Abstract
Gliadins are the major components of storage proteins in wheat grains, and they play an essential role in the dough extensibility and nutritional quality of flour. Because of the large number of the gliadin family members, the high level of sequence identity, and the lack of abundant genomic data for Triticum species, identifying the full complement of gliadin family genes in hexaploid wheat remains challenging. Triticum urartu is a wild diploid wheat species and considered the A-genome donor of polyploid wheat species. The accession PI428198 (G1812) was chosen to determine the complete composition of the gliadin gene families in the wheat A-genome using the available draft genome. Using a PCR-based cloning strategy for genomic DNA and mRNA as well as a bioinformatics analysis of genomic sequence data, 28 gliadin genes were characterized. Of these genes, 23 were α-gliadin genes, three were γ-gliadin genes and two were ω-gliadin genes. An RNA sequencing (RNA-Seq) survey of the dynamic expression patterns of gliadin genes revealed that their synthesis in immature grains began prior to 10 days post-anthesis (DPA), peaked at 15 DPA and gradually decreased at 20 DPA. The accumulation of proteins encoded by 16 of the expressed gliadin genes was further verified and quantified using proteomic methods. The phylogenetic analysis demonstrated that the homologs of these α-gliadin genes were present in tetraploid and hexaploid wheat, which was consistent with T. urartu being the A-genome progenitor species. This study presents a systematic investigation of the gliadin gene families in T. urartu that spans the genome, transcriptome and proteome, and it provides new information to better understand the molecular structure, expression profiles and evolution of the gliadin genes in T. urartu and common wheat.
Highlights
Common wheat (Triticum aestivum L.) could be developed into numerous kinds of foods owing to the viscoelastic properties of dough, which makes it one of the “big three” cereal crops in human diets [1, 2]
As for the newly identified gliadins, the LMW-gliadin genes are located on group 4 and 7 chromosomes, and the δ-gliadin genes are found in the Gli-1/Glu-3 region in each of the wheat genomes [6, 7]
Our work offers a systematic investigation of the gliadin gene families in T. urartu at the genomic, transcriptomic and proteomic levels, and it provides new information to further understand the molecular structure, expression profiles and evolution of the gliadin genes in T. urartu and common wheat
Summary
Common wheat (Triticum aestivum L.) could be developed into numerous kinds of foods owing to the viscoelastic properties of dough, which makes it one of the “big three” cereal crops in human diets [1, 2]. As for the newly identified gliadins, the LMW-gliadin genes are located on group 4 and 7 chromosomes, and the δ-gliadin genes are found in the Gli-1/Glu-3 region in each of the wheat genomes [6, 7] Apart from their common signal peptides, each type of gliadin has a unique structure. Ω-gliadins with at least one cysteine were recently characterized and they might form intermolecular disulfide bonds with other components of the gluten matrix [14] Despite their vital roles in determining dough quality, gliadins can cause various diseases, such as celiac disease (CD), wheat-dependent exercise-induced anaphylaxis (WDEIA), and baker’s asthma [15,16,17]. With regards to the γ-gliadins, 11 peptides, DQ2.5-glia-γ1 (PQQSFPQQQ), DQ2.5-glia-γ2 (IQPQQPAQL), DQ2.5-glia-γ3 (QQPQQPYPQ), DQ2.5-glia-γ4a (SQPQQQFPQ), DQ2.5-glia-γ4b (PQPQQQFPQ), DQ2.5-glia-γ4c (QQPQQPFPQ), DQ2.5-gliaγ4d (PQPQQPFCQ), DQ2.5-glia-γ5 (QQPFPQQPQ), DQ8-glia-γ1a
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