Small angle neutron scattering contrast variation reveals heterogeneities of interactions in protein gels.

We propose a quantitative approach to probe the spatial heterogeneities of interactions in macromolecular gels, based on a combination of small angle X-ray (SAXS) and neutrons (SANS) scattering. We investigate the structure of model gluten protein gels and show that the gels display radically different SAXS and SANS profiles when the solvent is (at least partially) deuterated. The detailed analysis of the SANS signal as a function of the solvent deuteration demonstrates heterogeneities of sample deuteration at different length scales. The progressive exchange between the protons (H) of the proteins and the deuteriums (D) of the solvent is inhomogeneous and 60 nm large zones that are enriched in H are evidenced. In addition, at low protein concentration, in the sol state, solvent deuteration induces a liquid/liquid phase separation. Complementary biochemical and structure analyses show that the denser protein phase is more protonated and specifically enriched in glutenin, the polymeric fraction of gluten proteins. These findings suggest that the presence of H-rich zones in gluten gels would arise from the preferential interaction of glutenin polymers through a tight network of non-exchangeable intermolecular hydrogen bonds.

Characterization and quantification of low molecular weight glutenins in durum wheats.

Durum wheat proteins have been considered as a model because of the very clear-cut relationship previously evidenced between the electrophoretic type '42' or '45' of the components that are coded by the Gli-B1 chromosome locus and the intrinsic quality (gluten viscoelasticity) of cultivars. The proteins from 4 cultivars were subjected to sequential extraction and separated into five groups, respectively, in: NaCl, EtOH (gliadins-I), EtOH + mercaptoethanol (ME) (gliadins-II), AcOH + ME (glutenins-I) and SDS + ME (glutenins-II) and characterized using polyacrylamide gel electrophoresis (PAGE), SDS-PAGE and 2-dimensional (NEPHGE X SDS - PAGE) electrophoretic systems. EtOH-soluble fractions were also separated by ion-exchange chromatography, each fraction being characterized in PAGE and SDS-PAGE and its composition in major bands determined by densitometry. From the ratio of each chromatographic fraction and of each solubility group, an estimation of the major bands or electrophoretic zones was also made in respect to the whole proteins. In 'type 45' cultivars, it was shown that only 67% of the EtOH-soluble fraction (although considered as classical gliadins) had a monomeric character, giving rise to discrete bands in PAGE systems. The remainder (33%) were aggregated fractions, essentially those referred to as low molecular weight glutenins (LMWG), that migrate, upon reduction only, in SDS-PAGE systems. LMWG make up 27% of total proteins and are revealed as a strong triplet in the 44,500-51,500 MW region, in gliadin-I and especially in gliadin-II groups. In type '42' cultivars, the LMWG ratio is reduced about by half (18% of EtOH soluble fraction, 14% of total proteins). This difference, coupled with their aggregative behavior, leads to their consideration as the major functional markers of gluten quality, gliadins 42/45 being genetic markers only. Without excluding possible physicochemical differences between different LMWG allelic types, it is hypothesized that quantitative differences could explain by themselves the quality differences between the two durum wheat genetic types. Concerning the other aggregative fractions, like high molecular weight glutenin (HMWG) subunits in glutenin-I and II groups, they do not show (unlike bread wheats) quantitative or qualitative differences large enough to play a major role in explaining genetic differences in durum wheat gluten characteristics. It is recommended, especially for physicochemical studies of wheat quality, to rely on a protein classification based on monomeric or aggregative characteristics, instead of Osborne's scheme based only on fractionation by solubility.(ABSTRACT TRUNCATED AT 400 WORDS)

Wheat gluten phenolic acids: occurrence and fate upon mixing.

Ferulic acid (FA, 4.9-17.7 microg/100 mg), sinapic acid (SA, 1.4-3.5 microg/100 mg), and traces of p-coumaric acid and vanillic acid were detected after saponification of six wheat glutens from industrial and pilot-scale origins. FA and SA occurred mostly as soluble-bound and insoluble-bound forms according to their extractability by acetone/methanol/water (7:7:6, v/v/v). The major part of FA (50-95%) was found in the unextractable fraction, whereas SA was mostly extractable (64-85%). The carbohydrate contents of the glutens were determined also after acid hydrolysis. The highest levels of glucose, arabinoxylan, and FA were obtained from the unextractable fractions of the pilot-scale extracted glutens, probably in relation with a lower efficiency of washing during extraction compared to industrial processes. On the other hand, SA compounds were in similar concentrations in all samples, suggesting their involvement in specific interactions during gluten protein agglomeration. Saponification of the soluble-bound phenolic acids released mainly glucose, whereas a beta-glucosidase treatment had no effect. FA and SA extractability, especially that of soluble-bound ones, decreased strongly in overmixed gluten/water doughs. These low molecular weight conjugates of phenolic acids could be involved in the dough breakdown phenomenon.

Protein insolubilization and thiol oxidation in sulfite-treated wheat gluten films during aging at various temperatures and relative humidities.

Gluten films were prepared by casting an acidic and ethanolic solution of gluten previously treated with sodium sulfite. The effects of sulfitolysis on proteins were investigated by SE-HPLC and thiol/disulfide content measurements. During sulfitolysis, insoluble glutenin macropolymer was converted into its constitutive subunits. About 10% of gluten disulfide bonds were cleaved, of which three-fourths originated from interchain disulfide bonds. Oxidation of thiol groups released during sulfitolysis was followed for various temperatures (T) and relative humidities. Oxidation was shown to be a second-order rate process occurring below the glass transition temperature (T(g)) and related to T - T(g). Thiol oxidation ensured the formation of interchain bonds between specific classes of gluten proteins according to an ordered process. Intrachain bonds were also formed and through thiol/disulfide-exchange reactions were finally converted to interchain bonds. Thus, fully oxidized gluten films had more insoluble glutenin macropolymers than native gluten.

Can oral vitamin K before elective surgery substitute for preoperative heparin bridging in patients on vitamin K antagonists?

BACKGROUND: After a vitamin K antagonist (VKA) overdose, 1-2 mg of oral vitamin K can lower the International Normalized Ratio (INR) to the therapeutic range. OBJECTIVE: To establish whether oral vitamin K can substitute for heparin bridging and decrease the INR to < or = 1.5 before elective surgery. METHODS: Patients on long-term VKAs were randomized either to heparin bridging after the last VKA dose on day -5 before surgery (group H) or to VKA treatment until day -2, followed by 1 mg of oral vitamin K on the day before surgery (group K). Blood clotting variables were assessed on days -5/-2, 1 and 0, and postoperatively. If the target INR was not achieved 2 h before incision, surgery was deferred or performed after injection of prothrombin complex concentrate (PCC). RESULTS: In 30 of 94 included patients, baseline INR was outside the chosen range (18, INR < 2; 12, INR > 3.5), leaving 34 eligible patients in group H and 30 in group K. The groups were balanced in terms of body mass index, VKA treatment duration and indication, scheduled surgery, preoperative and postoperative hemoglobin, and blood loss. The INR was significantly higher in group K on days -1 and 0 than in group H. An INR < or = 1.5 was not achieved in 20 group K patients (66%). Surgery was postponed or performed after PCC injection in 12 of these 20 patients. CONCLUSIONS: Oral vitamin K (1 mg) cannot substitute for heparin bridging before surgery. In addition, one-third of patients on VKAs were exposed to a risk of bleeding (overdose) or thrombosis (underdose), thus highlighting the need for new oral anticoagulants.

Separation of durum wheat proteins by ultrathin-layer isoelectric focusing: a new tool for the characterization and quantification of low molecular weight glutenins.

An isoelectric focusing method capable of resolving all groups of storage protein of the wheat seed, including the most basic low molecular weight glutenin (LMWG), was developed. Ultrathin polyacrylamide gels were used after drying and rehydration with 8 M urea, 50 mM DTE and 2.4% carrier ampholytes (pH 4-9). Densitometric scanning of the isoelectric focusing gels permitted a more accurate and specific quantitation of LMWG components among various cultivars than patterns based on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The two main genetic types (i.e. 'gamma-42' and 'gamma-45') of durum wheats were separated on the basis of the proportion in LMWG in storage proteins, but no significant difference was found within these groups. Advantages of the system as regards reliability, high resolution, ability to abolish protein oxidation and preventing reaggregation of LMWG were also discussed.

Determination of the number of cysteine residues in high molecular weight subunits of wheat glutenin.

A simple method allowing the determination of the number of cysteine residues of the high molecular weight glutenin subunits (HMW-GS) is presented. The method was adapted from that of Creighton (T. E. Creighton, Nature 1980, 2840, 487-489) with modified reagents for alkylation of the cysteine residues and the electrophoretic system. The acid-urea-polyacrylamide gel electrophoresis (PAGE) method, developed by Morel (M. H. Morel, Cereal Chem. 1994, 713, 238-242), was adopted and mixtures of iodoacetic acid and 4-vinylpyridine were used to alkylate the glutenin subunits. The accuracy of the method was checked with some HMW-GS whose number of cysteine residues was already known from molecular biology approaches. In subunits 5*, 2.2, 2.2* and 4.1 (of Dx types) from cultivars Ben and Fiorello, MG 7249, MG 315, and Kador, respectively, only 4 cysteine residues were demonstrated. Subunit 20 was found to exist as a regular Bx and By subunit pair, with the Bx subunit containing only 2 cysteine residues, which is unusual.

Purification of wheat glutenin subunits by preparative acid and two-dimensional electrophoresis.

Reduced alkylated glutenin subunits from wheat flour were fractionated by preparative electrophoresis at acid pH. The high molecular weight glutenin subunits (HMW-GS) and some of the low molecular weight glutenin subunits (LMW-GS) were purified by this one-step procedure, whereas the remainder of the LMW-GS, comigrating in the acid system, were purified in a second step by electroendosmotic preparative electrophoresis in the presence of sodium dodecyl sulfate. The quantities of recovered protein were sufficient for biochemical characterization and/or antibody production.

Reversible changes of the wheat gamma 46 gliadin conformation submitted to high pressures and temperatures.

The structure of the wheat gamma 46 gliadin was investigated, in aqueous solutions, under high pressure or temperature by the use of ultraviolet and fluorescence spectroscopic techniques. We found that high pressure (above 400 MPa) induces a change in the protein conformation that results in a decrease of the polarity of the environment of aromatic amino acids. This new conformation was able to bind the hydrophobic probe, 8-anilino-1-naphtalene-sulfonic acid (ANS), indicating an increase in the gliadin surface hydrophobicity. Thermodynamic parameters of this conformational change were measured and infrared spectroscopy studies were used to probe the potential secondary structure modifications. The high stability of gamma 46 gliadin could be related to its elastic character, as the observed changes were always found to be reversible.