Elastomeric proteins: biological roles, structures and mechanisms.

Elastomeric proteins are able to withstand significant deformations without rupture before returning to their original state when the stress is removed. Although elastomeric proteins differ considerably in their amino acid sequence, they all have a complex domain structure and share two common properties. Namely, they contain elastomeric domains, comprised of repeated sequences, and additional domains that form intermolecular crosslinks. Furthermore, several protein contain beta-turns as a structural motif within the elastomeric domains.

Expression of a novel high-molecular-weight glutenin subunit gene in transgenic wheat.

High-molecular-weight glutenin subunits (HMW-GS), one class of seed storage proteins, are important determinants of the bread-making quality of wheat flour. To change the amount and composition of these proteins via genetic engineering, a gene encoding a novel hybrid subunit under the control of native HMW-GS regulatory sequences was inserted into wheat. Of 26 independent transgenic lines identified by bialaphos selection, 18 expressed the cotransformed hybrid HMW-GS gene in their seed. The hybrid subunit accumulated to levels comparable to those of the native HMW-GS. These results show that a native HMW-GS gene promoter can be used to obtain high levels of expression of seed storage and, potentially, other proteins in transgenic wheat endosperm. Transgene expression was stable for at least three seed generations in the majority of lines. These experiments demonstrate the feasibility of constructing wheat plants with novel seed protein compositions.

Transformation of wheat with high molecular weight subunit genes results in improved functional properties.

The high molecular weight (HMW) subunits of wheat glutenin are major determinants of the elastic properties of gluten that allow the use of wheat doughs to make bread, pasta, and a range of other foods. There are both quantitative and qualitative effects of HMW subunits on the quality of the grain, the former being related to differences in the number of expressed HMW subunit genes. We have transformed bread wheat in order to increase the proportions of the HMW subunits and improve the functional properties of the flour. A range of transgene expression levels was obtained with some of the novel subunits present at considerably higher levels than the endogenous subunits. Analysis of T2 seeds expressing transgenes for one or two additional HMW subunits showed stepwise increases in dough elasticity, demonstrating the improvement of the functional properties of wheat by genetic engineering.

Integration and expression of the high-molecular-weight glutenin subunit 1Ax1 gene into wheat.

The unique bread-making characteristic of wheat flour is closely related to the elasticity and extensibility of the gluten proteins stored in the starchy endosperm, particularly the high-molecular-weight glutenin subunits (HMW-GS), which are important in determining gluten and dough elasticity. The quality of wheat cultivars depends on the number and composition of the HMW-GS present. We have introduced the HMW-GS 1Ax1 gene, known to be associated with good bread-making quality, into the Bob White cultivar of wheat (Triticum aestivum L.), in which it is not present in nature, by the biolistic bombardment of cultured immature embryos. Of the 21 independent transformed lines selected, 20 expressed the selectable bar gene, and nine the 1Ax1 gene. The amount of HMW-GS 1Ax1 protein produced in the different transgenic lines varied from 0.6% to 2.3% of the total protein, resulting in an increase of up to 71% in total HMW-GS proteins. The transgenic plants were normal, fertile, and showed Mendelian segregation of the transgenes. The accumulation of HMW-GS 1Ax1 was consistent and stable up to the R3 seed generation. These results demonstrate that it is possible to manipulate both the quantity and quality of HMW-GS, which influence the bread-making quality of wheat.

Intermolecular disulfide bonds link specific high-molecular-weight glutenin subunits in wheat endosperm.

A detergent wash extracted soluble proteins from wheat flour, leaving a residue enriched with insoluble glutenin aggregates. Digestion of this residue with endoproteinase Lys-C, which showed a limited specificity for glutenin subunits, produced several peptides with apparent molecular weights close to those of intact high-molecular-weight glutenin subunits. N-terminal sequencing indicated that the isolated peptides were composed of high-molecular-weight glutenin subunit fragments joined by an intermolecular disulfide bond. In two of these peptides, only two components were found, one from an x-type subunit and the other from a y-type subunit. The isolated peptides all contained at least one x-type C-terminal region and one y-type N-terminal region, suggesting a specific orientation to the intermolecular disulfide linkage.

Small angle X-ray scattering of wheat seed-storage proteins: alpha-, gamma- and omega-gliadins and the high molecular weight (HMW) subunits of glutenin.

Small angle X-ray scattering in solution was performed on seed-storage proteins from wheat. Three different groups of gliadins (alpha-, gamma- and omega-) and a high molecular weight (HMW) subunit of glutenin (1Bx20) were studied to determine molecular size parameters. All the gliadins could be modelled as prolate ellipsoids with extended conformations. The HMW subunit existed as a highly extended rod-like particle in solution with a length of about 69 nm and a diameter of about 6.4 nm. Specific aggregation effects were observed which may reflect mechanisms of self-assembly that contribute to the unique viscoelastic properties of wheat dough.

Synthesis, expression and characterisation of peptides comprised of perfect repeat motifs based on a wheat seed storage protein.

We have developed a novel method for constructing synthetic genes that encode a series of peptides comprising perfect repeat motifs based on a high molecular weight subunit (HMW glutenin subunit), a highly repetitive storage protein from wheat seed. A series of these genes of sequentially increasing size was produced, four of which (called R3, 4, 5, 6) were expressed in Escherichia coli. Activity of the synthetic genes in E. coli was confirmed by Northern blot analysis but SDS-PAGE of crude protein extracts failed to show any expressed peptides when stained using Coomassie brilliant blue R250. However, Western blots probed with a HMW glutenin subunit-specific polyclonal antibody showed the presence of the R6 peptide (M(r) 22005) in the crude cell extracts and both this and the R3 peptide (M(r) 12005) were subsequently purified by extraction with hot aqueous ethanol followed by precipitation with acetone and separated by RP-HPLC. The R4 and R5 peptides were not purified. The purified R3 and R6 peptides absorbed Coomassie brilliant blue R250 or other protein stains only weakly and this was considered to account for their failure to be revealed by staining of separations of the crude protein extracts. Circular dichroism spectroscopy showed that both peptides had similar beta-turn rich structures similar to the repetitive sequences present in the whole HMW glutenin subunits. We conclude that expression of perfect repeat peptides in E. coli is a suitable system for the study of structure-function relationships in wheat gluten proteins and other highly repetitive proteins.

Sequential extraction and quantitative recovery of gliadins, glutenins, and other proteins from small samples of wheat flour.

Methods to sequentially extract and fractionate wheat flour proteins were evaluated to reliably quantify gliadins, glutenins, and albumins/globulins in single flour samples. Compositions of the resulting protein fractions were analyzed by RP-HPLC combined with SDS-PAGE. Unknown proteins were identified by mass spectrometry or N-terminal sequencing. The best separation and recovery of discrete albumin/globulin, gliadin, and glutenin fractions from the same flour sample was achieved by extraction with 0.3 M NaI in 7.5% 1-propanol followed by 2% SDS, 25 mM DTT in 25 mM TRIS, pH 8.0, and precipitation of the solubilized proteins with ammonium acetate/methanol followed by acetone. Average flour composition for the variety Butte86 was 10% albumin/globulin, 40% gliadin, and 48% glutenin. This method should be useful for determining flour composition in diverse samples and evaluating relationships between proteins and end-use functionality.

Homology modeling and molecular dynamics simulations of the N-terminal domain of wheat high molecular weight glutenin subunit 10.

High molecular weight glutenin subunits (HMW-GS) are of a particular interest because of their biomechanical properties, which are important in many food systems such as breadmaking. Using fold-recognition techniques, we identified a fold compatible with the N-terminal domain of HMW-GS Dy10. This fold corresponds to the one adopted by proteins belonging to the cereal inhibitor family. Starting from three known protein structures of this family as templates, we built three models for the N-terminal domain of HMW-GS Dy10. We analyzed these models, and we propose a number of hypotheses regarding the N-terminal domain properties that can be tested experimentally. In particular, we discuss two possible ways of interaction between the N-terminal domains of the y-type HMW glutenin subunits. The first way consists in the creation of interchain disulfide bridges. According to our models, we propose two plausible scenarios: (1) the existence of an intrachain disulfide bridge between cysteines 22 and 44, leaving the three other cysteines free of engaging in intermolecular bonds; and (2) the creation of two intrachain disulfide bridges (involving cysteines 22-44 and cysteines 10-55), leaving a single cysteine (45) for creating an intermolecular disulfide bridge. We discuss these scenarios in relation to contradictory experimental results. The second way, although less likely, is nevertheless worth considering. There might exist a possibility for the N-terminal domain of Dy10, Nt-Dy10, to create oligomers, because homologous cereal inhibitor proteins are known to exist as monomers, homodimers, and heterooligomers. We also discuss, in relation to the function of the cereal inhibitor proteins, the possibility that this N-terminal domain has retained similar inhibitory functions.

Construction and expression of a synthetic wheat storage protein gene.

A synthetic wheat high-molecular-weight (HMW) glutenin storage protein gene analog was constructed for expression in E. coli. This first synthetic HMW-glutenin gene and future modifications are intended to allow systematic dissection of the molecular basis of HMW-glutenin role in the visco-elastic properties critical for wheat product processing and utilization. The design of the gene included four features: different construction strategies for the separate assembly of major polypeptide domains, the inclusion of convenient restriction sites for modifications, use of a codon selection similar to E. coli highly expressed genes, and the ability to produce repetitive sequence domains of exact numbers of defined repeats. The complete synthetic HMW-glutenin construct was 1908 bp, and contained 32 identical copies of one of the HMW-glutenin repetitive domain motifs. The gene expressed the novel HMW-glutenin protein to relatively high levels in bacterial cultures and the protein exhibited the known anomalous behavior of HMW-glutenins in SDS-PAGE.

Cloning of the rice seed alpha-globulin-encoding gene: sequence similarity of the 5'-flanking region to those of the genes encoding wheat high-molecular-weight glutenin and barley D hordein.

A genomic clone encoding the rice endosperm major globulin (alpha-globulin) with an apparent molecular mass of 26 kDa was isolated, and its nucleotide (nt) sequence and transcription start point (tsp) were determined. The tsp was identical to that of the gene encoding the wheat high-molecular-weight (HMW) glutenin subunit. The consensus '-300 element' and an A + T-rich sequence exist upstream from the TATA box in the 5'-flanking region. A nt sequence of about 130 bp in the 5'-flanking region was found to be markedly homologous to those of the genes encoding the wheat HMW glutenin subunit and barley D hordein.

Synthesis of a wheat storage protein subunit in Escherichia coli using novel expression vectors.

Useful plasmid expression vectors have been constructed which allow the synthesis of beta-galactosidase (betaG) fusion polypeptides or of polypeptides specified by cDNA clones in Escherichia coli hosts. A foreign DNA fragment can be inserted in any one of the three reading frames at the unique EcoRI, BamHI or SmaI sites immediately after the initiation codon. The cloned foreign gene is under the control of the lac promoter. Using a cDNA clone that encodes part of a wheat storage protein [a high-Mr (HMW) glutenin subunit] synthesis of a glutenin-beta G fusion protein was demonstrated. Synthesis of the glutenin polypeptide, not fused to beta G, was achieved by replacing the lacZYA genes with a stop codon.

Molecular flexibility in wheat gluten proteins submitted to heating.

Prolamin proteins are responsible for the network that gives wheat dough its viscoelastic properties. Non-prolamin depleted gluten was prepared under conditions that preserve its functionality. Electron Spin Resonance (ESR) was used to provide information about the dynamics of the protein at temperatures between 5 and 90 degrees C by specific spin labelling of its cysteine residues. The spectra were of a composite type, resulting from at least two populations of spin labels largely differing in molecular mobility. The correlation time of the less mobile nitroxide radicals was determined by saturation transfer ESR. Upon heating there was a transfer from the slow to the fast moving population of radicals, and an increase of mobility of this last catagory that followed the Arrhenius law. The effect of temperature on molecular flexibility was reversible. This was not the case for purified, polymerised glutenin subunits extracted from gluten. Urea created similar modifications on gluten as heat.

Characterisation of high Mr wheat glutenin polymers by agarose gel electrophoresis and dynamic light scattering.

Agarose gel electrophoresis has been used to separate the complex mixture of wheat gluten polymers into fractions ranging in Mr, determined by dynamic light scattering, from about 500,000 to over 5x10(6). The separation is reliable and reproducible and well suited to the routine analysis of multiple samples.

Opioid peptides derived from wheat gluten: their isolation and characterization.

Four opioid peptides were isolated from the enzymatic digest of wheat gluten. Their structures were Gly-Tyr-Tyr-Pro-Thr, Gly-Tyr-Tyr-Pro,Tyr-Gly-Gly-Trp-Leu and Tyr-Gly-Gly-Trp, which were named gluten exorphins A5, A4, B5 and B4, respectively. The gluten exorphin A5 sequence was found at 15 sites in the primary structure of the high molecular weight glutenin and was highly specific for delta-receptors. The structure-activity relationships of gluten exorphins A were unique in that the presence of Gly at their N-termini increased their activities. Gluten exorphin B5, which corresponds to [Trp4,Leu5]enkephalin, showed the most potent activity among these peptides. Its IC50 values were 0.05 microM and 0.017 microM, respectively, on the GPI and the MVD assays.

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)

Structural studies of the allelic wheat glutenin subunits 1Bx7 and 1Bx20 by matrix-assisted laser desorption/ionization mass spectrometry and high-performance liquid chromatography/electrospray ionization mass spectrometry.

Structural studies of the high molecular mass (HMM) glutenin subunits 1Bx7 (from cvs Hereward and Galatea) and 1Bx20 (from cv. Bidi17) of bread wheat were conducted using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS) and reversed-phase high-performance liquid chromatography/electrospray ionization mass spectrometry (RP-HPLC/ESI-MS). For all three proteins, MALDI-TOFMS analysis showed that the isolated fractions contained a second component with a mass about 650 Da lower than the major component. The testing and correction of the gene-derived amino acid sequences of the three proteins were performed by direct MALDI-TOFMS analysis of their tryptic peptide mixture. Analysis of the digest was performed by recording several MALDI mass spectra of the mixture at low, medium and high mass ranges, optimizing the matrix and the acquisition parameters for each mass range. Complementary data were obtained by RP-HPLC/ESI-MS analysis of the tryptic digest. This resulted in coverage of about 98% of the sequences. In contrast to the gene-derived data, the results obtained demonstrate the insertion of the sequence QPGQGQ between Trp716 and Gln717 of subunit 1Bx7 (cv. Galatea) and a possible single amino acid substitution within the T20 peptide of subunit 1Bx20. Moreover, the mass spectrometric data demonstrated that the lower mass components present in all the fractions correspond to the major components but lack about six amino acid residues, which are probably lost from the protein C-terminus. Finally, the results obtained provide evidence for the lack of glycosylation or other post-translational modifications of these subunits.

Rice seed globulin: a protein similar to wheat seed glutenin.

The globulin of the seed endosperms of rice has an isoelectric point of 6.4 and a M(r) of 26,000. There is one intra-disulphide bond, but no N-linked oligosaccharide chain. The amino acid sequence of the N-terminal and internal regions of the globulin was determined and found to be homologous with that of glutenin, the storage protein in the seed endosperms of wheat. Rice globulin and wheat glutenin were rich in glycine, and glutamic acid or glutamine, and in addition, wheat glutenin cross-reacted with antibody raised against rice globulin. These results suggest that rice seed globulin represents a protein similar to wheat seed glutenin.

Cellular and humoral responses in coeliac disease. 2. Protein extracts from different cereals.

The humoral and cellular immune responses to grain protein extracts from coeliac-toxic and non-toxic cereals were compared by use of a number of ELISA and immunoblotting methods and the indirect leucocyte migration inhibition factor (LMIF) assay. Both adult and child coeliacs had elevated levels of serum antibody to proteins from the coeliac-toxic cereals, namely bread wheat, durum wheat, rye and barley and low levels of proteins from other cereals. Using protein blotting techniques, antibody binding was greatest to gliadins/low mol mass glutenin subunits and homologous prolamins from rye and barley, consistent with the ELISA findings. Competition ELISA and preabsorption tests indicated that antibody reaction to maize storage proteins did not simply result from cross-reaction of antigliadin antibodies. In LMIF assays, only the wheat extracts had activity in coeliac patients. This is most likely partly due to loss of some of T-cell epitopes from the extraction technique required for these proteins, as well as the relatively small effects seen for even very active fractions in the LMIF assay.

Cellular and humoral responses in coeliac disease. 1. Wheat protein fractions.

The humoral and cellular immune response of coeliac individuals to various wheat protein fractions was studied using serum antibody ELISA assays and the indirect leucocyte migration inhibition factor (LMIF) assays. Greater migration inhibition factor activity was seen in coeliacs on a gluten-free-diet having low serum antibody titres, and using purified T-cells instead of total peripheral blood mononucleocytes. Gliadin was the most active fraction in both assays. Raised antibodies to low-molecular weight and high-molecular weight glutenin polypeptides was observed, though these proteins had little migration inhibition factor activity. No cellular or humoral response was seen to albumins or globulins. Proteins associated with the granules of well-washed wheat starch are distinct from gluten proteins and had little T-cell activity, correlating with clinical observations that properly prepared wheat starch is devoid of coeliac toxicity. The greater specificity of the humoral response for individual wheat protein fractions in this study, compared with the earlier reports, likely results from cross-contamination in the earlier work of each fraction with gliadin.