Project description:The high molecular weight (HMW) subunits of wheat glutenin are synthesised only in the starchy endosperm tissue of the developing wheat grain. The transcriptomes of the lines L88-18 and L88-31 (Lawrence, G.J., Macritchie, F. & Wrigley, C.W. Dough and baking quality of wheat lines in glutenin subunits controlled by Glu-A1, Glu-B1 and Glu-D1 loci. J. Cereal. Sci. 7,109-112 (1988)) coming from the same cross were compared. Transcriptomes analysis was performed in endosperm tissue (14 and 28 days post anthesis-dpa) and in leaf tissue (8 days post germination –dpg). Each of the transcriptome comparisons was performed using three biological replicates (i.e. per line/tissue /developmental stage selected). Hybridisations were performed in reverse dye labelling.

Project description:The high molecular weight (HMW) subunits of wheat glutenin are synthesised only in the starchy endosperm tissue of the developing wheat grain. To place the differences observed between the endosperms of the transgenic and non-transgenic lines in a wider developmental context, the transcriptomes of endosperm at 14 dpa and leaf at 8 dpg of the transgenic line B102,1-1 were also compared.The experiment was performed with three biological replicates and hybridisations were performed in reverse dye labelling.

Project description:The high molecular weight (HMW) subunits of wheat glutenin are synthesised only in the starchy endosperm tissue of the developing wheat grain. We studied the effect of introducing transgenes on the global gene expression profiles of selected transgenic wheat lines, particularly during wheat seed development. For these particular set of experiments a direct comparison between the hexaploid bread transgenic line B102,1-1 (Rooke, L., Steele, S.H., Barcelo, P.,Shewry, P.R. & Lazzeri,P. Transgene inheritance, segregation and expression in bread wheat. Euphytica 129, 301-309 (2003)) and it background, non transformed L88-31 wheat line (Lawrence,G.J., Macritchie, F. & Wrigley, C.W. Dough and baking quality of wheat lines in glutenin subunits controlled by Glu-A1, Glu-B1 and Glu-D1 loci. J. Cereal. Sci. 7,109-112 (1988)) was performed. Transcriptome comparison analysis was performed in endosperm tissue (14 and 28 days post anthesis-dpa) and in leaf tissue (8 days post germination ?dpg). The transcriptome comparisons analysis was performed using three biological replicates (i.e. per line/tissue /developmental stage selected). Hybridisations were performed in reverse dye labelling.

Project description:The high molecular weight (HMW) subunits of wheat glutenin are synthesised only in the starchy endosperm tissue of the developing wheat grain. We compared the expressed genomes of the transgenic wheat line B102,1-1 (Rooke et al. Transgene inheritance, segregation and expression in bread wheat. Euphytica 129, 301-309 (2003)). Both lines were shown to express the HMW-GS Ax1 gene (Halford, N.G. et al. Analysis of HMW glutenin subunits encoded bychromosome 1A of bread wheat (Triticum aestivum L.) indicates quantitative effects on grain quality. Theor Appl Genet 83, 373-378 (1992).) to the expressed genome of conventionally bred wheat line L88-18 (Lawrence et al. Dough and baking quality of wheat lines in glutenin subunits controlled by Glu-A1, Glu-B1 and Glu-D1 loci. J. Cereal. Sci. 7,109-112 (1988)) which results in the same effects on traits. Transcriptomes comparison analysis was performed in endosperm tissue (14 and 28 days post anthesis-dpa) and in leaf tissue (8 days post germination –dpg), respectively. Each of the transcriptome comparisons was performed using three biological replicates (i.e. per line/tissue /developmental stage selected). Hybridisations were performed in reverse dye labelling.Exceptionally, biological replica 2 was only performed for B102,1-1 (green)/L88-18 (red) labelling and not swap

Project description:LC-MS/MS(Lipid metabolomics)

Project description:Proteomics LC-MS MS dataset

Project description:Here is reported the first study of transcriptome analyses using the Illumina HiSeq 4000 platform for three kinds of wheat (G represents Strong gluten wheat, Z represents middle gluten wheat,R represents weak gluten wheat). The variation of wheat varieties with different gluten content is mainly shown in the content of gluten, flour is divided into high gluten powder ( > 30%), medium gluten powder (26%-30%) and low gluten powder ( < 20%), according to the wet gluten content. In total, over 102.6 Gb clean reads were produced and 114, 621 unigenes were assembled; more than 59,085 unigenes had at least one significant match to an existing gene model. Differentially expressed gene analysis identified 2339 and 2600 unigenes which were expressed higher or lower among strong gluten, middle gluten and weak gluten wheat. After functional annotation and classification, three dominant pathways including protein isomerase, antioxidase activity and energy metabolism, and 410 unigenes related to gluten strength polymerization of wheat were discovered. In strong-gluten wheat, low molecular weight subunit content is higher than weak-gluten wheat, and the activity of cysteine synthase and isomerase is increased, which may promote the cross-linking of low molecular weight protein to high molecular weight protein. Meanwhile, POD enzyme strengthens gluten network and CAT enzyme affects gluten polymerization, along with higher ATPase activity, which will provides energy for protein polymerization reaction in comparison of strong-gluten wheat and weak-gluten wheat. The accuracy of these RNA-seq data was validated by qRT-PCR analysis. These data will extend our knowledge of quality characteristics of wheat and provide a theoretical foundation for molecular mechanism research of wheat.

Project description:Metabolomics LC-MS dataset

Project description:Wheat gluten proteins are key determinants of baking quality. While untargeted proteomics enable relative quantification, absolute quantities of specific gluten protein groups are not available so far. We developed a targeted liquid chromatography with tandem mass spectrometry (LC-MS/MS) stable isotope dilution assay (SIDA) to quantify eleven individual gluten protein groups based on isotope-labeled internal standards corresponding to the selected marker peptides. The comparison of targeted and untargeted measurements revealed differences in protein composition, likely arising from different MS/MS acquisition strategies and protein assignment. We correlated the absolute protein content with baking quality traits in the Bavarian multiple advanced generation intercross wheat population. None of the individual groups correlated strongly with any baking quality trait. Six groups (α-gliadin 2, γ-gliadin 1, low-molecular-weight glutenin subunit (LMW-GS) 3, and high-molecular-weight glutenin subunits (HMW-GS) 1–4) showed weak to moderate associations (r = 0.32–0.64), mainly with grain protein content, sedimentation value, and wet gluten content. LMW-GS 3 represents the rare i-type containing eight cysteine residues. Loaf volume was only weakly to moderately correlated, primarily with HMW-GS 1 (r = 0.41) and HMW-GS 3 (r = 0.40), supporting the superior effect of Dy10. By contrast, HMW-GS 5 (Dx2, Dx5) showed little effect, consistent with a stronger influence of y-type glutenin subunits. Summing up the protein content across groups increased correlation strengths, yet baking quality remains a complex trait shaped by multiple proteins and non-protein factors.

Project description:High-molecular-weight glutenin subunits (HMW-GS) play an important role for the baking quality of wheat. The ancient wheats emmer and spelt differ in their HMW-GS pattern compared to modern common wheat and this might be one reason for their comparatively poor baking quality. The aim of this study was to elucidate similarities and differences in the amino acid sequences of two 1Bx HMW-GS of common wheat, spelt and emmer. First, the sodium dodecyl polyacrylamide gel electrophoresis (SDS-PAGE) system was optimized to separate common wheat, spelt and emmer Bx6 and Bx7 from other HMW-GS (e.g., 1Ax and 1By) in high concentrations. The in-gel digests of the Bx6 and Bx7 bands were analyzed by untargeted LC-MS/MS experiments revealing different UniProtKB accessions in spelt and emmer compared to common wheat. The HMW-GS Bx6 and Bx7, respectively, of emmer and spelt showed differences in the amino acid sequences compared to those of common wheat. The identities of the peptide variations were confirmed by targeted LC-MS/MS. These peptides can be used to differentiate between Bx6 and Bx7 of spelt and emmer and Bx6 and Bx7 of common wheat. The findings should help to increase the reliability and curation status of wheat protein databases and to understand the effects of protein structure on the functional properties.