Chromosomal location of structural genes controlling isozymes in Hordeum chilense

Summary Polyacrylamide and starch gel electrophoresis of esterase (EST), glutamate oxaloacetate transaminase (GOT) and phosphoglucomutase (PGM) isozymes in Hordeum chilense, Triticum turgidum conv. durum, the amphiploid H. chilense X T. turgidum (Tritordeum), and the durum wheat/H. chilense monosomic addition lines revealed the chromosomal location of one EST locus, two GOT loci and one PGM locus. Loci Est-H ^ch1 and Got-H ^ch2 were found on chromosome 6H^ch,Got-H ^ch3 on chromosome 3H^ch, and Pgm-H ^ch1 on chromosome 4H^ch. These results lend evidence for the assumed homoeology relationships between chromosomes of Triticeae species.     

Chromosome engineering in wheat to restore male fertility in the msH1 CMS system

Pollen fertility restoration of the CMS phenotype caused by H. chilense cytoplasm in wheat was associated with the addition of chromosome 6H^chS from H. chilense accession H1. In order to develop an euploid restored line, different genomic combinations substituting the 6H^chS arm for another homoeologous chromosome in wheat were evaluated, with the conclusion that the optimal combination was the translocation T6H^chS·6DL. The double translocation T6H^chS·6DL in H. chilense cytoplasm was obtained. This line is fertile and stable under different environmental conditions. However, a single dose of the T6H^chS·6DL translocation is insufficient for fertility restoration when chromosome 6D is also present. Restoration in the msH1 system is promoted by interaction between two or more genes, and in addition to the restorer of fertility (Rf) located on chromosome 6H^chS, one or more inhibitor of fertility (Fi) genes may be present in chromosome 6DL.     

Molecular and cytological characterization of an extra acrocentric chromosome that restores male fertility of wheat in the msH1 CMS system

A new CMS system designated as ‘msH1’ has been reported in bread wheat using the cytoplasm of H. chilense. While testing this system in different wheat backgrounds, a highly fertile line with chromosome number 42 plus an extra acrocentric chromosome was obtained. The extra chromosome did not pair with any wheat chromosome at meiosis, and progeny from this line which lack the acrocentric chromosome showed pollen abortion and male sterility. In order to establish the origin of this chromosome, FISH using H. chilense genomic DNA as probe was used and showed that it had originated from H. chilense chromosome(s). The novel chromosome did not possess sequences similar to wheat rDNA; however, the probe pSc119.2 from S. cereale containing the 120 bp family was found to occur at the end of its long arm. Data obtained from FISH and EST molecular markers confirm that the long arm of the acrocentric chromosome is indeed, the short arm of chromosome 1H^ch from H. chilense. We suggest that the novel chromosome originated from a deletion of the distal part of the long arm of chromosome 1H^ch. Neither the 1H^chS short arm, nor the whole chromosome 1H^ch restores pollen fertility of the alloplasmic wheat. Therefore, the restorer gene on the acrocentric chromosome must be located on the retained segment from the hypothetical 1H^chL, while some pollen fertility inhibitor could be present on the deleted 1H^chL distal segment. Disomic addition of the acrocentric chromosome was obtained and this line resulted fully stable and fertile.     

Chromosomal location of genes coding for endosperm proteins of Hordeum chilense,determined by two-dimensional electrophoresis of wheat-H. chilense chromosome addition lines

The proteins of Hordeum chilense grain were resolved into 25 major components by two-dimensional electrophoresis. Their solubilities in aqueous alcohol solutions were determined to distinguish prolamin storage proteins from metabolic and structural proteins. The prolamins were divided into two groups, based on the presence or absence of intermolecular disulfide bonds determined by gel-filtration chromatography. Using an incomplete set of Chinese Spring wheat-H. chilense disomic addition lines, the structural genes of 21 of the 26 most dominant seed proteins were assigned to chromosomes. The great majority of the prolamin genes, including those coding for a high molecular weight (HMW) prolamin subunit, was present on chromosome 1H^ch. However, a small number of prolamin genes also occurred on chromosomes 5H^ch and 7H^ch. A minor protein, probably belonging to the nonstorage group of proteins, is coded by genes on 5H^ch. Various ditelosomic addition lines and ditelosomic and disomic substitution lines for chromosome 7H^ch were also analyzed by electrophoresis. This technique revealed that the genes for three major prolamins occur on the arm of chromosome 7H^ch and that a gene for a minor protein, also thought to be a prolamin, occurs on the arm. These results are discussed in relation to the evolution of prolamin genes in the Triticeae.     

Meiotic pairing of the amphiploid Hordeum chilense X Triticum turgidum conv. durum studied by means of Giemsa C-banding technique

Summary The meiotic behaviour of the amphiploid Hordeum chilense X Triticum turgidum conv. durum using a C-banding staining method is studied. Nine pairs of chromosomes at metaphase-1 (4A, 7A and the seven of the B genome) were identified and the remaining wheat chromosomes (1A, 2A, 3A, 5A and 6A) and seven of the chilense (1 to 7 H ^ch chromosomes) were assigned to its particular genome. A similar mean number of univalents from parental genomes (wheat and wild barley) were found. No meiotic pairing between chilense and turgidum chromosomes was detected. Differences in the meiotic behaviour per chromosome and amongst genomes are explained on the basis of cytomorphological and heterochromatin characteristics.     

The genetic control of grain esterases in hexaploid wheat

Summary A comparison of EST-5 grain esterase phenotypes from wheat-alien amphiploid, addition and substitution genotypes, resolved by flat-bed isoelectric focusing identified homoeologous Est-5 loci on chromosome 3H of Hordeum vulgare, 3H^ch of H. chilense, 3S^b of Aegilops bicornis, 3S¹ of Ae. sharonensis and Ae. longissima and 6R of Secale cereale and 6R^m of S. montanum. The Est-5 genes in alien species provide evidence for chromosome homoeology with wheat.     

Novel Bread Wheat Lines Enriched in Carotenoids Carrying Hordeum chilense Chromosome Arms in the ph1b Background

The use of crop wild relative species to improve major crops performance is well established. Hordeum chilense has a high potential as a genetic donor to increase the carotenoid content of wheat. Crosses between the 7H^ch H. chilense substitution lines in wheat and the wheat pairing homoeologous1b (ph1b) mutant allowed the development of wheat-H. chilense translocation lines for both 7H^chα and 7H^chβ chromosome arms in the wheat background. These translocation lines were characterized by in situ hybridization and using molecular markers. In addition, reverse phase chromatography (HPLC) analysis was carried out to evaluate the carotenoid content and both 7H^chα∙7AL and 7AS∙7H^chβ disomic translocation lines. The carotenoid content in 7H^chα∙7AL and 7AS∙7H^chβ disomic translocation lines was higher than the wheat-7H^ch addition line and double amount of carotenoids than the wheat itself. A proteomic analysis confirmed that the presence of chromosome 7H^ch introgressions in wheat scarcely altered the proteomic profile of the wheat flour. The Psy1 (Phytoene Synthase1) gene, which is the first committed step in the carotenoid biosynthetic pathway, was also cytogenetically mapped on the 7H^chα chromosome arm. These new wheat-H. chilense translocation lines can be used as a powerful tool in wheat breeding programs to enrich the diet in bioactive compounds.     

A cytoplasmic male sterility (CMS) system in durum wheat

Cytoplasmic male sterility (CMS) systems are based in the incompatible interaction between nucleus and cytoplasm and are commonly used for hybrid seed production in many crop species. The msH1 CMS system in common wheat results from the incompatibility between the nuclear genome of wheat and the cytoplasm of Hordeum chilense. Fertility restoration of the CMS phenotype is associated with the addition of the short arm of chromosome 6H^ch from H. chilense. In this work, we attempt to transfer the msH1 system to durum wheat and to evaluate its potential as a new source of CMS for the production of hybrid durum wheat. For that purpose, an alloplasmic durum wheat line was developed by substituting wheat cytoplasm by that from H. chilense. This line was completely male sterile. Also, the double translocation T6H^chS·6DL was transferred from common wheat into durum wheat, to test its potential as a restorer line. Finally, the system was tested by using the double T6H^chS·6DL translocation in durum wheat as pollen donor for the alloplasmic male sterile line, which confirmed the fertility restoration ability of 6H^chS in durum wheat.     

OPTIMAS-DW: A comprehensive transcriptomics,metabolomics, ionomics,proteomics and phenomics data resource for maize

Background

The wild barley Hordeum chilense fulfills some requirements for being a useful tool to investigate the endosperm yellow pigment content (YPC) in the Triticeae including its diploid constitution, the availability of genetic resources (addition and deletion stocks and a high density genetic map) and, especially, its high seed YPC not silenced in tritordeums (amphiploids derived from H. chilense and wheat). Thus, the aim of this work was to test the utility of the H. chilense genome for investigating the YPC in the Triticeae.

Results

Twelve genes related to endosperm carotenoid content and/or YPC in grasses (Dxr, Hdr [synonym ispH], Ggpps1, Psy2, Psy3, Pds, Zds, e-Lcy, b-Lcy, Hyd3, Ccd1 and Ppo1) were identified, and mapped in H. chilense using rice genes to identify orthologs from barley, wheat, sorghum and maize. Macrocolinearity studies revealed that gene positions were in agreement in H. vulgare and H. chilense. Additionally, three main regions associated with YPC were identified in chromosomes 2H^ch, 3H^ch and 7H^ch in H. chilense, the former being the most significant one.

Conclusions

The results obtained are consistent with previous findings in wheat and suggest that Ggpps1, Zds and Hyd3 on chromosome 2H^ch may be considered candidate genes in wheat for further studies in YPC improvement. Considering the syntenic location of carotenoid genes in H. chilense, we have concluded that the H^ch genome may constitute a valuable tool for YPC studies in the Triticeae.

     

Selection and molecular characterization of imidazolinone resistant mutation-derived lines of Tritordeum HT621

Imidazolinone herbicides resistant varieties, induced by mutations at the AHAS gene (acetohydroxyacid synthase), have been developed in many crops. Hexaploid tritordeum (Tritordeum Asch. & Graebn.) is the amphiploid derived from the cross between Hordeum chilense (H^chH^ch) and durum wheat Triticum turgidum L. (Thell) (AABB). Tritordeums have the potential to become a new crop with high added-value for food or feed. Mutagenesis with EMS was conducted to obtain imidazolinone resistant lines derived of the tritordeum HT621. Eleven M₃ plants were selected after imidazolinone treatment and five descendants of two of these lines (HT621-M3R1-3 and HT621-M3R10-1) were analyzed at the molecular level. Partial sequences of the three homologous AHAS loci in genomes A, B, and H^ch were obtained as well as those of HT621. A partial sequence of the AHAS gene in Hordeum chilense is first described in this work, and the designation ahasL-H ^ch 1 is proposed. A single Ser-Asn₆₂₇ substitution at the AHAS locus in the B genome is responsible of resistance in both lines. We propose the name AhasL-B2 for this resistance allele. This is the first report of the selection of imidazolinone resistant lines of tritordeum and the molecular characterization of the mutation conferring this resistance.     

Linkage relationships between prolamin genes located on chromosome 1H<Superscript>ch</Superscript> in<Emphasis Type="Italic"> Hordeum chilense</Emphasis>

The endosperm storage proteins of Hordeum chilense Roem. et Schult., a species used in the synthesis of the amphiploid tritordeum (×Tritordeum Ascherson et Graebner), have a great effect on the gluten strength of this amphiploid. We have analysed electrophoretically the heredity of these proteins, which are synthesised by genes located on chromosome 1H^ch, and detected up to five loci in a cross between two lines of H. chilense. These loci present a certain homology with loci synthesising the same proteins in wheat. The genetic distances between these loci were calculated.Communicated by H.F. Linskens     

Subunits of tetrameric α-amylase inhibitors of Hordeum chilense are encoded by genes located in chromosomes 4Hch and 7Hch

Summary Three proteins (components 1, 2, and 4) of the non-prolamin, 70% ethanol soluble fraction from the endosperm of Hordeum chilense have been identified as putative subunits of the tetrameric inhibitors active against insect -amylases. In experiments carried out with the synthetic alloploid Tritordeum (H. chilense x Triticum turgidum conv. durum), previously described proteins from T. turgidum, designated CM2, CM3 and CM 16, have been also identified as subunits of -amylase inhibitors. Genes for components 1 and 4 of H. chilense have been located in chromosomes 4H^ch and 7H^ch, based on the analysis of H. chilense-T.turgidum addition lines. Subunits of the inhibitors from wheat and from cultivated barley had been previously assigned to chromosomes of the same homoeology groups.     

Allelic variation of the D-prolamin subunits encoded at the Hch genome in a collection of primary hexaploid tritordeums

 Hexaploid tritordeum is the amphiploid derived from the cross between Hordeum chilense and durum wheat. The storage proteins synthesised by the H^ch genome have an influence on the gluten strength of this amphiploid. The D-prolamins of H. chilense are glutenin-like proteins. The variability has been analysed electrophoretically and up to 20 different patterns have been detected in a world collection of this species. This genetic variability of H. chilense could be a source of additional variation in tritordeum and in breeding wheat for quality. Received: 29 November 1998 / Accepted: 19 December 1998     

IRAP,REMAP and ISSR Fingerprinting in Newly Formed Hexaploid Tritordeum (X Tritordeum Ascherson et Graebner) and Respective Parental Species

Retrotransposon (RTN)-based markers, such as the inter-retrotransposon amplified polymorphism (IRAP) and the retrotransposon-microsatellite amplified polymorphism (REMAP), are highly informative, multilocus, and reveal insertion polymorphisms among individuals. These markers have been used for evolutionary studies, genetic diversity assessment, DNA fingerprinting, and detection of genetic rearrangements induced by allopolyploidization. The hexaploid tritordeum (H^chH^chAABB; 2n?=?6x?=?42) is an allopolyploid produced from crosses between wild barley (Hordeum chilense Roem. et Schultz.) (H^chH^ch; 2n?=?2x?=?14) and durum wheat (Triticum turgidum L. conv. durum) (AABB; 2n?=?4x?=?28). With this study, we carried out the DNA fingerprinting of two newly formed hexaploid tritordeum lines (HT22 and HT27) and their respective parents, line H1 of H. chilense and line T81 of durum wheat, based on IRAPs, REMAPs and inter-simple sequence repeats (ISSRs), in order to detect potential rearrangements in tritordeum derived from polyploidization. The amphiploid nature of the HT22 and HT27 individuals was successfully confirmed after fluorescence in situ hybridization (FISH), which was performed on their mitotic chromosome spreads with genomic DNA from H. chilense and 45S ribosomal DNA (rDNA), simultaneously, as probes. Six combinations of LTR (long terminal repeat) primers and seven combinations of one LTR and one SSR (simple sequence repeat) primers successfully produced IRAPs and REMAPs, respectively, in both tritordeum lines, and their respective parents. ISSRs were produced with three SSR primers (8081, 8082, and 8564). The analysis of the presence/absence of bands among the tritordeum lines and the respective parents allowed the detection of polymorphic bands: (1) shared by tritordeum and one of the parents; (2) exclusively amplified in tritordeum; and (3) exclusively present in one of the parents. Once no polymorphism was detected among the individuals of each parental species, the polymorphic bands that fit into the second and third cases probably constituted rearrangements in the newly formed tritordeums that arose in response to allopolyploidization, which resulted from the loss of parental bands or, conversely, from the appearance of novel bands not seen in the parental species. Most of the polymorphic IRAPs in tritordeum were shared with the female parent (H. chilense), while most of the polymorphic REMAPs and ISSRs were common to the male parent (durum wheat), but globally, most of the bands inherited by tritordeum had a wheat origin. In conclusion, these dominant markers were successful for DNA fingerprinting and detection of rearrangements in newly formed tritordeum derived from responses to allopolyploidization.     

Characteristics of alpha-amylase isozymes in cytologenetically different wheat cultivars

The isoenzyme composition of alpha-amylase is studied by polyacrylamide gel electrophoresis in Tris-glycine (pH 8.3) system in wheat cultivars with different genome composition. We show that durum wheat (Triticum durum, 2n = 4x = 28, BBAA) lacks the isoenzymes encoded by 6D and 7D chromosomes that are present in common wheat zymograms (Triticum aestivum, 2n = 6x = 42, BBAADD). A similar pattern is observed in a synthetic allohexaploid carrying the BBAA genomes of wheat and the H ^ch H ^ch genome of barley (Hordeum chilense). Our method of electrophoresis fails to reveal additional variants of alpha-amylase encoded by the barley genome, although C-banding analysis confirms the genomic structure BBAAH ^ch H ^ch of this allopolyploid. The electrophoretic spectrum of the spring common wheat cultivar Dobrynya with the wheat-Agropyron translocation 7DL-7AiL contains all of the alpha-amylase isoenzymes typical for common wheat (2n = 6x = 42, BBAADD) except for the zymotype encoded by the long arm of chromosome 7D. This observation confirms the results of cytogenetic analysis that identified a 7DL-7AiL translocation in this cultivar. No additional alpha-amylase isoenzymes encoded by Agropyron chromosome have been observed. Our data indicate that analysis of wheat-alien hybrids or introgressive forms should be carried out using a complex of different methods.     

Unlinked structural genes for the developmentally regulated isozymes of sn-glycerol-3-phosphate dehydrogenase in mice

Genetic variants that affect the heat stability and ionic charge of the adult isozyme of glycerol-3-phosphate dehydrogenase (EC 1.1.1.8) map to a gene, Gdc-1, located on chromosome 15. A second isozyme of glycerol-3-phosphate dehydrogenase, structurally homologous to the product of the Gdc-1 locus and expressed predominantly in undifferentiated tissues, has previously been identified. We have now discovered an electrophoretic variant of this embryonic isozyme. This expression is determined by a codominant allele of the gene, Gdc-2, that maps to the distal end of chromosome 9 as inferred from the observed gene order Mpi-1–d-Mod-1–Gdc-2.     

Potential of Start Codon Targeted (SCoT) markers for DNA fingerprinting of newly synthesized tritordeums and their respective parents

Hexaploid tritordeum (H^chH^chAABB; 2n?=?42) results from the cross between Hordeum chilense (H^chH^ch; 2n?=?14) and cultivated durum wheat (Triticum turgidum ssp. durum (AABB; 2n?=?28). Morphologically, tritordeum resembles the wheat parent, showing promise for agriculture and wheat breeding. Start Codon Targeted (SCoT) polymorphism is a recently developed technique that generates gene-targeted markers. Thus, we considered it interesting to evaluate its potential for the DNA fingerprinting of newly synthesized hexaploid tritordeums and their respective parents. In this study, 60 SCoT primers were tested, and 18 and 19 of them revealed SCoT polymorphisms in the newly synthesized tritordeum lines HT27 and HT22, respectively, and their parents. An analysis of the presence/absence of bands among tritordeums and their parents revealed three types of polymorphic markers: (i) shared by tritordeums and one of their parents, (ii) exclusively amplified in tritordeums, and (iii) exclusively amplified in the parents. No polymorphism was detected among individuals of each parental species. Three SCoT markers were exclusively amplified in tritordeums of lines HT22 and HT27, being considered as polyploidization-induced rearrangements. About 70 % of the SCoT markers of H. chilense origin were not transmitted to the allopolyploids of both lines, and most of the SCoTs scored in the newly synthesized allopolyploids originated from wheat, reinforcing the potential use of tritordeum as an alternative crop.     

New isozyme systems for maize (Zea mays L.): Aconitate hydratase,adenylate kinase,NADH dehydrogenase,and shikimate dehydrogenase

Electrophoretic variation and inheritance of four novel enzyme systems were studied in maize (Zea mays L.). A minimum of 10 genetic loci collectively encodes isozymes of aconitate hydratase (ACO; EC 4.2.1.3.), adenylate kinase (ADK; EC 2.7.4.3), NADH dehydrogenase (DIA; EC 1.6.99.—), and shikimate dehydrogenase (SAD; EC 1.1.1.25). At least four loci are responsible for the genetic control of ACO. Genetic data for two of the encoding loci,Aco1 andAco4, demonstrated that at least two maize ACOs are active as monomers. Analysis of organellar preparations suggests that ACO1 and ACO4 are localized in the cytosolic and mitochondrial subcellular fractions, respectively. Maize ADK is encoded by a single nuclear locus,Adk1, governing monomeric enzymes that are located in the chloroplasts. Two cytosolic and two mitochondrial forms of DIA were electrophoretically resolved. Segregation analyses demonstrated that the two cytosolic isozymes are controlled by separate loci,Dia1 andDia2, coding for products that are functional as monomers (DIA1) and dimers (DIA2). The major isozyme of SAD is apparently cytosolic, although an additional faintly staining plastid form may be present. Alleles atSad1 are each associated with two bands that cosegregate in controlled crosses. Linkage analyses and crosses with B-A translocation stocks were effective in determining the map locations of six loci, including the previously described but unmapped locusAcp4. Several of these loci were localized to sparsely mapped regions of the genome.Dia2 andAcp4 were placed on the distal portion of the long arm of chromosome 1, 12.6 map units apart.Dia1 was localized to chromosome 2, 22.2 centimorgans (cM) fromB1. Aco1 was mapped to chromosome 4, 6.2 cM fromsu1. Adk1 was placed on the poorly marked short arm of chromosome 6, 8.1 map units fromrgd1. Less than 1% recombination was observed betweenGlu1 (on chromosome 10) andSad1. In contrast to many other maize isozyme systems, there was little evidence of gene duplication or of parallel linkage relationships for these allozyme loci. This work was supported by grants from Pioneer Hi-Bred International, Inc., of Johnston, Iowa, the National Institute of Health (Research Grant GM11546), and the United States Department of Agriculture (Competitive Research Grant 83-CRCR-1-1273). This is Paper No. 11372 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh.     

Milling energy requirement of the aneuploid stocks of common wheat,including alien addition lines

Summary Aneuploid stocks, which included Triticum aestivum/alien, disomic, chromosome addition lines, wheat/alien, ditelosomic, chromosome addition lines, and the available aneuploids of Chinese Spring wheat, were used to locate genes that influence milling energy requirement (ME). Genes that affected ME were found on all seven homoeologous chromosome groups. The addition of complete wheat chromosomes 1B, 1D, 2A, 2D, 5B, 6B, 7B and 7D increased ME. Positive effects were also found in specific chromosome arms: 1BS, 2DS, 5AS, 5BS and 6BL. Wheat chromosome 3B conditioned low ME and the gene(s) responsible was located on the short arm. Other negative effects were attributed to wheat chromosome arms 4BL, 4DL, 5DS and 6DS. Alien chromosome additions that conferred high ME included 2H, 5H, 6H and 7H of barley, Hordeum vulgare and 2R, 2R, 4R, 4RL, 6R, 6RL and 7RL of rye, Secale cereale. Those that conferred a low ME included 1H ^ch of H. chilense, and 6u and 7u of Aegilops umbellulata, 5R and 5RS of S. cereale and 5R ^m and 5R ^mS of S. montanum. Although the control of ME is polygenic, there is a major effect of genes located on the short arms of homoeologous group 5 chromosomes.     

Localization of the enzymes involved in H2 and formate metabolism inSyntrophospora bryantii

Cell-free extracts of crotonate-grown cells of the syntrophic butyrate-oxidizing bacteriumSyntrophospora bryantii contained high hydrogenase activities (8.5–75.8 µmol · min^–1 mg^–1 protein) and relatively low formate dehydrogenase activities (0.04–0.07 µmol · min^–1 mg^–1 protein). The K _M value and threshold value of the hydrogenase for H₂ were 0.21 mM and 18 µM, respectively, whereas the K _M value and threshold value of the formate dehydrogenase for formate were 0.22 mM and 10 µM, respectively. Hydrogenase, butyryl-CoA dehydrogenase and 3-OH-butyryl-CoA dehydrogenase were detected in the cytoplasmic fraction. Formate dehydrogenase and CO₂ reductase were membrane-bound, likely located at the outer aspect of the cytoplasmic membrane. Results suggest that during syntrophic butyrate oxidation H₂ is formed intracellularly while formate is formed at the outside of the cell.