A. M. Stanca

Uptake and agronomic efficiency of nitrogen in winter barley and winter wheat

Abstract Nitrogen (N) uptake and utilization efficiency ( N UtE ) of the high-yielding cultivars `Gemini of wheat and `Jaidor of barley were tested with N rates of 0, 140 and 210xa0kgxa0ha −1 and 0, 80 and 140xa0kgxa0ha −1 , respectively. The different grain yield response was linked to their difference in nitrogen uptake and utilization efficiency. The highest yield in barley was recorded with 80xa0kgxa0Nxa0ha −1 and in wheat with 210xa0kgxa0Nxa0ha −1 . Nitrogen application affected the accumulation of biomass up to heading in wheat and barley. While N uptake during grain filling did not show any correlation to N applied in barley, it was markedly correlated in wheat. At N 0 and N 140 N applied, barley exhibited a 32 and 8% higher N UtE than wheat. N agronomic efficiency, a parameter representing the ability of the plant to increase yield in response to N applied, was similar in barley and wheat (8.7 and 9.2xa0kgxa0kg −1 of N applied, respectively), suggesting that both species respond equally to nitrogen fertilization. Nevertheless, due to its lower N UtE , wheat requires high N fertilization to optimize yields; by contrast, in barley the lower N rate needed to achieve highest yields enables this crop to perform better in low-input conditions. As a results, the reduced N requirements for barley highest yield associated with a better R F value (apparent N fertilizer recovery of 63% in barley and 49% in wheat at N 140 ) makes barley crop a better choice to reduce ground-water pollution due to nitrate leaching in winter and early spring.

Two loci on chromosome 5H determine low-temperature tolerance in a ‘Nure’ (winter) × ‘Tremois’ (spring) barley map

Barley (Hordeum vulgare subsp. vulgare) is an economically important diploid model for the Triticeae; and a better understanding of low-temperature tolerance mechanisms could significantly improve the yield of fall-sown cereals. We developed a new resource for genetic analysis of winter hardiness-related traits, the ‘Nure’ × ‘Tremois’ linkage map, based on a doubled-haploid population that is segregating for low-temperature tolerance and vernalization requirement. Three measures of low-temperature tolerance and one measure of vernalization requirement were used and, for all traits, QTLs were mapped on chromosome 5H. The vernalization response QTL coincides with previous reports at the Vrn-1/Fr1 region of the Triticeae. We also found coincident QTLs at this position for all measures of low-temperature tolerance. Using Composite Interval Mapping, a second proximal set, of coincident QTLs for low-temperature tolerance, and the accumulation of two different COR proteins (COR14b and TMC-Ap3) was identified. The HvCBF4 locus, or another member of the CBF loci clustered in this region, is the candidate gene underlying this QTL. There is a CRT/DRE recognition site in the promoter of cor14b with which a CBF protein could interact. These results support the hypothesis that highly conserved regulatory factors, such as members of the CBF gene family, may regulate the stress responses of a wide range of plant species.

Fine mapping of a HvCBF gene cluster at the frost resistance locus Fr-H2 in barley

Barley is an economically important model for the Triticeae tribe. We recently developed a new resource: the ‘Nure’xa0×xa0‘Tremois’ mapping population. Two low temperature QTLs were found to segregate on the long arm of chromosome 5H (Fr-H1, distal; Fr-H2, proximal). With the final aim of positional cloning of the genetic determinants of Fr-H1 and Fr-H2, a large segregating population of 1,849 F2 plants between parents ‘Nure’ and ‘Tremois’ was prepared. These two QT loci were first validated by using a set of F3 families, marker-selected to harbor pairs of reciprocal haplotypes, with one QTL fixed at homozygosity and the alternate one in heterozygous phase. The study was then focused towards the isolation of the determinant of Fr-H2. Subsequent recombinant screens and phenotypic evaluation of F4 segregants allowed us to estimate (Pxa0≤xa00.01) a refined genomic interval of Fr-H2 (4.6xa0cM). Several barley genes with the CBF transcription factor signature had been already roughly mapped in cluster at Fr-H2, and they represent likely candidate genes underlying this QTL. Using the large segregating population (3,698 gametes) a high-resolution genetic map of the HvCBF gene cluster was then constructed, and after fine mapping, six recombinations between the HvCBFs were observed. It was therefore possible to genetically divide seven HvCBF subclusters in barley, in a region spanning 0.81xa0cM, with distances among them varying from 0.03 to 0.32xa0cM. The few recombinants between the different HvCBF subclusters are being marker-selected and taken to homozygosity, to phenotypically separate the effects of the single HvCBF genes.

Patterns of genetic diversity and linkage disequilibrium in a highly structured Hordeum vulgare association-mapping population for the Mediterranean basin

Population structure and genome-wide linkage disequilibrium (LD) were investigated in 192 Hordeum vulgare accessions providing a comprehensive coverage of past and present barley breeding in the Mediterranean basin, using 50 nuclear microsatellite and 1,130 DArT® markers. Both clustering and principal coordinate analyses clearly sub-divided the sample into five distinct groups centred on key ancestors and regions of origin of the germplasm. For given genetic distances, large variation in LD values was observed, ranging from closely linked markers completely at equilibrium to marker pairs at 50xa0cM separation still showing significant LD. Mean LD values across the whole population sample decayed below r2 of 0.15 after 3.2xa0cM. By assaying 1,130 genome-wide DArT® markers, we demonstrated that, after accounting for population substructure, current genome coverage of 1 marker per 1.5xa0cM except for chromosome 4H with 1 marker per 3.62xa0cM is sufficient for whole genome association scans. We show, by identifying associations with powdery mildew that map in genomic regions known to have resistance loci, that associations can be detected in strongly stratified samples provided population structure is effectively controlled in the analysis. The population we describe is, therefore, shown to be a valuable resource, which can be used in basic and applied research in barley.

Mixed model association scans of multi-environmental trial data reveal major loci controlling yield and yield related traits in Hordeum vulgare in Mediterranean environments

An association panel consisting of 185 accessions representative of the barley germplasm cultivated in the Mediterranean basin was used to localise quantitative trait loci (QTL) controlling grain yield and yield related traits. The germplasm set was genotyped with 1,536 SNP markers and tested for associations with phenotypic data gathered over 2xa0years for a total of 24xa0yearxa0×xa0location combinations under a broad range of environmental conditions. Analysis of multi-environmental trial (MET) data by fitting a mixed model with kinship estimates detected from two to seven QTL for the major components of yield including 1000 kernel weight, grains per spike and spikes per m2, as well as heading date, harvest index and plant height. Several of the associations involved SNPs tightly linked to known major genes determining spike morphology in barley (vrs1 and int-c). Similarly, the largest QTL for heading date co-locates with SNPs linked with eam6, a major locus for heading date in barley for autumn sown conditions. Co-localization of several QTL related to yield components traits suggest that major developmental loci may be linked to most of the associations. This study highlights the potential of association genetics to identify genetic variants controlling complex traits.

Mapping adaptation of barley to droughted environments

Identifying barley genomic regions influencing the response of yield and its components to water deficits will aid in our understanding of the genetics of drought tolerance and the development of more drought tolerant cultivars. We assembled a population of 192 genotypes that represented landraces, old, and contemporary cultivars sampling key regions around the Mediterranean basin and the rest of Europe. The population was genotyped with a stratified set of 50 genomic and EST derived molecular markers, 49 of which were Simple Sequence Repeats (SSRs), which revealed an underlying population sub-structure that corresponded closely to the geographic regions in which the genotypes were grown. A more dense whole genome scan was generated by using Diversity Array Technology (DArT®) to generate 1130 biallelic markers for the population. The population was grown at two contrasting sites in each of seven Mediterranean countries for harvest 2004 and 2005 and grain yield data collected. Mean yield levels ranged from 0.3 to 6.2xa0t/ha, with highly significant genetic variation in low-yielding environments. Associations of yield with barley genomic regions were then detected by combining the DArT marker data with the yield data in mixed model analyses for the individual trials, followed by multiple regression of yield on markers to identify a multi-locus subset of significant markers/QTLs. QTLs exhibiting a pre-defined consistency across environments were detected in bins 4, 6, 6 and 7 on barley chromosomes 3H, 4H, 5H and 7H respectively.

Genetic analysis of the accumulation of COR14 proteins in wild (Hordeum spontaneum) and cultivated (Hordeum vulgare) barley

The cold-regulated (COR14) protein of 14 kDa is a polypeptide accumulated under low-temperature conditions in the chloroplasts of barley leaves. In H. vulgare the COR14 antibody cross-reacts with two proteins, with a slightly different relative molecular weight around the marker of 14.4 kDa, referred to as COR14a and COR14b (high and low relative molecular weight, respectively). In a collection of H. spontaneum genotypes a clear polymorphism was found for the corresponding COR proteins. While some accessions showed the same COR pattern as cultivated barley, in 38 out of 61 accessions examined the COR14 antibody cross-reacted with an additional coldregulated protein with a relative molecular weight of about 24 kDa (COR24). The accumulation of COR24 was often associated with the absence of COR14b; the relationship between the COR14b/COR24 polymorphism and the adaptation of H. spontaneum to different environments is discussed. By studying COR14 accumulation in cultivated barley we have found that the threshold induction-temperature of COR14a is associated with the loci controlling winter hardiness. This association was demonstrated by using either a set of 30 cultivars of different origin, or two sets of frost-tolerant and frost-sensitive F1 doubled-haploid lines derived from the cross Dicktoo (winter type) x Morex (spring type). These results suggest that the threshold induction-temperature of COR14a can be a potential biochemical marker for the identification of superior frostresistant barley genotypes.

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

Abstractu2002Pyrenophora 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.

Development of PCR-based markers on chromosome 5H for assisted selection of frost-tolerant genotypes in barley

Frost tolerance is an important trait for barley breeding. Field selection for this trait is not always efficient since, especially in Southern Europe, severe winter frost occurs erratically. Recent advances of cloned genes and molecular markers in barley provide molecular breeders with the means to develop new, simple PCR-based molecular markers, which can be used to select frost-tolerant genotypes quickly without stress simulation. This paper reports the development of two STS markers derived from the RFLP probes WG644 and PSR637, chosen as they are located on the long arm of homoeologous group 5 chromosomes of Triticeae, known to harbour the most important loci for frost tolerance. The two STS markers were validated together with one selected RAPD marker, OPA17, by separating two sets of winter and spring barley genotypes with different levels of frost tolerance. The ability of the developed markers to select segregant frost-tolerant and frost-susceptible genotypes was then investigated in a population of doubled haploid lines derived from a cross between a highly tolerant (Nure) and a susceptible (Tremois) genotype. In this population only two markers, OPA17 and Psr637 demonstrated their efficiency in dividing the phenotypes according to the parental alleles. These two markers mapped on the long arm of chromosome 5H, tightly linked to two frost tolerance QTLs. Two polymorphic bands of the WG644 STS were mapped: the former on the long arm of chromosome 5H (Wg644c) and the latter (Wg644b) on the long arm of chromosome 2H.

RFLP analysis of highly polymorphic loci in barley

SummaryBarley middle-repeat sequences were screened for their ability to discriminate 51 barley commercial varieties. Two hordein clones, a clone encoding a leaf-specific thionin, a desiccation induced cDNA clone, a clone coding for 5S-rRNA and one corresponding to ubiquitin genes were tested. A very sensitive RFLP technique including four cutter restriction enzymes and denaturing 4% polyacrylamide gels were used to evidence the highest level of polymorphism.The RFLP data were analyzed by computer. Some probe/enzyme combinations were able to differentiate a large number of the cultivars tested, whereas three probe/enzyme combinations succeeded in identifying all the varieties. The use of this RFLP method can thus be suggested for cultivar identification in barley.