Disulphide Bonds in Wheat Gluten Proteins

Disulphide bonds play a key role in determining the structure and properties of wheat gluten proteins. Comparison of the sequences of monomeric gliadins and polymeric glutenin subunits allows the identification of conserved and variant cysteine residues. Direct disulphide bond determination demonstrates that the conserved cysteine residues present in S-rich prolamins (α-type gliadins, γ-type gliadins and LMW subunits) form intra-chain disulphide bonds while additional cysteines residues present only in the LMW subunits form inter-chain bonds with cysteines in HMW subunits and other LMW subunits. Conserved and variant cysteine residues are also present in the HMW subunits but their patterns of disulphide bond formation are less well understood. Further information on the abilities of individual cysteine residues to form intra- and inter-chain disulphide bonds has also been obtained by heterologous expression of wild type and mutant proteins inE. coliand, in the case of the HMW subunits, by examination of the patterns of dimers recovered on partial reduction of glutenin or resulting from the expression of subunits in transgenic tobacco plants. Wheat gluten proteins are folded and assembled within the lumen of the endoplasmic reticulum of the developing endosperm cells, where disulphide bond formation and exchange may be catalysed by the enzyme protein disulphide isomerase. Similarly, disulphide bond reduction, for example to facilitate mobilisation during germination, may be catalysed by thioredoxinh. Understanding the mechanism and specificity of disulphide bond formation in gluten is crucial for the manipulation of its functional properties by genetic engineering or chemical modification.     

Chain Extension and Termination as a Function of Cysteine Content and the Length of the Central Repetitive Domain in Storage Proteins

Analogue glutenin proteins (ANGs) based on the barley seed storage protein C-hordein, modified to contain N- and/or C-terminal cysteine residues and varying lengths of repetitive domain, have been purified from a bacterial expression system. The proteins were used to modify the mixing, extension and baking properties of wheat flour doughs in small-scale tests. Comparison of the effects of simple addition of the proteins versus their chemical incorporation into the glutenin macropolymer has allowed us to assess the importance of cysteine content, cysteine position and repetitive domain length in determining dough mixing and processing properties. When incorporated, the proteins, along with small synthetic oligopeptides based on their N- and C-terminal sequences, change the amount of large glutenin polymers, and hence dough properties, in ways consistent with their action as either chain terminators (polypeptides with single cysteine residues) or chain extenders (polypeptides with two cysteine residues, one in either terminal domain). The gross effects of chain extension and termination may be further fine-tuned by modification of the molecular size of the incorporated proteins through alteration of their repetitive domains.     

Incorporation of high-molecular-weight glutenin subunits into doughs using 2 gram mixograph and extensigraphs

To study the contributions of high-molecular-weight glutenin subunits (HMW-GS) to the gluten macropolymer and dough properties, wheat HMW-GS (x- and y-types) are synthesized in a bacterial expression system. These subunits are then purified and used to supplement dough mixing and extensigraph experiments through dough partial reduction and reoxidation to allow these exogenously added HMW-GS to incorporate into gluten polymers. Detailed results are given for seven mixing and two extension parameters. HMW-GS synthesized in bacteria behaved similarly under these conditions to the same HMW-GS extracted from wheat flour. These experiments initially focused on the HMW-GS of the D-genome of hexaploid wheat encoded at the Glu-D1 locus; e.g. the Dx2, Dx5, Dy10, and Dy12 subunits. Experiments used five different flours and results are shown to be consistent when normalized to results from Dx5. The incorporation of Dx-type subunits into the gluten disulfide bonded network has greater effects on dough parameters than incorporation of Dy-type subunits. When Glu-D1 x- and y-type subunits are incorporated together, there are synergistic effects greater than those with either subunit type alone. This synergistic effect was greatest with approximately equal amounts of Dx- and Dy-type subunits - implying a 1:1 stoichiometric relationship.     

Proteomic analysis of wheat recombinant inbred lines: Variations in prolamin and dough rheology

To investigate the impact of the 1BL.1RS translocation on dough strength and to understand how 1BL.1RS genotypes may overcome the loss of Glu-B3 and Gli-B1, proteomic profiles of 16 doubled haploid (DH) lines of similar glutenin composition but of different strength, as measured by Chopin's alveograph, were compared. The results showed that 32 spots, mainly prolamins, were differentially expressed and that five others were specific to high-strength DH lines. The identification and quantification of the prolamin fractions on the two-dimensional (2D) electrophoresis gels demonstrated that the high-molecular weight glutenin sub-unit (HMW-GS) were up-regulated by 25% in 1BL.1RS DH lines, even though the corresponding genes were not located on the missing 1BS chromosome. The γ-gliadins were also up-regulated (by 36%) in such lines to counterbalance, to some extent, the loss of LMW-GS of Glu-B3. The polymeric prolamin fractions also accumulated in high-tenacity lines and decreased in high-extensibility lines confirming the role of the inter-chain disulfide bonds in resistance to deformation. In contrast, the monomeric fraction of α-gliadin favored extensibility and decreased tenacity by increasing the accumulation (+12%) of α-gliadins in high-extensibility lines; the Gli-A1 allele of the parent Toronit was found to be more abundant when compared to the Gli-A1 allele of parent 211.12014.     

Redox Reactions in Wheat Dough as Affected by Ascorbic Acid

Ascorbic acid (AA) is used as bread improver, as its addition to dough causes an increase in loaf volume and an improvement in crumb structure. To explain these effects we review the stereospecificity of the improver action and the properties of ascorbate oxidase and glutathione dehydrogenase and the occurrence of low molecular thiols in flour and their concentration changes during dough mixing in the presence and absence of AA. On the basis of the results the improver action of AA is explained by a reaction sequence leading to a rapid removal of endogenous GSH, which otherwise would cause dough weakening by sulphhydryl/disulphide interchange reactions with gluten proteins. To test this hypothesis the binding sites of endogenous GSH in gluten proteins have been determined by the addition of³⁵S-labelled GSH as a tracer to flour before dough mixing. The distribution of radioactivity in the gliadin and glutenin fractions of gluten obtained from dough indicates that the major portion of GSH is bound to glutenins. The isolation and sequence analysis of radioactive cystine peptides from an enzymatic digest of glutenins demonstrates that GSH is almost exclusively linked to those cysteine residues of LMW subunits that have been proposed to form intermolecular disulphide bonds.     

Antigenicity of Wheat Prolamins: Detailed Epitope Analysis using a Panel of Monoclonal Antibodies

Putative continuous epitopes, recognised by five panels of monoclonal antibodies (MAb) with differing specificities for gliadins and glutenin subunits, were identified using overlapping nonapeptides. These peptides corresponded to the entire sequence of an α/β-gliadin, a γ-gliadin, an ω-prolamin (homologous to ω-gliadin), a low molecular weight glutenin subunit (L M_rGS) and several high molecular weight glutenin subunits (HM_r GS). Antibodies that bound to γ- or ω-gliadins, L M_rGS or HM_r GS bound to the peptides at similar concentrations used normally in direct ELISA, but little binding to the peptides was seen for several antibodies that bound specifically to small groups of α/β-gliadins. Epitopes for these antibodies in α/β-gliadin may be discontinuous (i.e. derived from amino acid residues that are brought together by folding of the polypeptide chain or by juxtaposition of two polypeptide chains), since binding of these antibodies to gliadins was greatly decreased following the reduction of intra-molecular disulphide bonds. While some regions in particular subunits were immunodominant, such as the cysteine–cysteine containing peptide found in the central domain of many prolamins, a diversity of reaction patterns was found. Cross-reaction of antibody with peptides from other prolamin families was often due to binding to a peptide having significant sequence homology, but in some cases no homology was obvious. Some major trends were as follows. Antibodies which bound to most or all H M_rGS recognised the central repeat region, while those that were selective for one or two subunits bound to epitopes in the unique N- and/or C-terminal domains. A high proportion of the epitopes recognised by MAb to α-, β-, ω-gliadins and L M_rGS contained cysteine; these MAb may be useful in detecting covalent binding sites within or between subunits. Although a number of MAb bound a wide range of gliadins and GS, several of these recognised single (and differing) epitopes in the target proteins. However, comparatively few MAb recognised epitopes from either the N- or C-terminal regions of the target proteins. Several explanations are possible; either these regions are buried in the immunogen and not accessible for antibody production or alternatively the repeat sequences are immunodominant.     

Significance of LMW-GS and HMW-GS for Dough Extensibility: «Addition» versus «Incorporation» Protocols

Low molecular weight (LMW-GS) and high molecular weight glutenin subunits (HMW-GS) were added to a base flour using both «addition» and «incorporation» protocols. «Incorporation» of glutenin subunits into the glutenin network of the base flour was performed by partial (reversible) reduction and subsequent reoxidation of the glutenin network in the presence of the added glutenin subunits whereas, in the «addition» protocol, glutenin subunits were added without reduction/oxidation. The effects of both «addition» and «incorporation» of alkylated and unalkylated LMW-GS and HMW-GS on dough extension parameters maximum resistance (MR) and extensibility (EX) were compared and thoroughly discussed. HMW-GS and LMW-GS had totally different effects on dough extensibility. «Addition» of LMW-GS significantly decreased both MR and EX whereas HMW-GS caused a significant increase in MR. «Incorporation» of LMW-GS caused a decrease in MR whereas HMW-GS clearly increased MR. The similarity in effects obtained with «addition» and «incorporation» of glutenin subunits indicated that, even with «addition», glutenin subunits can be partially incorporated into the glutenin network in the presence of oxygen. Alkylated and unalkylated glutenin subunits had different effects. This was probably caused by the effect of free sulphydryl groups in unalkylated subunits (possibility of SS/SH exchanges and/or incorporation) and/or the effect induced by introduction of alkylated derived substituents. A protocol for «incorporation with excess KIO₃» was developed to exclude the possible effect of a lowering of the available oxidant concentration by oxidation of free sulphydryl groups in glutenin subunits. However, the use of high levels of oxidant in the «incorporation with excess KIO₃» protocol seems to overrule the effects of added glutenin subunits or may force glutenin subunits to incorporate differently from what can be observed under gentle oxidation conditions. Therefore, «incorporation with excess KIO₃» is not suitable for studying the effects of incorporation of glutenin subunits on dough extensibility.     

Correlation of glutenin macropolymer with viscoelastic properties during dough mixing

Although significant correlations exist for glutenin macropolymer (GMP) quantity and rheological properties/bread making quality of dough, little information about these links is available. The relationship between GMP contents measured by UV absorption method/RP-HPLC and dough viscoelastic properties determined by TA-XT2i texturometer from three wheat varieties (Xiaoyan6, Yumai56 and Zhengnong8805) during mixing was investigated. GMP contents of doughs decrease significantly (P<0.05) during mixing. During the initial mixing stage, amounts of the HMW-GS and LMW-GS and GMP decrease significantly (P<0.05). Their contents begin to increase beyond peak dough development time (DDT). This indicates that during further mixing after peak DDT some glutenin subunits are incorporated into GMP by repolymerization. The HMW/LMW-GS ratio has a significant effect on load-deformation properties (area, resistance and extensibility) of dough. The varieties behaved differently in relation to the contribution of their HMW-LMW-GS ratio to the rheological properties.     

Evidence for the Presence of Only One Cysteine Residue in the D-type Low Molecular Weight Subunits of Wheat Glutenin

D-type low molecular weight subunits of bread wheat glutenin have ω-gliadin type N-terminal amino acid sequences, but are incorporated into the glutenin polymers because of the presence of cysteine residues. In order to determine the number and position of cysteine residues, ID-encoded D-type low molecular weight subunits of wheat glutenin were purified from the cv. Chinese Spring using a procedure that allowed high recovery. Comparison of the molecular weights of alkylated and unalkylated subunits by MALDI mass spectrometry indicated the presence of only one cysteine residue per molecule. This was supported also by the detection of dimers of D subunits in gluten. An internal sequence of 62 amino acids preceding the cysteine was obtained, but it was not possible to identify the cysteine residue, either because it was not within the range of N-terminal sequencing of peptides obtained, or because it was present in one of the two unidentified positions.     

Effect of glucose oxidase,transglutaminase, and pentosanase on wheat proteins: Relationship with dough properties and bread-making quality

Glucose oxidase (Gox), transglutaminase (TG), and pentosanase (Pn) were investigated for their effect on bread quality. The changes introduced in wheat protein by the action of these enzymes were analysed to explain dough behaviour. Gox treatment decreased free sulphydryl groups (SHf), increased glutenin macropolymer contents, and modified the electrophoretic pattern of protein fractions. Gox modified mainly albumin, globulin, and glutenin, forming large protein aggregates. These modifications explained the high strength of the dough and the low bread specific volume of samples with Gox. TG treatment modified solubility in SDS of protein and decreased glutenin macropolymer content. However, it formed large protein aggregates. The new cross-linking bonds introduced by this enzyme were different to S–S bonds and, consequently, the dough was less extensible and showed high resistance. Pn treatment increased water soluble pentosan content. Moreover, in these samples a tendency to increase SHf content was observed. In addition, Pn increased protein solubility in isopropanol, which indicates that the reduction of pentosans size decreases steric impediment of insoluble pentosans, thus increasing interaction among protein and making their extraction easier. These changes at the microscopic level allowed explaining the formation of softer dough and the production of higher specific volume in breads with Pn.     

Expression and Functional Analysis ofMr58 000 Peptides Derived from the Repetitive Domain of High Molecular Weight Glutenin Subunit 1Dx5

A highly repetitiveM_r58 000 peptide based on residues 102 to 643 of subunit 1Dx5 and forms containing one to four cysteine residues were expressed inE. coliand purified to homogeneity. Incorporation into dough using a 2 g Mixograph showed that most peptides resulted in reduced strength, which was possibly due to dilution or chain termination of glutenin polymers. However, a form containing four cysteines (two each close to the N-terminus and C-terminus) resulted in increased strength, indicating that the repetitive domains of the HMW subunits are sufficient to contribute to dough strength when incorporated into glutenin polymers.     

The low-molecular-weight glutenin subunits of wheat gluten

Low-molecular-weight glutenin subunits (LMW-GS) are polymeric protein components of wheat endosperm and like all seed storage proteins, are digested to provide nutrients for the embryo during seed germination and seedling growth. Due to their structural characteristics, they exhibit features important for the technological properties of wheat flour. Their ability to form inter-molecular disulphide bonds with each other and/or with high-molecular-weight glutenin subunits (HMW-GS), is important for the formation of the glutenin polymers, which are among the biggest macromolecules present in nature, and determine the processing properties of wheat dough. Explanation of the structural basis for these correlations continues to intrigue researchers and, while earlier emphasis had been on HMW-GS, considerable attention is now being focused on the LMW-GS.LMW-GS are a highly polymorphic protein complex, including proteins with gliadin-type sequences. Difficulty in separating single components, arising from the complexity of the group, has limited the characterisation of the individual proteins and the establishment of clear-cut relationships with quality parameters.Here we review results concerning different aspects of LMW-GS, including their structural characteristics, genetic control, and relationships with quality parameters. In addition, we emphasise the distinction between the components with sequences unique to the LMW-GS fraction and those behaving like glutenin subunits (incorporated into polymers), but with sequences corresponding to gliadins.     

Effect of hydrostatic pressure and temperature on the chemical and functional properties of wheat gluten II. Studies on the influence of additives

Cysteine, N-ethylmaleinimide, radical scavengers, various salts or urea were added to wheat gluten. After treatment at increasing pressure (0.1–800 MPa) and temperature (30–80 °C) the resulting material was analysed by micro-extension tests and an extraction/HPLC method to measure protein solubility. Furthermore, cysteine was added to isolated gliadin and glutenin prior to high-pressure treatment and protein solubility was determined. The resistance to extension of gluten strongly increased and the solubility of gliadin in aqueous ethanol decreased with increasing pressure and temperature. As compared to experiments without additive the observed effects were much stronger. Isolated gliadin turned largely insoluble in aqueous ethanol when cysteine was added prior to high-pressure treatment. The S-rich α- and γ-gliadins were much more strongly affected than the S-poor ω-gliadins pointing to a disulphide related mechanism. Monomeric gliadin components were completely recovered after reduction of the aggregates with dithioerythritol. In contrast, samples without free thiol groups such as isolated gliadins or with SH groups, which had been blocked by N-ethylmaleinimide, were hardly affected by high-pressure treatment. The addition of radical scavengers to gluten showed no effect in comparison to the control experiment, indicating that a radical mechanism of the high-pressure effect can be excluded. The observed effects can be explained by thiol-/disulphide interchange reactions, which require the presence of free thiol groups in the sample. The addition of salts and urea showed that unfolding of the protein due to weakening of interprotein hydrogen bonds is strongest for ions with a high radius (e.g. thiocyanate). This leads to weakening of gluten at ambient pressure but it facilitates high pressure induced reactions, e.g. of disulphide bonds.     

The location of disulphide bonds in α-type gliadins

Gliadin prepared from gluten of the cultivar Rektor by extraction with 70% (v/v) aqueous ethanol adjusted to pH 5.5 was separated by RP-HPLC. Amongst 23 components obtained, two α-type gliadins (α3- and α8-gliadin) were selected for the determination of disulphide bonds. After both proteins were digested with thermolysin, differential RP-HPLC (chromatography prior to and after reduction of disulphide bonds) was used for the detection of cystine peptides. Two cystine peptides from α3-gliadin and three cystine peptides from α8-gliadin were isolated by RP-HPLC. The resulting peptides were reduced and alkylated with 4-vinylpyridine, separated by RP-HPLC and their amino acid sequences determined. The cystine peptides from both α-type gliadins had similar structures, and the corresponding fragments had homologous sequences. One cystine peptide of each gliadin was composed of three fragments linked by two disulphide bonds. The second cystine peptide consisted of two fragments linked by one disulphide bond. The third cystine peptide derived from α8-gliadin was different from the second peptide in one position of the sequences (glutamic acid instead of glutamine). Comparing complete sequences of α-type gliadins described in the literature, the cystine peptides from α3- and α8-gliadins were identical with corresponding sequences of clones A1235 and A212, respectively¹¹. The structures of the cystine peptides analysed indicate one intramolecular disulphide bond within domain III of α-type gliadins and two disulphide bonds between domains III and V. The linkages found correspond to homologous linkages determined for low M_r subunits of glutenin and glutenin-bound γ-type gliadins⁶. Obviously, these intramolecular disulphide bonds are not linked randomly, but are strongly directed.     

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.     

Effect of hydrostatic pressure and temperature on the chemical and functional properties of wheat gluten: Studies on gluten, gliadin and glutenin

The effect of hydrostatic pressure (0.1–800 MPa) in combination with various temperatures (30–80 °C) on the chemical and physical properties of wheat gluten, gliadin and glutenin was studied. Chemical changes of proteins were determined by extraction, reversed-phase high-performance liquid chromatography (HPLC), sodium dodecylsulphate (SDS) polyacrylamide gel electrophoresis (PAGE), circular dichroism (CD) spectroscopy, thiol measurement and studies on disulphide bonds. Rheological changes were measured by extension tests and dynamic stress rheometry. Treatment of gluten with low pressure (200 MPa) and temperature (30 °C) increased the proportion of the ethanol-soluble fraction (ESF) and decreased gluten strength. The enhancement of both pressure and temperature provoked a strong reduction of the ESF and the thiol content of gluten. Within gliadin types, cysteine containing α- and γ-gliadins, but not cysteine-free ω-gliadins were sensitive to pressure and were transferred to the ethanol-insoluble fraction. Disulphide peptides isolated from treated gluten confirmed that cleavage and rearrangement of disulphide bonds were involved in pressure-induced reactions. Increased pressure and temperature induced a significant strengthening of gluten, and under extreme conditions (e.g. 800 MPa, 60 °C), gluten cohesivity was lost. Isolated gliadin and glutenin reacted differently: solubility, HPLC and SDS-PAGE patterns of gliadin having a very low thiol content were not influenced by pressure and heat treatment; only conformational changes were detected by CD spectroscopy. In contrast, the properties of isolated glutenin having a relatively high thiol content were strongly affected by high pressure and temperature, similar to the effects on total gluten.     

Effect of incorporation of an i-type low-molecular-weight glutenin subunit and a modified γ-gliadin in durum and in bread wheat doughs as measured by micro-mixographic analyses

The effects of incorporation of an i-type low-molecular-weight glutenin subunit (LMW-i) and of a modified γ-gliadin showing an additional cysteine residue, on 2 g Mixograph parameters of durum (biotypes 42 and 45 of the Italian cv. Lira) and bread wheat (Australian cv. Kukri) doughs were studied. In bread wheat flour incorporation of the modified γ-gliadin resulted in a significant decrease in dough strength (decreased mixing time and peak resistance), but at the same time it produced a slight increase in dough stability (decreased resistance to breakdown). The incorporation of the LMW-i type into bread wheat dough had minimal effects on dough mixing requirements. The incorporation of both LMW-i type and modified γ-gliadin in durum wheat doughs produced a significant decrease in the overall dough strength, especially in Lira 45 biotype doughs. Reversed phase high-performance liquid chromatography (RP-HPLC), size exclusion high-performance liquid chromatography (SE-HPLC) and two-dimensional gels analyses of control and reconstituted semolina doughs showed that the two polypeptides were in the polymeric fraction. The effect of the incorporation of the two polypeptides in durum and bread wheat doughs showed remarkable differences and the reasons for this is discussed in terms of both intrinsic differences between wheat flour and durum semolina and in methodological approaches.     

Disulphide structure of high-molecular-weight (HMW-) gliadins as affected by terminators

This study aimed at elucidating SS-bonds of HMW-gliadins (HGL) from wheat with the focus on terminators of glutenin polymerisation. HGL from wheat flour extracts non-treated or treated with the S-alkylation reagent N-ethylmaleinimide (NEMI) were compared. HGL from wheat flour Akteur were isolated, hydrolysed with thermolysin and the resulting peptides pre-separated by gel permeation chromatography and analysed by liquid chromatography/mass-spectrometry using alternating electron transfer dissociation/collision-induced dissociation. Altogether, 22 and 28 SS-peptides from samples without and with NEMI treatment, respectively, were identified. Twenty-six peptides included standard SS-bonds of α- and γ-gliadins, high-molecular-weight and low-molecular-weight glutenin subunits. Eleven SS-bonds were identified for the first time. Fifteen peptides unique to HGL contained cysteine residues from gliadins with an odd number of cysteines (ω5-, α- and γ-gliadins). Thus, gliadins with an odd number of cysteines, glutathione and cysteine had acted as terminators of glutenin polymerisation. Decisive differences between samples without and with NEMI treatment were not obvious showing that the termination of polymerisation was already completed in the flour. The two HGL samples, however, were different in the majority of ten peptides that included disulphide-linked low-molecular-weight (LMW) thiols such as glutathione and cysteine with the former being enriched in the non-treated HGL-sample.     

Influence of sulphur fertilisation on quantities and proportions of gluten protein types in wheat flour

Although different supplies of sulphur (S) during wheat growth are known to influence the quantitative composition of gluten proteins in flour, an effect on the amount and on the proportions of single protein types has yet not been determined. Therefore, wholemeal flours of the spring wheat ‘Star’ grown on two different soils and at four different levels of S fertilisation (0, 40, 80, 160 mg S per container) were analysed in detail using an extraction/HPLC procedure. The results demonstrated that the amount of total gluten proteins as well as of the crude protein content of flour was little influenced, whereas amounts and proportions of single protein types were strongly affected by the different S fertilisation. The changes were clearly dependent on the Cys and Met content of each protein type. The amount of S-free ω-gliadins increased drastically, and that of S-poor high-molecular-weight (HMW) glutenin subunits increased moderately in the case of S deficiency. In contrast, the amounts of S-rich γ-gliadins and low-molecular-weight (LMW) glutenin subunits decreased significantly, whereas the amount of α-gliadins was reduced only slightly. S deficiency resulted in a remarkable shift of protein proportions. The gliadin/glutenin ratio increased distinctly; ω-gliadins became major components, and γ-gliadins minor components, whereas the ratio of HMW to LMW glutenin subunits was well-balanced.     

Protein bodies ontogeny and localization of prolamin components in the developing endosperm of wheat caryopses

During caryopsis development, prolamins are initially stored in individual protein bodies, then generate a protein matrix in the ripe caryopsis. The ontogeny of the protein bodies was analyzed by fluorescence and electron microscopy from 7 to 43 days after anthesis (dAA), a period of time from the cellularization of endosperm to its desiccation. A series of antibodies specific to each prolamin type (α/β-, γ-, ω-gliadins, low-molecular weight and high-molecular weight glutenin subunits) made it possible to localize and co-localize the different prolamins in organelles of endosperm cells at different developmental stages. Protein bodies containing prolamins were observed as early as 7 dAA. At the early developmental stages, protein bodies were spherical with diameters around 1–2 μm. Later, around 15 dAA, the PBs enlarged, and aggregation and/or coalescence were prominent at 21 dAA. From 33 dAA, individual PBs were no longer visible, but a protein matrix was confined in the space between starch granules. All prolamins were found in the same protein bodies, without any segregation according to their types. Immunochemical labelling of prolamins failed to reveal in TEM analyses any particular internal organization in protein bodies. Glutenin subunits and gliadins were observed in the Golgi apparatus at the early stages of endosperm development.