higher efficiency for increasing the selenium content of soybean than soil application. Significant differences were found in that soybean cultivars exhibited different accumulation of selenium. There was no remarkable difference in soybean yield, soybean protein, and lipid between selenium and control. The selenium-enriched protein derived from selenium-enriched soybean could be used as a functional ingredient and soybean okra as a selenium-enriched feed for animals for increasing selenium intake.     

Utilization of Soybean Products in Fish Paste Products

Large amounts of food-grade soybean products are consumed in fish product industries in Japan. To clarify the properties of soybean products desirable for fish processing, the kamaboko added with soybean products were evaluated by both sensory testing and instrumental measurements. The correlation between the suitability of soybean products for kamaboko and the basic chemical and functional properties of the soybean products was discussed. It was found that the “hardness” of the kamaboko added with soybean products correlated highly with the degree of denaturation of soy protein and with the amount of nitrogen of soybean products not dispersible in 3% sodium chloride aqueous solution.

It was also estimated that the textural properties of kamaboko added with soybean products could not be deduced from the textural properties of heat-coagulated gels of the corresponding soybean products.     

A new corn fiber gum polysaccharide isolation process that preserves functional components

Corn fiber gum (CFG) is a hemicellulose (arabinoxylan)-enriched fraction obtained by the extraction of corn bran/fiber using a mild alkaline hydrogen peroxide process. The unique polysaccharide, CFG, with its low solution viscosity has been proposed as a stabilizer for oil-in-water emulsions. We have verified that in some model systems, CFG can out-perform the “gold standard” emulsifier, gum arabic. Our results have also shown that “pure” CFG fractions often contain considerable amounts of associated lipids, phenolic acids and proteins which contribute to its emulsifying properties. The extraction of CFG with alkaline hydrogen peroxide was investigated using different combinations of alkali concentration and time to identify the optimum extraction condition to retain its functional groups (protein, lipids and phenolic acids). The pure CFG prepared by this process was hydrolyzed with 1.5 N methanolic KOH at 70 °C for 1 h to release hydroxycinnamic acids (p-coumaric and ferulic) and lipids. The total lipid was extracted with chloroform/methanol, evaporated and quantified. The released phenolic acids were identified and quantified using HPLC with detection by both UV and evaporative light-scattering detection (ELSD). The protein content was determined by an AACC approved combustion method. The total lipids, phenolic acids and protein content in CFGs isolated with lower alkali concentration for a shorter time was comparatively higher than CFGs isolated with higher alkali concentration for a longer time. The presence of these phenolic acids, lipids and protein in CFG may contribute to its excellent emulsifying properties and may combine to give improved chemical, physical, and even nutritional properties. Understanding these critical structural elements required for optimal emulsification properties will allow future commercial producers of CFG to provide consistent quality and functionality in their products.     

Superfine grinding of steam-exploded rice straw and its enzymatic hydrolysis

The combination of low severity steam explosion and superfine grinding has been studied with respect to side products generation and enzymatic hydrolysis efficiency. Chemical compositions, fiber characteristics and composed cells contents in the superfine ground product and the ground residue particles produced by superfine grinding were also studied. At the determined parameters using FJM-200 fluidized bed opposed jet mill, 78% superfine ground steam-exploded rice straw (SERS) products with the mean fiber length of 60 μm were obtained, the particles yield was 179% higher than that from the native rice straw (RS). Enzymatic hydrolysis, chemical composition, fiber characteristics and composed cells proportion of the superfine ground SERS product and the ground residue all show great differences. The difference in enzymatic hydrolysis and structural properties indicates that superfine grinding is a good way to fractionate SERS into easily bio-converted part and difficultly hydrolysed part.     

Pea,Chickpea and Lentil Protein Isolates: Physicochemical Characterization and Emulsifying Properties

This work is focused on physicochemical and emulsifying properties of pea (PP), chickpea (CP) and lentil (LP) proteins. We evaluated the molecular weight distributions, surface net charge, free sulfhydryl group (SH) and disulfide bond (SS) contents, protein solubility and thermal stability of the protein isolates. Their emulsifying properties (droplet size distribution, flocculation, coalescence and creaming) were also determined as function of pH values. The three protein isolates exhibit similar physicochemical properties, including good solubility and high thermal stability despite a high degree of denaturation. In addition, we analysed the influence of pH on stability of oil-in-water (O/W; 10 wt%/90 wt%) emulsions stabilized by the legume protein isolates. Concerning emulsifying ability and stability, the most unfavourable results for all three protein isolates relate to their isoelectric point (pI?=?4.5). A significant improvement in emulsion stability takes place as the pH value departs from the pI. Overall, this study indicates that pea, chickpea and lentil proteins have great potential as food emulsifiers.     

Mechanical and water soaking properties of medium density fiberboard with wood fiber and soybean protein adhesive

Soybean protein is a renewable and abundant material that offers an alternative to formaldehyde-based resins. In this study, soybean protein was modified with sodium dodecyl sulfate (SDS) as an adhesive for wood fiber medium density fiberboard (MDF) preparation. Second-order response surface regression models were used to study the effects and interactions of initial moisture content (IMC) of coated wood fiber, press time (PT) and temperature on mechanical and water soaking properties of MDF. Results showed that IMC of coated fiber was the dominant influencing factor. Mechanical and soaking properties improved as IMC increased and reached their highest point at an IMC of 35%. Press time and temperature also had a significant effect on mechanical and water soaking properties of MDF. Second-order regression results showed that there were strong relationships between mechanical and soaking properties of MDF and processing parameters. Properties of MDF made using soybean protein adhesive are similar to those of commercial board.     

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.     

The Active Component of the Bioemulsifier Alasan from Acinetobacter radioresistens KA53 Is an OmpA-Like Protein

The bioemulsifier of Acinetobacter radioresistens KA53, referred to as alasan, is a high-molecular-weight complex of polysaccharide and protein. Recently, one of the alasan proteins, with an apparent molecular mass of 45 kDa, was purified and shown to constitute most of the emulsifying activity. The N-terminal sequence of the 45-kDa protein showed high homology to an OmpA-like protein from Acinetobacter spp. In the research described here the gene coding for the 45-kDa protein was cloned, sequenced, and expressed in Escherichia coli. Recombinant protein AlnA (35.77 kDa without the leader sequence) had an amino acid sequence homologous to that of E. coli OmpA and contained 70% of the specific (hydrocarbon-in-water) emulsifying activity of the native 45-kDa protein and 2.4 times that of the alasan complex. In addition to their emulsifying activity, both the native 45-kDa protein and the recombinant AlnA were highly effective in solubilizing phenanthrene, ca. 80 microg per mg of protein, corresponding to 15 to 19 molecules of phenanthrene per molecule of protein. E. coli OmpA had no significant emulsifying or phenanthrene-solubilizing activity. The production of a recombinant surface-active protein (emulsification and solubilization of hydrocarbons in water) from a defined gene makes possible for the first time structure-function studies of a bioemulsan.     

Expression of the soybean allergenic protein P34 in Escherichia coli and its indirect ELISA detection method

To detect the soybean allergen P34 (Gly m Bd 30K) from soybean products, the full-length cDNA sequence of P34 was synthesized and inserted into the prokaryotic expression vector pET-28a. The P34 protein was expressed in Escherichia coli BL21 (DE3) as an inclusion body under the induction of 0.8 mmol/L isopropyl β-D-1-thiogalactopyranoside. After purification with His-Bind affinity chromatography, the purity quotient of the recombinant protein was over 92 %, and its molecular weight (approximately 33 kDa) was very close to that of the native soybean P34. The polyclonal antibody (pAB) against P34 was prepared with the purified recombinant P34. The generated pAB, named as pAB-P34, exhibited high specificity to the P34 protein of the soybean meal. The indirect enzyme-linked immunosorbent assay (iELISA) based on pAB-P34 was established to determine the P34 content of soybean products. The CVs of the recovery tests of P34 were less than 7.77 %, which indicated that iELISA had high reproducibility and accuracy. Therefore, the recombinant P34 produced in the E. coli expression system, the prepared pAB-P34, and the developed iELISA could provide a valuable tool for sensitive detection of P34 in various soybean products and for future studies on allergies related to soybean P34.     

Reconstitution of emulsifying activity of Acinetobacter calcoaceticus BD4 emulsan by using pure polysaccharide and protein

Acinetobacter calcoaceticus BD4 and BD413 produce extracellular emulsifying agents when grown on 2% ethanol medium. For emulsifying activity, both polysaccharide and protein fractions were required, as demonstrated by selective digestion of the polysaccharide with a specific bacteriophage-borne polysaccharide depolymerase, deproteinization of the extracellular emulsifying complex with hot phenol, and reconstitution of emulsifier activity with pure polysaccharide and a polysaccharide-free protein fraction. Chemical modification of the carboxyl groups in the polysaccharide resulted in a loss of activity. The protein required for reconstitution of emulsifying activity was purified sevenfold. The BD4 emulsan apparently derives its amphipathic properties from the association of an anionic hydrophilic polysaccharide with proteins.     

Reconstitution of emulsifying activity of Acinetobacter calcoaceticus BD4 emulsan by using pure polysaccharide and protein.

Acinetobacter calcoaceticus BD4 and BD413 produce extracellular emulsifying agents when grown on 2% ethanol medium. For emulsifying activity, both polysaccharide and protein fractions were required, as demonstrated by selective digestion of the polysaccharide with a specific bacteriophage-borne polysaccharide depolymerase, deproteinization of the extracellular emulsifying complex with hot phenol, and reconstitution of emulsifier activity with pure polysaccharide and a polysaccharide-free protein fraction. Chemical modification of the carboxyl groups in the polysaccharide resulted in a loss of activity. The protein required for reconstitution of emulsifying activity was purified sevenfold. The BD4 emulsan apparently derives its amphipathic properties from the association of an anionic hydrophilic polysaccharide with proteins.     

Isolation and Identification of 6-Methylsalcylic Acid and Gentisyl Alcohol from Phyllosticta sp.

Bovine serum albumin was reduced by incubating with various concentrations (0–200 mM) of 2-mercaptoethanol, and its emulsifying properties were examined for an oil-in-water emulsion system. A particle size analysis revealed that albumin reduced at 30 mM of the thiol yielded smaller oil particles than either native protein, or the protein reduced at 70 or 200 mM of the thiol. Furthermore, the particle size was almost constant during 35 days of storage with albumin reduced at 30 mM of the thiol, while an emulsion prepared using the native protein, or the protein reduced at 70 or 200 mM of the thiol was unstable during the same storage period. Gel filtration chromatography and transmission electron micrography show that serum albumin made aggregates with high molecular size by its disulfide reduction with 70 or 200 mM, but not with 30 mM of 2-mercaptoethanol. It was, therefore, concluded that the emulsifying property of serum albumin can be improved by a mild disufide reduction.     

Enzymatic modification of yeast protein isolates

Yeast protein isolate with 85% of pure protein and 1.2% of nucleic acids in dry matter was isolated from Saccharomyces cerevisiae by a procedure of two pre-treatment steps, acidic extraction and isoelectric precipitation. The application of this yeast protein isolate was limited by its functionality resulting from the partially extreme isolating conditions. An enzymatic partial hydrolysis with Thermitase to a degree of hydrolysis of 5% not only improved the solubility and foaming properties, but also the water binding capacity and the emulsifying properties. The hydrolysate was free of bitter taste and could be applied either in two fractions of different solubility after centrifugation or as a whole product in food systems to improve the physiological and functional quality. The yeast protein hydrolysate had the same or even better properties than conventional protein products.     

Studies on Amino Acid Contents of Processed Soybean

The influence of sugars on the heat destruction of the basic and sulphur containing amino acids of soybean products, soybean protein and also pure amino acids has been investigated.

Amino acids were estimated by microbiological assay procedure. Cystine was also determined chromatographically.

Lysine, arginine and histidine were destroyed in different ways behaved when soybean products, soybean protein or pure amino acids mixed with and without sugars were autoclaved; and the condition of added sugars tended to influence the way of destruction.

Cystine was the most heat-labile amino acid. But the destruction did not appear to be ascribed to added sugars except 50% ethyl alcohol-soluble sugar solution of defatted soybean flour. This finding was also substantiated by the chromatographic analysis.

Methionine, in soybean products and soybean protein or as pure amino acid with and without the addition of sugars, was not influenced by autoclaving.