In vitro assessment of acetic-acid-soluble proteins (glutenin) toxicity in celiac disease

Acetic-acid-soluble storage proteins from gluten of the bread wheat cv. Sprint 3 were fractionated by adsorption chromatography on 2000 Å controlled-pore glass (CPG) beads, and glutenin polymers with molecular mass higher than 10⁷ Da and free from monomeric gliadins were recovered. The glutenin polymers were found to consist of high-molecular-weight (HMW) and low-molecular-weight (LMW) glutenin subunits. Peptic-tryptic (PT) digests of glutenins were examined for their agglutination activity on human myelogenous leukemia K 562(S) cells, agglutination being strongly correlated with toxicity for the celiac intestine. The peptide fraction at a concentration of 1 g/L of culture medium was able to agglutinate 30% of K 562(S) cells, suggesting a moderate toxic effect. This toxicity may be accounted for by homologies in amino acid sequences between glutenin subunits and α/β-and γ-gliadins. © 1997 John Wiley & Sons, Inc.     

Targeting of prolamins by RNAi in bread wheat: effectiveness of seven silencing‐fragment combinations for obtaining lines devoid of coeliac disease epitopes from highly immunogenic gliadins

Gluten proteins are responsible for the viscoelastic properties of wheat flour but also for triggering pathologies in susceptible individuals, of which coeliac disease (CD) and noncoeliac gluten sensitivity may affect up to 8% of the population. The only effective treatment for affected persons is a strict gluten‐free diet. Here, we report the effectiveness of seven plasmid combinations, encompassing RNAi fragments from α‐, γ‐, ω‐gliadins, and LMW glutenin subunits, for silencing the expression of different prolamin fractions. Silencing patterns of transgenic lines were analysed by gel electrophoresis, RP‐HPLC and mass spectrometry (LC‐MS/MS), whereas gluten immunogenicity was assayed by an anti‐gliadin 33‐mer monoclonal antibody (moAb). Plasmid combinations 1 and 2 downregulated only γ‐ and α‐gliadins, respectively. Four plasmid combinations were highly effective in the silencing of ω‐gliadins and γ‐gliadins, and three of these also silenced α‐gliadins. HMW glutenins were upregulated in all but one plasmid combination, while LMW glutenins were downregulated in three plasmid combinations. Total protein and starch contents were unaffected regardless of the plasmid combination used. Six plasmid combinations provided strong reduction in the gluten content as measured by moAb and for two combinations, this reduction was higher than 90% in comparison with the wild type. CD epitope analysis in peptides identified in LC‐MS/MS showed that lines from three plasmid combinations were totally devoid of CD epitopes from the highly immunogenic α‐ and ω‐gliadins. Our findings raise the prospect of breeding wheat species with low levels of harmful gluten, and of achieving the important goal of developing nontoxic wheat cultivars.     

The Introgression of RNAi Silencing of γ-Gliadins into Commercial Lines of Bread Wheat Changes the Mixing and Technological Properties of the Dough

In the present work the effects on dough quality by the down-regulation of γ-gliadins in different genetic backgrounds of bread wheat were investigated. RNAi-mediated silencing of γ-gliadins was introgressed by conventional crossing into three commercial bread wheat lines (namely ‘Gazul’, ‘Podenco’ and ‘Arpain’), and along with the transgenic line A1152 (cv. Bobwhite) compared with their respective wild types. The protein fractions were quantified by RP-HPLC, whereas the technological and mixing properties were assessed by SDSS test and by the Mixograph instrument. Principal component analysis (PCA) was carried out for both the wild types and the transgenic lines, showing differences in the factors affecting the technological and mixing properties of the dough as a consequence of the reduction of the γ-gliadins. In transgenic lines, the α- and ω-gliadins, and total gliadins negatively affected the dough strength and tolerance to over-mixing, whereas the L/H ratio showed the opposite effect, positively influencing the dough quality. The increase of the SDSS volume in the transgenic lines of ‘Gazul’, ‘Podenco’ and ‘Arpain’ indicates increased gluten strength and quality respect to the wild types. SDSS volume was found to be positively influenced by the amount of glutenins, which were also increased in the transgenic lines. In addition, a positive effect was observed in the MT, PR1 and RBD in some of the transgenic lines of ‘Podenco’ and ‘Arpain’. In conclusion, the down-regulation of γ-gliadins resulted in stronger doughs and a better tolerance to over-mixing in some transgenic lines. Although the reduction of γ-gliadins seems not to have a direct effect on the mixing and bread-making properties, the compensatory effect on the synthesis of the other prolamins may result in stronger doughs with improved over-mixing resistance.     

The wheat γ-gliadin genes: characterization of ten new sequences and further understanding of γ-gliadin gene family structure

Ten new wheat γ-gliadin gene sequences are reported and an analysis of γ-gliadin gene family structure is carried out using all known γ-gliadin sequences. The new sequences comprise four genomic clones with significantly more flanking DNA than previously reported, and six cDNA clones from a wheat endosperm EST project. Analysis of extended flanking DNA from the genomic clones indicates the limits of conservation of γ-gliadin DNA sequence that are similar to those previously found with other gliadin and glutenin genes and that are theorized to define the DNA sequence necessary for gene control. Most of the flanking DNA is not homologous to any reported DNA sequence, and one flanking region contains the first MITE-like (miniature inverted transposable element) DNA sequence associated with gliadin genes. About a quarter of the encoded polypeptides would contain a free cysteine residue – an observation that may relate to reports that at least some gliadins can participate in wheat endosperm glutenin polymer formation. The new sequences represent both genes closely related to those previously reported and a new sub-class of γ-gliadins.     

Grain quality characteristics of spring wheat (Triticum aestivum) as affected by free-air CO2 enrichment

Spring wheat (Triticum aestivum L. cv. Triso) was grown in a free-air carbon dioxide (CO₂) enrichment (FACE) system at Stuttgart–Hohenheim (Germany) in 2008 to examine effects on crop yield and grain quality. Elevated CO₂ had no significant impacts on aboveground biomass and grain yield components except for an increase in thousand grain weight by 5.4% with size distribution shifted towards larger grains. Total grain protein concentration decreased by 7.9% under CO₂ enrichment, and protein composition was altered. Total gliadins and their single types (ω5-gliadins, ω1,2-gliadins, α-gliadins, and γ-gliadins) were reduced, while albumins/globulins, total glutenins and their subunits were not influenced. The gluten proteins (gliadins plus glutenins) were lowered by 11.3% in the high-CO₂ treatment, whereas proportions of gluten protein types were slightly affected as only ω1,2-gliadins decreased. Accordingly, all proteinogenic amino acids were decreased by 4.2 to 7.9% in concentrations per unit flour mass, although partly below the level of statistical significance. In contrast, the composition of amino acids on a per protein basis remained unaffected except for a decline in serine. Among the minerals, the concentrations of calcium, magnesium, iron and cobalt decreased, while an increase was observed for boron. The concentrations of total non-structural carbohydrates and starch decreased, whereas fructose, raffinose and fructan increased. Total lipid concentration remained unaffected by the CO₂ enrichment, whereas the grain carbon/nitrogen relation was increased by 8.5%. Implications may occur for consumer nutrition and health, and for industrial processing, thus breeding of new wheat cultivars that exploit CO₂ fertilisation and maintain grain quality properties is regarded as one potential option to assure the supply chain for the future.     

Mapping of glutenin and gliadin genes located on chromosome 1B of common wheat

Summary The inheritance of the high molecular weight (HMW) glutenins and of several gliadins controlled, respectively, by the long and short arms of chromosome 1B of common wheat was studied. Analysis was carried out on the progeny of two inter-varietal crosses in which the parental lines possessed differentially migrating subunits as revealed by sodium dodecyl sulphate polyacrylamide gel electrophoresis. No recombination event was detected either within the fraction of the HMW glutenins or among most of the gliadin subunits studied indicating that they are controlled by tightly linked gene clusters. One gliadin subunit (B30) showed 25.5% recombination frequency with the rest of the gliadin subunits and 23.5% recombination frequency with the fraction of the HMW glutenin subunits. It has been concluded that this subunit is controlled by a separate locus (Gld-B6), proximal to the major gliadin gene cluster on the short arm of chromosome 1B. Consequently, the recombination percentage between the glutenin loci and most of the gliadin loci was calculated as 49.0 and the distance in centi-Morgans (cM) as 53.6. The estimated distance in cM is very close to the observed recombination percentage. A genetic map of these storage protein genes is presented.     

Biochemical and genetic characterization of a monomeric storage protein (T1) with an unusually high molecular weight in Triticum tauschii

The protein named T1, present in Triticum tauschii, was previously characterized as a high-molecular-weight (HMW) glutenin subunit with a molecular size similar to that of the y-type glutenin subunit-10 of Triticum aestivum. This protein was present along with other HMW glutenin subunits named 2^t and T2, and was considered as part of the same allele at the Glu-D ^t 1 locus of T. tauschii. This paper describes a re-evaluation of this protein, involving analyses of a collection of 173 accessions of T. tauschii, by SDS-PAGE of glutenin subunits after the extraction of monomeric protein. No accessions were found containing the three HMW glutenin subunits. On the other hand, 17 lines with HMW glutenin subunits having electrophoretic mobilities similar to subunits 2^t and T2 were identified. The absence of T1 protein in these gel patterns has shown that protein T1 is not a component of the polymeric protein. Rather, the T1 protein is an ω-gliadin with an unusually high-molecular-weight. This conclusion is based on acidic polyacrylamide gel electrophoresis (A-PAGE), sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and two-dimensional gel electrophoresis (A-PAGE+ SDS-PAGE), together with analysis of its N-terminal amino-acids sequence. The inheritance of ω-gliadin T1 was studied through analyses of gliadins and HMW glutenins in 106 F₂ grains of a cross between synthetic wheat, L/18913, and the wheat cv Egret. HMW glutenin subunits and gliadins derived from T. tauschii (Glu-D ^t 1 and Gli-D ^t 1) segregated as alleles of the Glu-D1 and Gli-D1 loci of bread wheat. A new locus encoding the ω-gliadin T1 was identified and named Gli-DT1. The genetic distance between this new locus and those of endosperm proteins encoded at the 1D chromosome were calculated. The Gli-DT1 locus is located on the short arm of chromosome 1D and the map distance between this locus and the Gli-D1 and Glu-D1 loci was calculated as 13.18 cM and 40.20 cM, respectively. Received: 13 October 2000 / Accepted: 18 April 2001     

Characterization of ��/��- and ��-Gliadins in Commercial Varieties and Breeding Lines of Durum Wheat Using MALDI-TOF and A-PAGE Gels

In this work, gliadin composition has been analyzed in 33 accessions of durum wheat using MALDI-TOF MS and compared with A-PAGE results. The MALDI-TOF MS spectra were 29,900-42,500 Da, which corresponds to the α/β- and γ-gliadin regions in A-PAGE. The average of gliadin peaks per line was 23 for MALDI-TOF MS and only 14.8 bands for A-PAGE. MALDI-TOF MS identified 33 gliadin peaks in the durum wheat collection, 20 of which were unique peaks present in 7 lines. A-PAGE analysis identified 30 bands, of which only 4 were unique. Thus, the MALDI-TOF MS method was more sensitive than A-PAGE for identifying α/β- and γ-gliadins in the 33 durum wheat lines studied. Phylogenetic analyses performed using MALDI-TOF MS data assigned the durum wheat lines to two groups. The utility of MALDI-TOF MS to determine relationships among genotypes and for identification of durum wheat accessions is discussed.     

Altered functional properties of tritordeum by transformation with HMW glutenin subunit genes

The high-molecular-weight (HMW) subunits of wheat glutenin are the major determinants of the gluten visco-elasticity that allows wheat doughs to be used to make bread, pasta and other food products. In order to increase the proportions of the HMW subunits, and hence improve breadmaking performance, particle bombardment was used to transform tritordeum, a fertile amphiploid between wild barley and pasta wheat, with genes encoding two HMW glutenin subunits (1Ax1 and 1Dx5). Of the 13 independent transgenic lines recovered (a transformation frequency of 1.4%) six express the novel HMW subunits at levels similar to, or higher than, those of the endogenous subunits encoded on chromosome 1B. Small-scale mixograph analysis of T₂ seeds from a line expressing the transgene for 1Dx5 indicated that the addition of novel HMW subunits can result in significant improvements in dough strength and stability, thus demonstrating that transformation can be used to modify the functional properties of tritordeum for improved breadmaking. Received: 15 January 1999 / Accepted: 5 February 1999     

Genetic control of endosperm proteins in wheat

Summary Total endosperm proteins extracted from both several common wheat cultivars and some intervarietal substitution lines derived from them were fractionated according to their molecular weight in a high resolution one-dimensional gel electrophoresis. The four donor cultivars and the recipient one — Chinese Spring, possessed differentially migrating protein bands in the fractions of high molecular weight (HMW) glutenins and gliadins. Several of these bands were identified for the first time in this study. By utilizing intervarietal substitution lines the control of the HMW glutenins and gliadins by chromosomes of homoeologous group 1 was either reaffirmed or, for the new bands, established. Several HMW gliadin subunits showed a considerable variation in their staining intensity in the intervarietal substitution lines indicating that their expression was dependent on the genetic background.This paper is based on a portion of a dissertation to be submitted by G. Galili in partial fulfilment of the Ph.D. requirements of the Feinberg Graduate School, The Weizmann Institute of Science, RehovotThe Marshall and Edith Korshak Professor of Plant Cytogenetics     

Silencing of HMW glutenins in transgenic wheat expressing extra HMW subunits

Wheat HMW glutenin subunit genes 1Ax1 and 1Dx5 were introduced, and either expressed or overexpressed, into a commercial wheat cultivar that already expresses five subunits. Six independent transgenic events were obtained and characterized by SDS-PAGE and Southern analysis. The 1Dx5 gene was overexpressed in two events without changes in the other endosperm proteins. Overexpression of 1Dx5 increased the contribution of HMW glutenin subunits to total protein up to 22%. Two events express the 1Ax1 subunit transgene with associated silencing of the 1Ax2* endogenous subunit. In the SDS-PAGE one of them shows a new HMW glutenin band of an apparent M_r lower than that of the 1Dx5 subunit. Southern analysis of the four events confirmed transformation and suggest that the transgenes are present in a low copy number. Silencing of all the HMW glutenin subunits was observed in two different events of transgenic wheat expressing the 1Ax1 subunit transgene and overexpressing the Dx5 gene. Transgenes and expression patterns were stably transmitted to the progenies in all the events except one where in some of the segregating T₂ seeds the silencing of all HMW glutenin subunits was reverted associated with a drastic lost of transgenes from a high to a low copy number. The revertant T₂ seeds expressed the five endogenous subunits plus the 1Ax1 transgene. Received: 16 June 1999 / Accepted: 29 July 1999     

激光诱变小麦后代材料籽粒贮藏蛋白编码基因变异的研究

本研究采用SDS—PAGE分析了冀麦七号、冀麦18和冀早15三个品种激光后代籽粒贮藏蛋白的变异情况。结果表明,高分子量麦谷蛋白和醇溶蛋白亚基变异较小,其控制位点为Glu—1和Gl—3或Gli—1;而低分子量部分变异较大,其控制位点多在Glu—3、Gli—2和Gli—3。这些变异具有一定的随机性。有关激光诱变对小麦面粉品质的影响有待进一步研究。     

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.     

Accumulation of Gliadin and Glutenin Polypeptides during Development of Normal and Sulphur-deficient Wheat Seed: Analysis using Specific Monoclonal Antibodies

A panel of monoclonal antibodies with various specificitiesfor wheat (Triticum aestivum L.) gluten polypeptides has beenused to analyse the accumulation of these polypeptides in theendosperm of developing wheat seeds grown under normal and sulphur-deficientconditions. Immunoblots of polypeptides fractionated by SDS-PAGEallowed a qualitative analysis of gliadin and HMW glutenin accumulationfor high- and low-sulphur seeds 8 d to 30 d after anthesis (d.a.a.).In addition, quantitative analysis of the deposition of variousgluten polypeptides was performed, with a solid-phase radioimmunoassayon extracts of seeds harvested 4–36 d.a.a. The initialaccumulation of HMW glutenin subunits was detectable at an earlierstage of development than that of gliadins for both normal andsulphur-deficient seeds. The initiation of detectable gliadinaccumulation was asynchronous with an order of alpha-gliadins,beta-, gamma- and some omega-gliadins and finally the remainingomega-gliadins. In sulphur deficiency, all gliadins reacheda constant proportion of the dry weight of the endosperm earlierthan in normal wheat, while a more marked increase in the proportionof HMW glutenin occurred late in grain development. The proteinblot studies also identified a putative omega-gliadin polypeptidewhich was detectable late in seed development and only in sulphur-deficientseeds. Key words: Wheat, seed maturation, immunoassay     

Variation in the HMW and LMW glutenin subunits from Spanish accessions of emmer wheat (Triticum turgidum ssp. dicoccum Schrank)

Emmer wheat (Triticum turgidum ssp. dicoccum Schrank) is hulled wheat that survives in marginal areas of the Mediterranean Region. The HMW and LMW glutenin subunit composition of 97 accessions of emmer wheat from Spain have been analysed by SDS-PAGE. For the HMW glutenin subunits, four allelic variants were detected for the Glu-A1 locus; one of them has not been previously described. For the Glu-B1 locus, three of the nine alleles detected have not been found before. A high degree of variation was evident for the LMW glutenin subunits, and up to 23 different patterns were detected for the B-LMW glutenin subunits. Considering both types of proteins (HMW and LMW), 30 combinations were found between all the evaluated lines. This wide polymorphism can be used to transfer new quality genes to wheat, and to widen its genetic basis. Received: 13 June 2000 / Accepted: 3 July 2000     

小麦新品种(系)Glu-1位点等位基因变异研究

应用SDS-PAGE技术分析了40份小麦新品种(系)的高分子量麦谷蛋白亚基等位基因变异。在Glu-1位点共检测到10种变异类型,其中Glu-Al位点有3种类型：Null、1、26 ,Glu-B1位点有5种类型：7 8、7 9、14 15、7、17 18,Glu-D1位点有2种类型：2 12、5 10;Null(54．3％)、7 8(51．4％)和2 12(62．9％)分别是Glu-Al、Glu-B1和Glu-D1位点上的主要亚基变异类型。另外,在2份材料的Glu-B1和Glu-D1位点各检测到1个新的亚基,分别命名为1By8．1和1Dx5^ 。Glu-1位点的Nei‘s遗传变异指数平均为0,5648,Glu-B1的遗传多样性最高,Glu-D1最低。供试小麦材料Glu-1位点的HMW-GS组合共有17种类型,以(Null,7 8,2 12)组合为主要类型,占31．4％;有9种亚基组合类型分别只在1份材料中出现,占26.1％。结果表明,这些小麦新品种(系)存在着丰富的亚基组合类型。     

Down-regulating γ-gliadins in bread wheat leads to non-specific increases in other gluten proteins and has no major effect on dough gluten strength

Background

Gliadins are a major component of gluten proteins but their role in the mixing of dough is not well understood because their contribution to wheat flour functional properties are not as clear as for the glutenin fraction.

Methodology/Principal Findings

Transgenic lines of bread wheat with γ-gliadins suppressed by RNAi are reported. The effects on the gluten protein composition and on technological properties of flour were analyzed by RP-HPLC, by sodium dodecyl sulfate sedimentation (SDSS) test and by Mixograph analysis. The silencing of γ-gliadins by RNAi in wheat lines results in an increase in content of all other gluten proteins. Despite the gluten proteins compensation, in silico analysis of amino acid content showed no difference in the γ-gliadins silenced lines. The SDSS test and Mixograph parameters were slightly affected by the suppression of γ-gliadins.

Conclusions/Significance

Therefore, it is concluded that γ-gliadins do not have an essential functional contribution to the bread-making quality of wheat dough, and their role can be replaced by other gluten proteins.     

Biochemical and molecular characterization of gliadins

Gliadins account for about 40–50% of the total proteins in wheat seeds and play an important role in the nutritional and processing quality of flour. Usually, gliadins can be divided into α-(α/β), γ-, and ω-groups, whereas the low-molecular-weight (LMW) gliadins are novel seed storage proteins. The low-molecular-weight glutenin subunits (LMW-GSs) are also designated as gliadins in a few publications. The genes encoding gliadins are mainly located on the short arms of group 6 and group 1 chromosomes, and not evenly distributed. Repetitive sequences cover most of the uncoding regions, which attributed greatly to the evolution of wheat genome. The primary structure of each gliadin is divided into several domains, and the long repetitive domains consist of peptide motifs. Conserved cysteine residues mainly form intramolecular disulfide bonds. The rare potential intermolecular disulfide bonds and the long repetitive domains play an important role in the quality of wheat flour. There is a general idea that gliadin genes, even prolamin genes, have a common origin and subsequent divergence leads to gene polymorphism. The γ-gliadins are considered to be the most ancient of the wheat prolamin family. Several elements in the 5′-flanking (e.g., CAAT and TATA box) and the 3′-flanking sequences have been detected, which has been shown to be necessary for the proper expression of gliadins. Published in Russian in Molekulyarnaya Biologiya, 2006, Vol. 40, No. 5, pp. 796–807. The text was submitted by the authors in English.