Michael G. Zeece

Soybean glycinin G1 acidic chain shares IgE epitopes with peanut allergen Ara h 3

Background: The identification of IgE epitopes for proteins is the first step in understanding the interaction of allergens with the immune system. Proteins from the legume family have shown in vitro cross-reactivity in IgE-binding assays, but this cross-reactivity is rarely clinically significant. Resolution of this discrepancy requires IgE epitope mapping of legume family protein allergens. Methods: We constructed six fusion proteins representing overlapping regions of soybean glycinin G1 acidic chain. These fusion proteins were used in immunoblotting and a novel sandwich ELISA with pooled sera from soy-allergic individuals to reveal a common IgE-binding region. This region was the focus for IgE epitope mapping using overlapping synthetic peptides. Results: Data from the fusion protein experiments revealed an IgE-binding region consisting of residues F192–I265. Analysis of the overlapping synthetic peptides to this region indicated that IgE epitopes to glycinin G1 acidic chain consist of residues G217–V235 and G253–I265. The epitopes identified for glycinin G1 acidic chain are homologous to IgE epitopes previously identified for the peanut allergen Ara h 3 [1]. However, residues identified by alanine scanning in the peanut epitopes as being important for IgE binding are different in the natural soybean epitopes. Conclusions: The IgE epitopes identified for glycinin G1 acidic chain apparently represent an allergenic region of several legume family seed storage proteins. Our findings indicate that the identification of IgE epitopes and structural analysis of legume family proteins will provide valuable information to the study of food allergies.

Analysis of resveratrol in wine by capillary electrophoresis

Capillary electrophoresis (CE) is a new analytical technique that has recently been reported as a method for analysis of resveratrol in wine. Several different separation approaches have been taken in these reports. In comparison with high-performance liquid chromatography (HPLC), CE methods have similar sensitivity and can discriminate between trans- and cis-isomers of resveratrol. CE methods also show promise for analysis of other flavonoid antioxidants (glycosides and aglycones) in wine.

Identification of IgE-Binding Proteins in Soy Lecithin

Background: Soy lecithin is widely used as an emulsifier in processed foods, pharmaceuticals and cosmetics. Soy lecithin is composed principally of phospholipids; however, it has also been shown to contain IgE-binding proteins, albeit at a low level. A few clinical cases involving allergic reactions to soy lecithin have been reported. The purpose of this investigation is to better characterize the IgE-binding proteins typically found in lecithin. Methods: Soy lecithin proteins were isolated following solvent extraction of lipid components and then separated on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). The separated lecithin proteins were immunoblotted with sera from soy-sensitive individuals to determine the pattern of IgE-binding proteins. The identity of IgE-reactive bands was determined from their N-terminal sequence. Results: The level of protein in six lecithin samples obtained from commercial suppliers ranged from 100 to 1,400 ppm. Lecithin samples showed similar protein patterns when examined by SDS-PAGE. Immunoblotting with sera from soy-sensitive individuals showed IgE binding to bands corresponding to 7, 12, 20, 39 and 57 kD. N-terminal analysis of these IgE-binding bands resulted in sequences for 3 components. The 12-kD band was identified as a methionine-rich protein (MRP) and a member of the 2S albumin class of soy proteins. The 20-kD band was found to be soybean Kunitz trypsin inhibitor. The 39-kD band was matched to a soy protein with unknown function. Conclusions: Soy lecithin contains a number of IgE-binding proteins; thus, it might represent a source of hidden allergens. These allergens are a more significant concern for soy-allergic individuals consuming lecithin products as a health supplement. In addition, the MRP and the 39-kD protein identified in this study represent newly identified IgE-binding proteins.

Identification and analysis of a conserved immunoglobulin E-binding epitope in soybean G1a and G2a and peanut Ara h 3 glycinins.

To identify conserved immunoglobulin E (IgE)-binding epitopes among legume glycinins, we utilized recombinant soybean G2a and G2a-derived polypeptide fragments. All of these fusion polypeptides bound IgE, and the C-terminal 94-residue fragment appeared to bind more IgE. Using synthetic peptides we identified S219-N233 (S(219)GFAPEFLKEAFGVN(233)) as the dominant IgE-binding epitope. Alanine scanning of this epitope indicated that six amino acids (E224, F225, L226, F230, G231, and V232) contributed most to IgE binding. Among these amino acids, only G231 of soybean G2a is not conserved in soybean G1a (S234) and peanut Ara h 3 (Q256). Synthetic peptides corresponding to the equivalent regions in G1a and Ara h 3 bound IgE in the order Ara h 3>/=soybean G2a>soybean G1a. This sequence represents a new IgE-binding epitope that occurs in a highly conserved region present in legume glycinins. Such IgE-binding sites could provide a molecular explanation for the IgE cross-reactivity observed between soybean and peanut proteins.

Reversible denaturation of the soybean Kunitz trypsin inhibitor

The soybean Kunitz trypsin inhibitor (SKTI) is a beta-sheet protein with unusual stability to chemical and thermal denaturation. Different spectroscopic criteria were used to follow the thermal denaturation and renaturation of SKTI. Upon heating to 70 degrees C, changes in UV difference spectra showed increased absorbance at 292 and 297 nm, attributable to perturbation of aromatic residues. Cooling the protein resulted in restoration of the native spectrum unless reduced with dithiothreitol. Far- and near-UV CD spectra also indicate thermal unfolding involving the core tryptophan and tyrosine residues. Both CD and UV-absorbance data suggest a two-state transition with the midpoint at approximately 65 degrees C. CD data along with the increased fluorescence intensity of the reporter fluorophore, 1-anilino-8-naphthalenesulfonate with SKTI, between 60 and 70 degrees C, are consistent with a transition of the native inhibitor to an alternate conformation with a more molten state. Even after heating to 90 degrees C, subsequent cooling of SKTI resulted in >90% of native trypsin inhibition potential. These results indicate that thermal denaturation of SKTI is readily reversible to the native form upon cooling and may provide a useful system for future protein folding studies in the class of disordered beta-sheet proteins.

Determination of native folates in milk and other dairy products by high-performance liquid chromatography

Folates were measured in dairy products by high-performance liquid chromatography without prior sample clean-up. Detection limits for individual folates range from 0.3 to 7.3 ng/g. The folates were extracted from the sample matrix by adjusting the pH to 4.5 with acetic acid, centrifuging to remove precipitated proteins, and treating with conjugase to remove multiple polyglutamate residues. Folates were separated from other sample components using a reversed-phase column with a methanol-phosphate buffer (pH 6.8), and ion-pairing with tetrabutylammonium ion. Fluorescence was found to be the most useful detection technique. Fluorescence detection of reduced forms of the vitamin was achieved by post-column pH adjustment of the eluent with phosphoric acid, while the parent folic acid molecule required chemical oxidation with hypochlorite in order to obtain a fluorescent response.

Identification of an IgE-binding region in soybean acidic glycinin G1

The acidic polypeptide chain of soybean glycinin G1 was identified as one of the several IgE-binding proteins by immuno-blotting with pooled sera from soy-allergic individuals. The region of IgE-binding within glycinin G1 was narrowed by in situ digestion with endoproteinase GluC followed by immuno-blotting of peptide products. This procedure resulted in a single IgE-binding fragment of approximately 15 kDa corresponding to residues 192 to 306 of the acidic chain of glycinin G1.

Capillary electrophoresis: a new analytical tool for food science

Abstract Capillary electrophoresis (CE) is a new technology for the separation of molecules on the basis of their intrinsic charge. A wide range of methods, including free solution electrophoresis, isoelectric focusing and isotachophoresis, is available for the separation and quantification of many biomolecules. The combination of efficiency, sensitivity and speed of separation promises to make CE widely used in the analysis of a variety of compounds found in food systems.

Analysis of endoproteinase Arg C action on adrenocorticotrophic hormone by capillary electrophoresis and reversed-phasse high-performance liquid chromatography☆

The specificity and rate of cleavage of adrenocorticotrophic hormone (ACTH) peptide bonds by endoproteinase Arg C were analyzed using capillary electrophoresis (CE) and reversed-phase (C18) high-performance liquid chromatography (HPLC). Acidic cleavage products were readily resolved by CE in uncoated capillaries using low ionic strength electrolytes. However, products predicted to have a net positive charge greater than 2 or more than 4 positively charged groups per peptide did not migrate out from the capillary at low ionic strength. Addition of salts and zwitterions to the electrolyte decreased capillary-peptide interactions such that all of the ACTH peptides examined were eluted with high efficiency separation by CE. Commercially obtained endoproteinase Arg C preparations exhibited peptidase activity at Lys-15-Lys16 and at Lys16-Arg17 in addition to the expected cleavage at Arg-X bonds. ACTH peptide bond cleavage rates for Arg8-Trp9, Arg17-Arg-18, Lys15-Lys16, and Lys16-Arg17 were 1.46, 0.096, 0.57, and 0.029 mumol min-1 mg-1 respectively. CE separations generally exhibited better resolution and were accomplished in shorter times than C18 HPLC separations. These properties make CE a particularly appropriate method for kinetic analysis of proteolytic enzyme action on peptide substrates.

P39, a novel soybean protein allergen, belongs to a plant-specific protein family and is present in protein storage vacuoles

Soybean lecithins are seeing increasing use in industry as an emulsifier and food additive. They are also a growing source of human food allergies, which arise principally from the proteins fractionating with the lecithin fraction during manufacture. A previous study (Gu, X.; Beardslee, T.; Zeece, M.; Sarath, G.; Markwwell, J. Int Arch. Allergy Immunol. 2001, 126, 218-225) identified several allergenic proteins in soybean lecithins and a soybean IgE-binding protein termed P39 was discovered. However, very little was known about this protein except that it was coded by the soybean genome. This paper investigates key biological and immunological properties of this potential soybean lecithin allergen. P39 is encoded by a multigene family in soybeans and in several other higher plants. The soybean P39-1 protein and its essentially indistinguishable homologue, P39-2, have been cloned and studied. These proteins and their homologues belong to a family of plant-specific proteins of unknown function. In soybeans, P39-1 is seed specific, and its transcript levels are highest in developing seeds and decline during seed maturation. In contrast, P39 protein was detectable only in the fully mature, dry seed. Subcellular fractionation revealed that P39 protein was strongly associated with oil bodies; however, immunolocalization indicated P39 was distributed in the matrix of the protein storage vacuoles, suggesting that association with oil bodies was an artifact arising from the extraction procedure. By the use of recombinant techniques it has also been documented that IgE-binding epitopes are present on several different portions of the P39-1 polypeptide.