Identification and distribution of Puroindoline b-2 variant gene homologs in Hordeum

The barley hordoindoline genes (Hina and Hinb) are homologous to the wheat puroindoline genes (Pina and Pinb). These genes are involved in grain hardness, which is an important quality for barley processing. We identified novel variants of Hina and Hinb in 10 wild Hordeum species (H. bogdanii, H. brachyantherum, H. bulbosum, H. chilense, H. comosum, H. marinum, H. murinum, H. patagonicum, H. pusillum, and H. roshevitzii) covering all Hordeum genomes and preliminarily named them Hinc. These nucleotide sequences were highly similar to those of Puroindoline b-2 variant genes (Pinb-2v) and were located on chromosome 7I in H. chilense. The Hinc genes in H. bogdanii, H. bulbosum, H. patagonicum, and H. roshevitzii were pseudogenes possessing in-frame stop codons. We also found a partial Hinc sequence in H. murinum. This gene was not found in cultivated barley and H. vulgare subsp. spontaneum. The phylogenetic tree of Gsp-1, Hin, and Pin genes demonstrates that Hinc and Pinb-2v genes formed one cluster. Therefore, we considered that Hinc and Pinb-2v genes shared a common ancestral gene and were homologous to each other. We also studied the evolutional process of Gsp-1, Hin, and Pin genes. Our results suggested that Gsp-1 might be the most closely related to a putative ancestral gene on Ha locus.     

Improving the yellow pigment content of bread wheat flour by selecting the three homoeologous copies of Psy1

The yellow pigment content (YPC) of endosperm affects the quality and nutritional value of wheat grain products. Major quantitative trait loci (QTL) for endosperm YPC have been repeatedly mapped on chromosomes 7A and 7B in durum and bread wheats. The genes coding for phytoene synthase (PSY1), which is involved in the biosynthesis of carotenoids, generally co-segregate with these QTL, indicating their role in determining YPC. Here, to study the genetic factors underlying endosperm YPC in bread wheat, the sequence polymorphism of the homoeologous A, B and D copies of genes coding for PSY1, Psy-A1, Psy-B1, and Psy-D1, was studied in a worldwide core collection, which was also phenotyped for flour YPC. Seven novel alleles of Psy-A1 and two novel alleles of Psy-B1 were detected, which confirms the high level of polymorphism of these genes. Two major QTL with respective candidate genes Psy-A1 and Psy-B1 were identified in the distal region of chromosomes 7A and 7B using progeny of a cross between Apache and Ornicar, high and low YPC cultivars, respectively. Association mapping confirms the role of these genes in YPC and shows that the D copy also significantly influences this trait. These results indicate that breeders need to consider all three Psy1 copies when seeking to improve the YPC of wheat endosperm.     

Molecular characterisation of the Wx-B1 allelic variants identified in cultivated emmer wheat and comparison with those of durum wheat

Emmer wheat is a neglected crop that could be used in the breeding of modern durum wheat for quality, one important aspect of which is the starch composition that is related to the waxy proteins. A collection of 87 accessions of Spanish emmer wheat was analysed for waxy protein composition by SDS?CPAGE. No polymorphism was found for the Wx-A1 gene. However, for the Wx-B1 gene, three alleles were detected, two of them new. The whole gene sequence of these alleles was amplified by PCR in three fragments, which were digested with several endonucleases to determine internal differences in the sequence. These variants were also compared with the Wx alleles present in durum wheat. Differences in size and restriction sites were detected. DNA sequence analysis confirmed that the alleles found in emmer wheat are different from those in durum wheat. The first data suggested that these alleles showed a different influence on the amylose content of these lines. The variation found could be used to enlarge the gene pool of durum and emmer wheat, and design new materials with different amylose content.     

Genetic characterization and mapping of the Rht-1 homoeologs and flanking sequences in wheat

The introgression of Reduced height (Rht)-B1b and Rht-D1b into bread wheat (Triticum aestivum) varieties beginning in the 1960s led to improved lodging resistance and yield, providing a major contribution to the ‘green revolution’. Although wheat Rht-1 and surrounding sequence is available, the genetic composition of this region has not been examined in a homoeologous series. To determine this, three Rht-1-containing bacterial artificial chromosome (BAC) sequences derived from the A, B, and D genomes of the bread wheat variety Chinese Spring (CS) were fully assembled and analyzed. This revealed that Rht-1 and two upstream genes were highly conserved among the homoeologs. In contrast, transposable elements (TEs) were not conserved among homoeologs with the exception of intronic miniature inverted-repeat TEs (MITEs). In relation to the Triticum urartu ancestral line, CS-A genic sequences were highly conserved and several colinear TEs were present. Comparative analysis of the CS wheat BAC sequences with assembled Poaceae genomes showed gene synteny and amino acid sequences were well preserved. Further 5′ and 3′ of the wheat BAC sequences, a high degree of gene colinearity is present among the assembled Poaceae genomes. In the 20 kb of sequence flanking Rht-1, five conserved non-coding sequences (CNSs) were present among the CS wheat homoeologs and among all the Poaceae members examined. Rht-A1 was mapped to the long arm of chromosome 4 and three closely flanking genetic markers were identified. The tools developed herein will enable detailed studies of Rht-1 and linked genes that affect abiotic and biotic stress response in wheat.     

Lycopene-ε-cyclase (e-LCY3A) is functionally associated with quantitative trait loci for flour b* colour on chromosome 3A in wheat (Triticum aestivum L.)

Flour b* colour is an important grain quality parameter for specific wheat end-products. The genetic control of b* colour in Australian wheat accessions is controlled by quantitative trait loci (QTL) on chromosomes 3A, 3B, 7A and 7B accumulating lutein, a compound of the carotenoid biosynthetic pathway. The relationship between lutein accumulation and flour b* colour provides an opportunity to identify sequence variants of genes encoding enzymes from the biosynthetic pathway that may control trait variation. This study identified a single nucleotide polymorphism (SNP) in the gene encoding lycopene-ε-cylcase on chromosome 3A (e-LYC3A) between two wheat accessions Ajana and WAWHT2074, identifying two alleles, e-LYC3Aa and e-LYC3Ab, respectively. e-LCY3Ab was present in 62.5 % of the wheat accessions analysed. A highly significant (P < 0.01) association with QTL on chromosome 3A in two mapping populations indicated that e-LYC3A is functionally associated with b* colour variation in some Australian wheat accessions. The SNP induced a serine/glycine substitution at amino acid residue 123 and a subtle change in protein folding at amino acid residue 119. The e-LYC3A SNP may be considered along with other alleles and genes on homoeologous group 3 and 7 chromosomes for selecting desirable flour b* colour variation in marker-assisted breeding.     

Sequence diversity, haplotype analysis, association mapping and functional marker development in the waxy and starch synthase IIa genes for grain-yield-related traits in hexaploid wheat (Triticum aestivum L.)

Development of high-yielding cereal crops could meet increasing global demands for food, feed and bio-fuels. Wheat is one of the world??s most important cereal crops. The biosynthesis of starch is the major determinant of yield in wheat. Two starch biosynthesis genes, the waxy (Wx) genes and the starch synthase IIa (SSIIa) genes, were amplified and sequenced in 92 diverse wheat genotypes using genome-specific primers. Nucleotide diversity, haplotype analysis and association mapping were performed. The first exon (5??-UTR) and the first intron of the three homoeologous Wx genes were isolated using expressed sequence tag sequences. The Wx genes contained 12 exons separated by 11 introns. SNP (single nucleotide polymorphism) frequency ranged from 1 SNP/3,648?bp for Wx-D1 to 1 SNP/135?bp for SSIIa-A1, with an average of 1 SNP/230?bp. The average SNP frequencies in exon and intron regions were 1 SNP/322?bp and 1 SNP/228?bp, respectively. Thirty, 23 and 5 SNPs were identified and formed five, six and five haplotypes for SSIIa-A1, SSIIa-B1 and SSIIa-D1, respectively. However, no association was found between these SNPs and seven yield-related traits. Twenty-two, 15 and 1 SNPs were detected and formed nine, five and two haplotypes for Wx-A1, Wx-B1 and Wx-D1, respectively. Three unique nucleotides C+A+T at SNP5, SNP6 and SNP12 formed Wx-B1-H3, which was significantly associated with increased grain weight, thousand kernel weight, and total starch content in three spring wheat genotypes and five winter wheat genotypes. Cost-effective and co-dominant SNP markers were developed using temperature-switch (TS)-PCR and are being used for marker-assisted selection of doubled haploid lines with enhanced grain yield and starch content in winter wheat breeding programs.     

Identification and development of a functional marker of TaGW2 associated with grain weight in bread wheat (Triticum aestivum L.)

The OsGW2 gene is involved in rice grain development, influencing grain width and weight. Its ortholog in wheat, TaGW2, was considered as a candidate gene related to grain development. We found that TaGW2 is constitutively expressed, with three orthologs expressing simultaneously. The coding sequence (CDS) of TaGW2 is 1,275?bp encoding a protein with 424 amino acids, and has a functional domain shared with OsGW2. No divergence was detected within the CDS sequences in the same locus in ten varieties. Genome-specific primers were designed based on the sequence divergence of the promoter regions in the three orthologous genes, and TaGW2 was located in homologous group 6 chromosomes through CS nulli-tetrasomic (NT). Two SNPs were detected in the promoter region of TaGW2-6A, forming two haplotypes: Hap-6A-A (?593A and ?739G) and Hap-6A-G (?593G and ?769A). A cleaved amplified polymorphic sequence (CAPS) marker was developed based on the ?593 A-G polymorphism to distinguish the two haplotypes in TaGW2-6A. This gene was fine mapped 0.6?cM from marker cfd80.2 near the centromere in a recombinant inbred line (RIL) population. Two hundred sixty-five Chinese wheat varieties were genotyped and association analysis revealed that Hap-6A-A was significantly associated with wider grains and higher one-thousand grain weight (TGW) in two crop seasons. qRT-PCR revealed a negative relationship between TaGW2 expression level and grain width. The Hap-6A-A frequencies in Chinese varieties released at different periods showed that it had been strongly positively selected in breeding. In landraces, Hap-6A-A is mainly distributed in southern Chinese wheat regions. Association analysis also indicated that Hap-6A-A not only increased TGW by more than 3?g, but also had earlier heading and maturity. In contrast to Chinese varieties, Hap-6A-G was the predominant haplotype in European varieties; Hap-6A-A was mainly present in varieties released in the former Yugoslavia, Italy, Bulgaria, Hungary and Portugal.     

Development of a new marker system for identifying the complex members of the low-molecular-weight glutenin subunit gene family in bread wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

Low-molecular-weight glutenin subunits (LMW-GSs) play an important role in determining the bread-making quality of bread wheat. However, LMW-GSs display high polymorphic protein complexes encoded by multiple genes, and elucidating the complex LMW-GS gene family in bread wheat remains challenging. In the present study, using conventional polymerase chain reaction (PCR) with conserved primers and high-resolution capillary electrophoresis, we developed a new molecular marker system for identifying LMW-GS gene family members. Based on sequence alignment of 13 LMW-GS genes previously identified in the Chinese bread wheat variety Xiaoyan 54 and other genes available in GenBank, PCR primers were developed and assigned to conserved sequences spanning the length polymorphism regions of LMW-GS genes. After PCR amplification, 17 DNA fragments in Xiaoyan 54 were detected using capillary electrophoresis. In total, 13 fragments were identical to previously identified LMW-GS genes, and the other 4 were derived from unique LMW-GS genes by sequencing. This marker system was also used to identify LMW-GS genes in Chinese Spring and its group 1 nulli–tetrasomic lines. Among the 17 detected DNA fragments, 4 were located on chromosome 1A, 5 on 1B, and 8 on 1D. The results suggest that this marker system is useful for large-scale identification of LMW-GS genes in bread wheat varieties, and for the selection of desirable LMW-GS genes to improve the bread-making quality in wheat molecular breeding programmes.     

Characterization of HMW-GSs and their gene inaction in tetraploid wheat

In this study, we report the expression of HMW-GSs in 87 accessions of tetraploid wheat, the characterization of three inactive and one active HMW glutenin genes, and the functional verification of HMW-GSs by promoter–GUS expression. SDS-PAGE profiles revealed that tetraploid wheat has many different combinations of HMW-GSs and the number of subunits varies from 1 to 4. HMW glutenin genes at the Glu-A1x, Glu-A1y and Glu-B1y loci exhibited different frequencies of inaction while the Glu-B1x allele was expressed in all 87 accessions. Gene cloning showed that only 1Bx (Tdu-e) could express a full-length protein and its deduced protein sequence has the typical primary structure but with fewer cysteine residues. The expression of the other three HMW glutenin genes has been disrupted by stop codons in their repetitive domains. Besides short indels or mutations of one or more bases, an 85-bp deletion and a 185-bp insertion were found in the promoter regions of 1Ay (Tdu-s) and 1Bx (Tdu-e). The transient expression of promoter–GUS constructs indicated that the 1Ay promoter can drive expression of the GUS gene. We conclude that defects (stop codons or the insertion of large transposon-like elements) in the coding regions may be the most probable cause for the inaction of the HMW glutenin genes.     

Fine mapping and epistatic interactions of the vernalization gene VRN-D4 in hexaploid wheat

Wheat vernalization requirement is mainly controlled by the VRN1, VRN2, VRN3, and VRN4 genes. The first three have been cloned and have homoeologs in all three genomes. VRN4 has been found only in the D genome (VRN-D4) and has not been cloned. We constructed a high-density genetic map of the VRN-D4 region and mapped VRN-D4 within a 0.09 cM interval in the centromeric region of chromosome 5D. Using telocentric 5D chromosomes generated from the VRN-D4 donor Triple Dirk F, we determined that VRN-D4 is located on the short arm. The VRN-D4 candidate region is colinear with a 2.24 Mb region on Brachypodium distachyon chromosome 4, which includes 127 predicted genes. Ten of these genes have predicted roles in development but we detected no functional polymorphisms associated to VRN-D4. Two recombination events separated VRN-D4 from TaVIL-D1, the wheat homolog of Arabidopsis vernalization gene VIL1, confirming that this gene is not a candidate for VRN-D4. We detected significant interactions between VRN-D4 and other four genes controlling vernalization requirement (Vrn-A1, Vrn-B1, Vrn-D1, and Vrn-B3), which confirmed that VRN-D4 is part of the vernalization pathway and that it is either upstream or is part of the regulatory feedback loop involving VRN1, VRN2 and VRN3 genes. The precise mapping of VRN-D4 and the characterization of its interactions with other vernalization genes provide valuable information for the utilization of VRN-D4 in wheat improvement and for our current efforts to clone this vernalization gene.     

Gene polymorphism analysis of Yersinia enterocolitica outer membrane protein A and putative outer membrane protein A family protein

Background

Yersinia enterocolitica outer membrane protein A (OmpA) is one of the major outer membrane proteins with high immunogenicity. We performed the polymorphism analysis for the outer membrane protein A and putative outer membrane protein A (p-ompA) family protein gene of 318 Y. enterocolitica strains.

Results

The data showed all the pathogenic strains and biotype 1A strains harboring ystB gene carried both ompA and p-ompA genes; parts of the biotype 1A strains not harboring ystB gene carried either ompA or p-ompA gene. In non-pathogenic strains (biotype 1A), distribution of the two genes and ystB were highly correlated, showing genetic polymorphism. The pathogenic and non-pathogenic, highly and weakly pathogenic strains were divided into different groups based on sequence analysis of two genes. Although the variations of the sequences, the translated proteins and predicted secondary or tertiary structures of OmpA and P-OmpA were similar.

Conclusions

OmpA and p-ompA gene were highly conserved for pathogenic Y. enterocolitica. The distributions of two genes were correlated with ystB for biotype 1A strains. The polymorphism analysis results of the two genes probably due to different bio-serotypes of the strains, and reflected the dissemination of different bio-serotype clones of Y. enterocolitica.     

Genetic mapping of a putative Thinopyrum intermedium-derived stripe rust resistance gene on wheat chromosome 1B

Key message

Stripe rust resistance transferred from Thinopyrum intermedium into common wheat was controlled by a single dominant gene, which mapped to chromosome 1B near Yr26 and was designated YrL693.

Abstract

Stripe rust caused by Puccinia striiformis f. sp. tritici (Pst) is a highly destructive disease of wheat (Triticum aestivum). Stripe rust resistance was transferred from Thinopyrum intermedium to common wheat, and the resulting introgression line (L693) exhibited all-stage resistance to the widely virulent and predominant Chinese pathotypes CYR32 and CYR33 and to the new virulent pathotype V26. There was no cytological evidence that L693 had alien chromosomal segments from Th. intermedium. Genetic analysis of stripe rust resistance was performed by crossing L693 with the susceptible line L661. F₁, F₂, and F_2:3 populations from reciprocal crosses showed that resistance was controlled by a single dominant gene. A total 479 F_2:3 lines and 781 pairs of genomic simple sequence repeat (SSR) primers were employed to determine the chromosomal location of the resistance gene. The gene was linked to six publicly available and three recently developed wheat genomic SSR markers. The linked markers were localized to wheat chromosome 1B using Chinese Spring nulli-tetrasomic lines, and the resistance gene was localized to chromosome 1B based on SSR and wheat genomic information. A high-density genetic map was also produced. The pedigree, molecular marker data, and resistance response indicated that the stripe rust resistance gene in L693 is a novel gene, which was temporarily designated YrL693. The SSR markers that co-segregate with this gene (Xbarc187-1B, Xbarc187-1B-1, Xgwm18-1B, and Xgwm11-1B) have potential application in marker-assisted breeding of wheat, and YrL693 will be useful for broadening the genetic basis of stripe rust resistance in wheat.     

Development of COS-SNP and HRM markers for high-throughput and reliable haplotype-based detection of Lr14a in durum wheat (Triticum durum Desf.)

Leaf rust (Puccinia triticina Eriks. & Henn.) is a major disease affecting durum wheat production. The Lr14a-resistant gene present in the durum wheat cv. Creso and its derivative cv. Colosseo is one of the best characterized leaf-rust resistance sources deployed in durum wheat breeding. Lr14a has been mapped close to the simple sequence repeat markers gwm146, gwm344 and wmc10 in the distal portion of the chromosome arm 7BL, a gene-dense region. The objectives of this study were: (1) to enrich the Lr14a region with single nucleotide polymorphisms (SNPs) and high-resolution melting (HRM)-based markers developed from conserved ortholog set (COS) genes and from sequenced Diversity Array Technology (DArT^®) markers; (2) to further investigate the gene content and colinearity of this region with the Brachypodium and rice genomes. Ten new COS-SNP and five HRM markers were mapped within an 8.0 cM interval spanning Lr14a. Two HRM markers pinpointed the locus in an interval of <1.0 cM and eight COS-SNPs were mapped 2.1–4.1 cM distal to Lr14a. Each marker was tested for its capacity to predict the state of Lr14a alleles (in particular, Lr14-Creso associated to resistance) in a panel of durum wheat elite germplasm including 164 accessions. Two of the most informative markers were converted into KASPar^® markers. Single assay markers ubw14 and wPt-4038-HRM designed for agarose gel electrophoresis/KASPar^® assays and high-resolution melting analysis, respectively, as well as the double-marker combinations ubw14/ubw18, ubw14/ubw35 and wPt-4038-HRM–ubw35 will be useful for germplasm haplotyping and for molecular-assisted breeding.     

Gas Vesicle Genes Identified in Bacillus megaterium and Functional Expression in Escherichia coli

Gas vesicles are intracellular, protein-coated, and hollow organelles found in cyanobacteria and halophilic archaea. They are permeable to ambient gases by diffusion and provide buoyancy, enabling cells to move upwards in liquid to access oxygen and/or light. In halobacteria, gas vesicle production is encoded in a 9-kb cluster of 14 genes (4 of known function). In cyanobacteria, the number of genes involved has not been determined. We now report the cloning and sequence analysis of an 8,142-bp cluster of 15 putative gas vesicle genes (gvp) from Bacillus megaterium VT1660 and their functional expression in Escherichia coli. Evidence includes homologies by sequence analysis to known gas vesicle genes, the buoyancy phenotype of E. coli strains that carry this gvp gene cluster, the presence of pressure-sensitive, refractile bodies in phase-contrast microscopy, structural details in phase-constrast microscopy, structural details in direct interference-contrast microscopy, and shape and size revealed by transmission electron microscopy. In B. megaterium, the gvp region carries a cluster of 15 putative genes arranged in one orientation; they are open reading frame 1 and gvpA, -P, -Q, -B, -R, -N, -F, -G, -L, -S, -K, -J, -T, and -U, of which the last 11 genes, in a 5.7-kb gene cluster, are the maximum required for gas vesicle synthesis and function in E. coli. To our knowledge, this is the first example of a functional gas vesicle gene cluster in nonaquatic bacteria and the first example of the interspecies transfer of genes resulting in the synthesis of a functional organelle.     

The detection of a de novo allele of the Glu-1Dx gene in wheat–rye hybrid offspring

Key message

This study provides a link between a de novo gene and novel phenotype in wheat–rye hybrids that can be used as a model for induced de novo genetic variation.

Abstract

Wide hybridization can produce de novo DNA variation that may cause novel phenotypes. However, there is still a lack of specific links between changed genes and novel phenotypes in wide hybrids. The well-studied high-molecular-weight glutenin subunit (HMW-GS) genes in tribe Triticeae provide a useful model for addressing this issue. In this study, we investigated the feasibility of a wheat–rye hybridization method for inducing de novo phenotypes using the Glu-1Dx2.2 subunit as an example. We developed three hexaploid wheat lines with normal fertility and a Glu-1Dx2.2 variant, named Glu-1Dx2.2 ^v , derived from three F₁ hybrids. The wild-type Glu-1Dx2.2 has two direct repeats of 295 bp length separated by an intervening 101 bp in its central repetitive region. In the mutant Glu-1Dx2.2 ^v , one copy of the repeats and the intervening sequence were deleted, probably through homology-dependent illegitimate recombination (IR). This study provides a direct link between a de novo allele and novel phenotype. Our results indicate that the wheat–rye method may be a useful tool to induce de novo genetic variations that broaden the genetic diversity for wheat improvement.     

Natural variation of TaGASR7-A1 affects grain length in common wheat under multiple cultivation conditions

GASR7 is a member of Snakin/GASA gene family in higher plants and has been found associated with grain length (GL) in rice and wheat under normal growth conditions. Here, we report the characterization of three distinct TaGASR7 homoeologs (TaGASR7-A1, TaGASR7-B1 and TaGASR7-D1) in common wheat and their deduced proteins and haplotype variation. TaGASR7 homoeologs were located on wheat group 7 chromosomes. Compared with previously characterized Snakin/GASA members, the central region in deduced TaGASR7 proteins and their orthologs was unique in containing a polyglycine tract. Through analyzing longer genomic sequence, more nucleotide differences were found for the two previously reported major haplotypes (H1c and H1g) of TaGASR7-A1. In contrast, no haplotype variation was detected for TaGASR7-B1 and TaGASR7-D1 in the 94 elite common wheat varieties examined. H1c, but not H1g, tended to associate with larger GL values in nine cultivation environments differing in water and nutrient application. However, the positive association between H1c and other grain traits (grain weight and yield) was affected by cultivation environment. Both H1c- and H1g-type alleles were more highly expressed in the unfertilized caryopses and those collected at 5 days after flowering (DAF). Interestingly, at 5 DAF, the expression level of H1c-type alleles was significantly lower than that of H1g-type alleles. By combining our data with those published previously, we suggest that TaGASR7-A1 is mainly a genetic determinant of GL in wheat with pleiotropic effects on grain weight and yield. Potential mechanism underlying TaGASR7-A1 function and its utility in enhancing genetic and breeding studies of wheat grain morphometric and yield traits are discussed.