Polymorphism of Low Mr Glutenin Subunits in Triticum tauschii

A collection of 173 Triticum tauschii accessions was analysed to evaluate the variability of low molecular weight (M_r) glutenin subunits. These proteins were analysed by one-step one-dimensional sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) and were divided into B-, C- and D-subunits in accordance with their electrophoretic mobility. Extensive polymorphism, both in the number and electrophoretic mobility, was detected in lowM_r glutenin subunits present in T. tauschii. Thirty different patterns for B-subunits and forty-three for C-subunits were identified, some of which were with identical electrophoretic mobility than those observed in hexaploid wheat. Glutenin subunits with the same electrophoretic mobilities of low M_r D-glutenin subunits as well as subunits encoded at the Glu-D4 and Glu-D5 loci, were also detected in accessions of T. tauschii. These results provide new basic knowledge regarding the genetics variability of the low M_r glutenin subunits, as well as their potential to create novel germplasm for the improvement of wheat quality in breeding programs.     

Polymorphism of High MrGlutenin Subunits in Triticum tauschii: Characterisation by Chromatography and Electrophoretic Methods

A large collection of accessions of the wild wheat progenitor Triticum tauschii, the donor of the D genome of Triticum aestivum, was evaluated for the variability of high molecular weight (M_r) glutenin subunits by electrophoretic and chromatographic methods. A large range of allelic variation at theGlu-D^t1 locus was found in this collection and some novel subunits were observed in both x- and y-type glutenin subunits, including x- or y-type null forms. A few accessions showed three bands in the high M_rglutenin subunit region. However, only two subunits were observed when monomeric proteins were removed before SDS-PAGE analysis of polymeric proteins. The presence of monomeric proteins in this region is discussed. Characterisation of these subunits was also carried out by reversed phase-high performance liquid chromatography (RP-HPLC). Very different surface hydrophobicities were observed between x- and y-type subunits and in some cases it was possible to identify glutenin subunits with the same apparent molecular weight but different surface hydrophobicity. Differences in elution times that were detected when the same subunit was either reduced or reduced and alkylated were related to the number of cysteine residues present in each glutenin subunit. The newGlu-D^t1 glutenin subunits have the potential to enhance the genetic variability available for improving the quality of bread wheat (T. aestivum).     

Functional Properties of LowMrWheat Proteins.III. Effects on Composition of the Glutenin Macropolymer During Dough Mixing and Resting

The effect of lowM_rwheat protein addition on the amount and composition of the glutenin macropolymer (GMP) of dough was investigated for the three wheat cultivars Obelisk (weak), Camp Remy (medium strong) and Rektor (strong). During mixing, the amounts of high and lowM_rglutenin subunit classes, and of the individual subunits decreased. The proportion of highM_rglutenin subunits decreased and that of lowM_rglutenin subunits increased, indicating an inhomogeneous distribution of the two subunit classes within the polymers present in GMP. During resting, the amounts of the glutenin subunit classes and of individual subunits increased. Meanwhile, the proportion of highM_rglutenin subunits in GMP increased. LowM_rwheat protein addition retarded re-polymerisation in that the amounts of glutenin subunit classes and of individual highM_rglutenin subunits in GMP increased less than without addition. The proportion of highM_rglutenin subunits in GMP directly after mixing was also decreased by lowM_rwheat protein addition, and the proportion increased faster during dough resting, compared with the GMP in dough without lowM_rwheat protein addition. Eventually, after 90 or 135 min resting, no differences existed in the proportions in GMP from doughs with and without lowM_rwheat protein addition. LowM_rwheat protein addition had no specific effect on individual highM_rglutenin subunits, nor on the x-type/y-type subunit ratio in the GMP. In contrast, with increasing lowM_rwheat protein addition, a highly significant reduction in the subunit 10 or 12/subunit 9 ratio in GMP was observed. This finding is in line with the decrease in this ratio directly after mixing in GMP of the dough without lowM_rwheat protein addition. Since no specific effects were observed, it can be concluded that the lowM_rwheat protein acts rather unspecifically on the GMP of dough.     

Relationships Between Chromosome 1B-encoded Glutenin Subunit Compositions and Bread-making Quality Characteristics of Some Durum Wheat (Triticum turgidum) Cultivars

The high and low M_r glutenin subunit compositions (controlled by the Glu-1 loci and the Glu-B3 locus, respectively) and the bread-making quality characteristics of 26 durum wheat (Triticum turgidum) genotypes were determined. The relationships between quality parameters and Glu-B1 and Glu-B3 controlled glutenin subunit composition were also investigated. The Glu-A1-controlled null allele was present in all the genotypes. High M_r subunits 20, 6 + 8 and 7 + 8 occurred in similar proportions in the cultivars analysed. The Glu-B3 low M_r allelic variants, LMW-1 and LMW-2, were both represented, with LMW-1 being present in lower proportion. Flour protein, SDS-sedimentation volume, dough strength (Alveograph W value), dough mixing time and bread loaf volume varied among the genotypes. Most samples had high Alveograph tenacity/extensibility (P/G) ratios, typical of tenacious gluten character. SDS-sedimentation volume, dough strength, dough mixing time and bread loaf volume were all interrelated. An association with flour protein content was observed only for mixing time, while the Alveograph tenacity/extensibility ratio was not correlated with the other parameters. Comparisons within the Glu-B1 and Glu-B3 loci indicated that the high M_r subunit 7 + 8 and the low M_r subunit LMW-2 had significantly greater beneficial effects on gluten strength and bread-making quality than the high M_r subunits 6 + 8 or 20 and the low M_r subunit LMW-1, respectively. High M_r subunit 6 + 8 had greater beneficial effects on quality than subunit 20.     

High Mr Glutenin Subunits of Indian Wheat Cultivars: Association of Subunits 5 + 10 with the 1BL/1RS Wheat-Rye Translocation

The seed proteins of 110 commercially-released Indian wheat cultivars were fractionated using sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) to determine their high M_r glutenin subunit compositions. Amongst the cultivars, three alleles were indentified for the Glu-A1 locus (subunits 1, 2^* and the null phenotype), eight alleles for the Glu-B1 locus (7, 7 + 8, 7 + 9, 6 + 8, 20, 13 + 16, 17 + 18 and a new allele) and two for the Glu-D1 locus (2 + 12 and 5 + 10). Nine of the cultivars were heterogeneous and possessed two or more 'biotypes' with respect to high M_r subunits. The cultivars were also analysed for the presence of the 1BL/1RS wheat-rye translocation by SDS-PAGE of unreduced prolamins and hybridisation of DNA dot blots with a rye-telomere-specific repetitive DNA probe, pAW-161. Both methods revealed that the majority of newly-released Indian wheat cultivars carry this translocation, thus confirming the agronomic superiority of these lines. While most of the normal wheat cultivars possessed high M_r subunits 2 + 12, 14 of the 18 translocation cultivars had the allelic subunits 5 + 10, even though no selection was made for these subunits during the breeding process. This suggests that the subunits 5 + 10 may play a compensating role for the loss of dough strength associated with the 1BL/1RS translocation.     

Quality-related Epitopes of High Mr Subunits of Wheat Glutenin

Three hundred and eighty four immobilised overlapping nonapeptides, corresponding to the full amino acid sequences of three high M_r subunits of glutenin from bread wheat (Triticum aestivum) grain, were used to determine the linear epitopes recognised by four monoclonal antibodies. These antibodies were selected on the basis of significant and positive correlations between their binding to wheat flour extracts in a two-site ('sandwich') enzyme immunoassay and rheological measures of dough strength, an important aspect of bread wheat quality. The antibodies did not bind to a single, specific sequence but bound a series of related peptides in each high M_r glutenin subunit examined. The sequences recognised were not identical for the four antibodies, but in each case were in the central repeating domain of the high M_r glutenin subunits, and usually comprised regions that overlapped the degenerate repeat nonamer and hexamer sequences. High M_r glutenin subunits that have been associated with greater dough strength, such as the D-genome allelic products 1Dx5 and 1Dy10, displayed an increased number of the epitope sequences. The location of the epitopes in sequences of overlapping β-turns in the repetitive region supports the hypothesis that dough elasticity arises partly from β-turn-forming secondary structure in the repeat regions of the M_r glutenin subunits. Additional β-turn within high M_r subunits may extend their structure to allow increased interaction between the glutenin subunits and with the other proteins of the gluten complex, thus improving dough strength.     

Detection of y-type Subunit at theGlu-A1Locus in Some Swedish Bread Wheat Lines

Electrophoretic and reversed phase high performance liquid chromatographic (RP–HPLC) analyses were performed on gluten proteins extracted from flours milled from two different Swedish bread wheat lines; these lines have been reported to possess a novel highM_rglutenin subunit controlled by a gene at theGlu-A1locus, referred to as 21*. Although RP–HPLC indicated that subunit 21* has a surface hydrophobocity similar to that of the commonly occurring allelic subunits 1 or 2*, it differs from them in isoelectric point, being more basic when analysed by two dimensional gel electrophoresis (IEF/SDS–PAGE). RP–HPLC separations of highM_rglutenin subunits showed the presence of an additional peak, the behaviour of which was similar to that of y-type subunits encoded by genes at theGlu-A1ylocus and present only in wild wheatsT. urartu(AA) orT. dicoccoides(AABB). Based on chromatographic results and on the tight linkage observed with subunit 21*, it is suggested that the additional component (indicated as 21*y), present in the breeding lines analysed, corresponds to the y-type subunit encoded at theGlu-A1locus. Genes encoding the subunits 21* and 21*y were also analysed by polymerase chain reaction (PCR). Contrary to what was observed for the polypeptide itself, the gene corresponding to subunit 21* was similar in size to that encoding subunit 2* and shorter than that corresponding to subunit 1. Moreover, the amplification product corresponding to the active 21*y gene was shorter than that of the allelic inactive gene present in the bread wheat cultivar Cheyenne. As reported for other highM_rglutenin subunits, gene size differences observed were due to a different length of the repetitive region. Because cultivated polyploid wheats have been shown to have only the x-type subunit at theGlu-A1locus, it is speculated that the new combination, with both x- and y-type subunits expressed, might have been introgressed during breeding processes from the wild wheat progenitorsT. urartuorT. dicoccoides, which have genotypes expressing both types of subunits.     

Characterisation of polyclonal and monoclonal anti-peptide antibodies specific for some lowMrsubunits of wheat glutenin and their use in the detection of allelic variants atGlu-3loci

Polyclonal and monoclonal antibodies (Mabs) were produced against the major type ofN-terminal amino acid sequence of lowM_rglutenin subunits. The reactivities of these antibodies were determined using glutenin extracts of several bread wheat cultivars of known allelic composition. Analyses were performed by immunoblotting after one or two-dimensional electrophoresis. One Mab (Mab 6x1) was found to react with lowM_rglutenin subunits encoded by chromosomes 1B and 1D but not with subunits controlled by chromosome 1A. Only some of the subunits encoded at theGlu-D3locus were recognised. In contrast, this Mab reacted with all the subunits controlled by theGlu-B3locus. After single dimension SDS–PAGE, we observed significant differences between immunoblot patterns of cultivars expressing different lowM_rglutenin subunits from chromosome 1B. Mab6 x1 is a useful reagent for analysing the allelic composition at theGlu-B3locus.     

Biochemical Characterisation of a Novel Polymeric Protein Subunit from Bread Wheat (Triticum aestivum L.)

A new wheat endosperm protein subunit that was found in accessions belonging to different collections was identified by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE). Insoluble in 0·5 M NaCl, 70% ethanol, dimethyl sulphoxide (DMSO) and 50% propan-1-ol, it appeared in the pellet corresponding to the polymeric proteins along with high (HMW) and low molecular weight (LMW) glutenin subunits (GS). In the reduced form, it had an electrophoretic mobility between those two types of glutenin subunits. The apparent M_r of this novel protein was estimated by SDS-PAGE to be 71 000. N-terminal sequence and amino acid analyses indicated a composition similar to the ω-gliadins encoded by genes located on chromosome 1B. This protein can be ascribed to the D-subunits of LMW-GS with at least one cysteine residue that allows it to form part of the polymeric structure of glutenin, as shown by reaction with a fluorogenic reagent specific for sulphydryl groups. Fractions collected after size exclusion high-performance liquid chromatography (SE-HPLC) fractionation and further characterised by SDS-PAGE, confirm that the protein participates in the glutenin polymeric structure. An increase in its concentration was observed in fractions collected within the polymeric peak as elution time increased, implying that a larger amount of this protein is present in small size polymers. The role of this protein in the complex relationship between endosperm proteins and quality parameters is discussed in relation to its likely role as a chain terminator.     

Bread making quality of durum wheat genotypes with some novel glutenin subunit compositions

Durum wheat genotypes with some novel high M_r (high molecular weight, HMW) and low M_r (low molecular weight, LMW) glutenin subunits were grown in Sicily for two years of testing in order to compare their rheological and baking properties with respect to commercial durum wheat cultivars. Good bread making quality, as measured by Alveograph W and P/L, Farinograph and Mixograph parameters, and loaf volume was observed in genotypes combining high M_r subunits 2⁺, 1 or 11 encoded at the Glu-A1 locus with the so-called LMW-2 subunit group encoded at the Glu-B3 locus. The cultivar Avanzi, which carries high M_r subunit 2⁺ and LMW-2-like subunits, and the cultivars Dritto and Keops, which contain novel high and low M_r subunits, gave higher loaf volumes than control cultivars. The LMW-2 group subunits were found to be the main factor in determining dough strength (Alveograph W). The increase in the amount of high M_r subunits in genotypes with one expressed Glu-A1 gene may account for their improved rheological and baking properties.     

A Null Gli-D1 Allele with a Positive Effect on Bread Wheat Quality

The French wheat cultivar Darius (Da) has very good bread-making quality, even though it possesses the high M_r glutenin subunit combination 2, 7 and 12, which is associated with poor quality, and a null allele at the Gli-D1 locus. Darius was crossed with three cultivars, Corin (Cor), Capitole (Cap) and Courtot (Cou), of poor, medium, and good quality, respectively. The three progenies (Cor × Da, Cap × Da and Da × Cou) were used to investigate the genetic basis of the good quality of Darius. Gliadin and glutenin compositions were analysed by acid polyacrylamide gel electrophoresis (A-PAGE) and SDS-PAGE, respectively, from half F2 grains, and the quality was evaluated using six technological criteria for the corresponding plants. The high M_r glutenin subunit alleles of Darius produced a negative effect on quality. The null allele of Darius, characterised by the absence of the Gli-D1 encoded ω-gliadins, was associated significantly with higher dough tenacity P , and strength W (up to 40% in the Cor × Da progeny). Darius had a higher amount of B zone low M_r glutenin subunits than the three other cultivars. The null allele of Darius reduced the dough extensibility in the two first progenies, and probably increased the ratio of aggregated glutenin to unaggregated gliadins. These results demonstrated that using only one locus breeders can improve particular quality traits.     

Comparative Studies of High MrSubunits of Rye and Wheat. II. Partial Amino Acid Sequences

A panel of anti-peptide antibodies specific for each of the different N-terminal sequence types of B- and C-low molecular mass glutenin subunits (L M_rGS) were utilised in immunoblotting studies to identify the chromosomal location of genes encoding different sequences and to characterise the allelic variation of the encoding loci. The MET-type sequences were predominantly found among the B- subunits, while the α- and γ- sequences predominated in the C- subunits. The quantitatively major SHIPGLERPS sequence was found in both the B- and C- mobility regions. Using either biotypes in the cultivar, Aroona or genetic lines containing double rye chromosome 1 substitutions and thus expressing only single LM_r GS alleles, the sequences were determined for most of the major polypeptides expressed by each LM_r GS allele. The L M_rGS from different genomes encoded different numbers of each sequence type. Furthermore, different polypeptides within a particular «block» of subunits encoded by a given allele often had differing N-terminal sequences. However, subunits of similar electrophoretic mobilities encoded by different alleles at each locus usually had identical N-terminal sequences, suggesting that they may instead differ in the number of repeats. In Chinese Spring, genes encoding the SHIPGLERPS and METSHIPGL sequence types were predominantly present on chromosomes 1B and 1D, while the related METSRVPGL sequence was only encoded on 1D. In contrast, the METSCIPGL, α- and γ-sequences were encoded on each of chromosomes 1A, 1B and 1D. Several different electrophoretic and immunoblotting approaches using null lines suggested that some of the α-type L M_rGS may also be encoded by group 6 chromosomes, particularly 6D. The anti- SHIPGLERPS antibody also recognised chromosome 1B encoded β-, γ- and ω-gliadins, while the anti-METSRVPGL antibody recognised 1D encoded α- and β-gliadins. The absence of sequences within the major gliadin families that are highly homologous to the latter two N-terminal L M_rGS sequences may suggest that some monomeric L M_rGS could exist within the electrophoretically-resolved gliadins. These antibodies will provide valuable reagents for the study of the roles of particular L M_rGS families in the structure and function of the glutenin macropolymer, the role of different LM_r GS types in determining the influence of allelic variation of L M_rGS composition on dough properties, and potentially in the development of diagnostics for these flour components.     

Molecular and Biochemical Characterisation of HMW Glutenin Subunits fromT. tauschiiand the D Genome of Hexaploid Wheat

Electrophoretic (urea SDS–PAGE) and chromatographic (RP–HPLC) analysis was performed on 8 allelic variants of HMW glutenin subunits derived fromTriticum tauschiiand from the D genome of a hexaploid wheat species (Triticum macha) and hexaploid landraces. These subunits had been previously identified using SDS–PAGE. The characterisation revealed that subunits Dy10^tand Dy12^tfromT. tauschiicould be differentiated from their bread wheat counterparts using both urea SDS–PAGE and RP–HPLC. In the latter case, theT. tauschiiy-type subunits were clearly more hydrophobic than the Dy type subunits of bread wheat. The characterisation also suggested that subunit Dx5^t, derived from two separateT. tauschiiaccessions, did not contain the extra cysteine residue characteristic of Dx5 from bread wheat. RFLP analysis of the genes encoding the HMW glutenin subunits of interest suggested that the absence of Dx-type HMW glutenins in two hexaploid landraces was due to lack of expression of their encoding genes. The relationship betweenHindIII DNA fragment size and protein subunit size, as measured by electrophoretic mobility, is examined and discussed. Finally, the solubility properties of a HMW protein designated T1 (derived fromT. tauschiiaccession AUS 18913) suggested that it was not a HMW glutenin subunit as was previously thought. Further studies are needed to clarify the identity of this subunit.     

Isolation and characterization of a novel variant of HMW glutenin subunit gene from the St genome of Pseudoroegneria stipifolia

The x- and y-type high molecular weight (HMW) glutenin subunits are conserved seed storage proteins in wheat and related species. Here we describe investigations on the HMW glutenin subunits from several Pseudoroegneria accessions. The electrophoretic mobilities of the HMW glutenin subunits from Pd. stipifolia, Pd. tauri and Pd. strigosa were much faster than those of orthologous wheat subunits, indicating that their protein size may be smaller than that of wheat subunits. The coding sequence of the Glu-1St1 subunit (encoded by the Pseudoroegneria stipifolia accession PI325181) was isolated, and found to represent the native open reading frame (ORF) by in vitro expression. The deduced amino acid sequence of Glu-1St1 matched with that determined from the native subunit by mass spectrometric analysis. The domain organization in Glu-1St1 showed high similarity with that of typical HMW glutenin subunits. However, Glu-1St1 exhibited several distinct characteristics. First, the length of its repetitive domain was substantially smaller than that of conventional subunits, which explains its much faster electrophoretic mobility in SDS-PAGE. Second, although the N-terminal domain of Glu-1St1 resembled that of y-type subunit, its C-terminal domain was more similar to that of x-type subunit. Third, the N- and C-terminal domains of Glu-1St1 shared conserved features with those of barley D-hordein, but the repeat motifs and the organization of its repetitive domain were more similar to those of HMW glutenin subunits than to D-hordein. We conclude that Glu-1St1 is a novel variant of HMW glutenin subunits. The analysis of Glu-1St1 may provide new insight into the evolution of HMW glutenin subunits in Triticeae species.     

7OE+8*亚基对东北强筋小麦品种品质性状影响研究

小麦品质改良是东北春麦区强筋小麦育种的主要目标之一。Glu-B1位点7^OE+8^*亚基为超强筋小麦品种必备基因。为了明确该亚基在东北春麦区强筋小麦遗传背景下的品质遗传效应,本研究利用分子标记和选择回交相结合的手段,将7^OE+8^*亚基定向导入到强筋小麦品种龙麦26和龙麦35（Glu-B1位点均为7+9亚基）的遗传背景之中,对BC₅F₁、BC₆F₁群体和自交BC₆F₂鉴定获得的纯合品系进行7^OE+8^*亚基遗传效应评价。结果表明,在强筋小麦品种龙麦26(7+9)和龙麦35(7+9)遗传背景下转入7^OE+8^*亚基后,其干面筋、面筋指数、形成时间、稳定时间、断裂时间、拉伸面积、延伸性和最大抗延阻力等品质指标3年平均分别提高1.3%(P=0.82)和1.8%(P=0.49)、6.6%(P=0.59)和4.7%(P=0.37)、55.0%(P=0.24)和35.8%(P=0.56)、44.5%(P=0.43)和32.8%(P=0.73)、41.4%(P=0.31)和30.0%(P=0.66)、28.0%(P=0.05)和23.4%(P=0.37)、6.5%(P=0.47)和5.8%(P=0.42)、19.5%(P=0.31)和18.0%(P=0.38);Zeleny沉降值2年平均分别提高6.8%和11.4%。以上结果表明,在2个强筋小麦品种遗传背景下,Glu-B1位点转入7^OE+8^*亚基较7+9亚基对各项品质指标改良均存在正向效应,但提高幅度存在差异,对形成时间、稳定时间、断裂时间、最大抗延阻力、拉伸面积等衡量面筋质量的指标提高幅度更大,表明该亚基对面筋质量改良效应显著。综上所述,7^OE+8^*亚基可作为东北春麦区强筋小麦遗传背景下品质性状进一步改良的优选基因,为超强筋小麦育种的重要基因资源。     

RP–HPLC and Capillary Electrophoresis of Subunits from Glutenin Isolated by SDS and Osborne Fractionation

The polypeptide subunits present in SDS-unextractable glutenin, the glutenin macropolymer (GMP) and the 70% (v/v) ethanol unextractable protein, the Osborne glutenin fraction, of various cultivars were separated by RP–HPLC and capillary electrophoresis (CE) under denaturing (urea and SDS, respectively) and reducing conditions. In addition, the SDS-extractable protein was separated by CE. HighM_rglutenin subunits were well separated by CE, while the separation of lowM_rglutenin subunits was better by RP–HPLC. HighM_rglutenin subunits separated by RP–HPLC were collected and separated by CE. The subunits were identified unequivocally using the combined information from these two techniques and from SDS–PAGE patterns using the cvs. Spring and Troy Spring. By both RP–HPLC and CE it could be demonstrated for flour from three wheat cvs. (Camp Remy, Obelisk and Rektor) and a blend of flour from two of those cvs. (Camp Remy/Obelisk) that the highM_rglutenin subunit content of the GMP was 29–31%. In contrast, the SDS-extractable protein consisted of 4–6% highM_rglutenin subunits, which accounted for 14–23% of the highM_rglutenin subunits in flour. Interestingly, the SDS-extractable highM_rglutenin subunits consisted mainly (90–96%) of x-type subunits whereas, in the GMP, only 70–75% of the highM_rsubunits were x-type subunits. Although the SDS extractable protein was not separated by RP–HPLC, results similar to those obtained by CE could be inferred from the subtraction of the contents of glutenin subunits of the GMP from the contents in the Osborne glutenin fraction. The results suggest that x- and y-type highM_rglutenin subunits may have a different role in the structure (size and composition) of glutenin polymers.     

Purification and Characterisation of HighMrGlutenin Subunit 20 and its Linked y-type Subunit from Durum Wheat

HighM_rglutenin subunit 20 and its linked y-type subunit, present in the durum wheat cultivar Lira, were purified by preparative reversed-phase high-performance liquid chromatography (RP–HPLC). Amino acid and N-terminal sequence analysis of subunit 20y confirmed that it corresponded to a y-type subunit. Moreover, the number and position of the cysteine residues in subunit 20 were determined by alkylation with the fluorogenic reagent 7-fluoro-4-sulfamoyl-2,1,3,-benzoxadiazole (ABD-F) and subsequent enzymic digestion with trypsin. N-terminal amino acid sequence analysis of the fluorescent peptides showed that subunit 20 had only two cysteine residues, one in the N-terminal region and the other in the C-terminal domain.     

Preparative Separation of High and Low Molecular Weight Subunits of Glutenin from Wheat

Wheat flour was washed with Tris-HCl buffer containing 4% Triton X114 before extracting the residual gluten with 70% ethanol. The glutenin extraction with 50% ethanol was performed at various ratios of DTT/protein; a minimum ratio of 0·1 g/g was needed to solubilise the maximum amount of glutenin. An experimental design was used to optimise the extraction conditions to obtain the best yield and purity of lowM_rand highM_rglutenin subunits. The purity of each glutenin subunit fraction was measured by RP-HPLC analysis after reduction and alkylation. Both temperature and protein concentration had an effect on the preparation of these fractions. An increase in the protein concentration enhanced the yield of the highM_rglutenin fraction and simultaneously decreased that of the lowM_rglutenin. Using the Deringer desirability function, conditions giving the optimum separation were determined. The procedure was scaled up and permitted the preparation of 0·96 g of highM_rand 1·64 g of lowM_rglutenin subunits from 5 g of gluten. The purities of these fractions, determined by RP-HPLC, were 90% and 95%, respectively, and their amino acid compositions were similar to those of high and lowM_rsubunits separated by RP-HPLC.     

聚合7OE亚基1B/1R易位系材料的创制及其品质研究

为提高小麦1B/1R易位系的加工品质,本研究选用高分子量麦谷蛋白亚基组成为1/7+9/2+12的小麦1B/1R易位系品种科农199为母本,与高分子量麦谷蛋白亚基组成为1/7^OE+8^*/5+10的强筋春小麦品种津强6号杂交,利用分子标记在F₄代株系中筛选到一个7^OE亚基基因与黑麦碱基因聚合在同一条染色体上的1B/1R易位系材料。PCR结果显示,该聚合材料和非聚合材料在Glu-A1和Glu-D1位点没有差异。在温室种植条件下,对这些聚合材料和非聚合材料及其亲本进行麦谷蛋白溶胀指数(SIG)测定,结果表明,与1B/1R易位系亲本科农199比较,聚合5+10优质亚基后SIG值显著提高,聚合7^OE优质亚基后,SIG值进一步显著提高,部分聚合材料达到了强筋亲本津强6号的水平。将聚合材料和非聚合材料及其亲本种植于大田,发现聚合5+10和7^OE优质亚基株系的乳酸-SDS溶剂保持力(LA-SDS SRC)和SDS沉降值均显著高于只聚合5+10优质亚基的株系,但未达到强筋亲本...     

Antibodies to N-terminal Peptides of Low MrSubunits of Wheat Glutenin. II. Detection of Subunits Encoded by Different Loci

A panel of anti-peptide antibodies specific for each of the different N-terminal sequence types of B- and C-low molecular mass glutenin subunits (L M_rGS) were utilised in immunoblotting studies to identify the chromosomal location of genes encoding different sequences and to characterise the allelic variation of the encoding loci. The MET-type sequences were predominantly found among the B- subunits, while the α- and γ- sequences predominated in the C- subunits. The quantitatively major SHIPGLERPS sequence was found in both the B- and C- mobility regions. Using either biotypes in the cultivar, Aroona or genetic lines containing double rye chromosome 1 substitutions and thus expressing only single LM_r GS alleles, the sequences were determined for most of the major polypeptides expressed by each LM_r GS allele. The L M_rGS from different genomes encoded different numbers of each sequence type. Furthermore, different polypeptides within a particular «block» of subunits encoded by a given allele often had differing N-terminal sequences. However, subunits of similar electrophoretic mobilities encoded by different alleles at each locus usually had identical N-terminal sequences, suggesting that they may instead differ in the number of repeats. In Chinese Spring, genes encoding the SHIPGLERPS and METSHIPGL sequence types were predominantly present on chromosomes 1B and 1D, while the related METSRVPGL sequence was only encoded on 1D. In contrast, the METSCIPGL, α- and γ-sequences were encoded on each of chromosomes 1A, 1B and 1D. Several different electrophoretic and immunoblotting approaches using null lines suggested that some of the α-type L M_rGS may also be encoded by group 6 chromosomes, particularly 6D. The anti- SHIPGLERPS antibody also recognised chromosome 1B encoded β-, γ- and ω-gliadins, while the anti-METSRVPGL antibody recognised 1D encoded α- and β-gliadins. The absence of sequences within the major gliadin families that are highly homologous to the latter two N-terminal L M_rGS sequences may suggest that some monomeric L M_rGS could exist within the electrophoretically-resolved gliadins. These antibodies will provide valuable reagents for the study of the roles of particular L M_rGS families in the structure and function of the glutenin macropolymer, the role of different LM_r GS types in determining the influence of allelic variation of L M_rGS composition on dough properties, and potentially in the development of diagnostics for these flour components.