Two loci on wheat chromosome 5A regulate the differential cold-dependent expression of the cor14b gene in frost-tolerant and frost-sensitive genotypes

Although cold acclimation in cereals involves the expression of many cold-regulated genes, genetic studies have shown that only very few chromosomal regions carry loci that play an important role in frost tolerance. To investigate the genetic relationship between frost tolerance and the expression of cold-regulated genes, the expression and regulation of the wheat homolog of the barley cold-regulated gene cor14b was studied at various temperatures in frost-sensitive and frost-tolerant wheat genotypes. At 18/15 °C (day/night temperatures) frost-tolerant plants accumulated cor14b mRNAs and expressed COR14b proteins, whereas the sensitive plants did not. This result indicates that the threshold temperature for induction of the wheat cor14b homolog is higher in frost-resistant plants, and allowed us to use this polymorphism in a mapping approach. Studies made with chromosome substitution lines showed that the polymorphism for the threshold induction temperature of the wheat cor14b homolog is controlled by a locus(i) located on chromosome 5A of wheat, while the cor14b gene was mapped in Triticum monococcum on the long arm of chromosome 2A^m. The analysis of single chromosome recombinant lines derived from a cross between Chinese Spring/Triticum spelta 5A and Chinese Spring/Cheyenne 5A identified two loci with additive effects that are involved in the genetic control of cor14b mRNA accumulation. The first locus was tightly linked to the marker psr911, while the second one was located between the marker Xpsr2021 and Frost resistance 1 (Fr1). Received: 20 July 1999 / Accepted: 15 November 1999     

First survey of the wheat chromosome 5A composition through a next generation sequencing approach

Wheat is one of the world's most important crops and is characterized by a large polyploid genome. One way to reduce genome complexity is to isolate single chromosomes using flow cytometry. Low coverage DNA sequencing can provide a snapshot of individual chromosomes, allowing a fast characterization of their main features and comparison with other genomes. We used massively parallel 454 pyrosequencing to obtain a 2x coverage of wheat chromosome 5A. The resulting sequence assembly was used to identify TEs, genes and miRNAs, as well as to infer a virtual gene order based on the synteny with other grass genomes. Repetitive elements account for more than 75% of the genome. Gene content was estimated considering non-redundant reads showing at least one match to ESTs or proteins. The results indicate that the coding fraction represents 1.08% and 1.3% of the short and long arm respectively, projecting the number of genes of the whole chromosome to approximately 5,000. 195 candidate miRNA precursors belonging to 16 miRNA families were identified. The 5A genes were used to search for syntenic relationships between grass genomes. The short arm is closely related to Brachypodium chromosome 4, sorghum chromosome 8 and rice chromosome 12; the long arm to regions of Brachypodium chromosomes 4 and 1, sorghum chromosomes 1 and 2 and rice chromosomes 9 and 3. From these similarities it was possible to infer the virtual gene order of 392 (5AS) and 1,480 (5AL) genes of chromosome 5A, which was compared to, and found to be largely congruent with the available physical map of this chromosome.     

Genetic Characterization of a Fusarium Head Blight Resistance QTL from Triticum turgidum ssp. dicoccoides

Plant Molecular Biology Reporter - Qfhs.ndsu-3AS in wild emmer wheat (Triticum turgidum L. ssp. dicoccoides) is a major quantitative trait locus associated with type II resistance to Fusarium head...     

Cold-induced mRNAs accumulate with different kinetics in barley coleoptiles

The effect of cold treatment on gene expression in two different barley (Hordeum vulgare L.) cultivars has been studied. Cold stress induced a set of new mRNAs as determined by in-vitro translation of coleoptile RNA obtained from control and stressed seedlings. These mRNAs accumulated with different kinetics, and the cold-induced proteins could be grouped into five categories. The first category (a) is represented by a single protein with M_r of 75 kDa that reaches its highest level of expression after 6 h at 5°C. This polypeptide readily accumulates in the plant tissues and it can be detected when proteins separated by two-dimensional electrophoresis are stained with silver nitrate. The other polypeptides appear later during the 1- to 4-d stress period (protein groups b and c), increase (group d), or decrease during the period of treatment (group e). Only minor differences between the two cultivars with different cold-resistance capacities were found when the in-vitro translation products were compared. The results obtained demonstrate that several mRNAs are specifically expressed as a response to cold treatment in barley coleoptiles.Abbreviations 2-D two-dimensional - IEF isoelectrofocusing - M_r relative molecular weight - poly(A) polyadenylated - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Identification and mapping of a new leaf stripe resistance gene in barley (Hordeum vulgare L.)

Pyrenophora graminea is the seed-borne pathogen causal agent of barley leaf stripe disease. Near-isogenic lines (NILs) carrying resistance of the cv ”Thibaut” against the highly virulent isolate Dg2 were obtained by introgressing the resistance into the genetic background of the susceptible cv ”Mirco”. The segregation of the resistance gene was followed in a F₂ population of 128 plants as well as on the F₃ lines derived from the F₂ plants; the segregation fitted the 1:2:1 ratio for a single gene. By using NILs, a RAPD marker associated with the resistance gene was identified; sequence-specific (STS) primers were designed on the basis of the amplicon sequence and a RILs mapping population with an AFLP-based map were used to position this molecular marker to barley chromosome 1 S (7HS). STS and CAPS markers were developed from RFLPs mapped to the telomeric region of barley chromosome 7HS and three polymorphic PCR-based markers were developed. The segregation of these markers was followed in the F₂ population and their map position with respect to the resistance gene was determined. Our results indicate that the Thibaut resistance gene, which we designated as Rdg2a, maps to the telomeric region of barley chromosome 7HS and is flanked by the markers OPQ-9₇₀₀ and MWG 2018 at distances of 3.1 and 2.5 cM respectively. The suitability of the PCR-based marker MWG2018 in selection- assisted barley breeding programs is discussed. Received: 22 June 2000 / Accepted: 16 October 2000     

Cloning and characterization of barley long chain acyl-CoA oxidase and its possible regulation by glucose

A barley ( Hordeum vulgare L.) full-length clone coding for long chain acyl-CoA oxidase (ACX), key enzyme of β -oxidation, was isolated by cDNA library screening and 5'-rapid amplification of cDNA ends. The cDNA encodes for a polypeptide of 667 amino acids, with a molecular mass of 74.5 kDa. The amino acid sequence, beside an extensive similarity with other plant and mammalian ACXs, showed a PTS1 peroxisomal targeting signal at the C terminus and a conserved FAD-binding domain. The gene was over-expressed in E. coli and the fusion protein was shown to possess long chain acyl-CoA oxidase activity. Polyclonal antibodies were raised against a large fragment of the protein encoded by the barley putative ACX gene. Northern and Western analysis demonstrated that a basal level of long chain ACX is always present along the barley life cycle, while a higher level of expression is typical of actively growing tissues such as germinating embryos, ovary before anthesis, developing embryos, shoots and roots apexes. In vitro germination experiments with glucose and glucose analogues provided evidence about the involvement of a glucose-deriving signal in the positive modulation of ACX expression. This result highlights the role of ACX, not only during oil reserve mobilization, but also in plant growth and metabolism.