A. R. Barr

A consensus map of barley integrating SSR, RFLP, and AFLP markers

A consensus map of barley combining simple sequence repeat (SSR), restriction fragment length polymorphism (RFLP), and amplified fragment length polymorphism (AFLP) markers has been developed by combining 5 Australian barley linkage maps, Galleon × Haruna Nijo, Chebec × Harrington, Clipper × Sahara, Alexis × Sloop, and Amaji Nijo × WI2585, using the software package JOINMAP 2.0. The new consensus map consists of 700 markers, with 136 being SSRs, and has a total genetic distance of 933 cM. The consensus map order appears to be in good agreement with the Australian barley linkage maps, with the exception of a small inversion located close to the centromere of chromosome 5H. Similarly, the SSR map orders are in good agreement with SSR markers integrated into the doubled haploid linkage map of Lina × Hordeum spontaneum, Canada Park. The new consensus map provides a framework to cross examine and align partial and complete barley linkage maps using markers common to many barley maps. This map will allow researchers to rapidly and accurately select SSR markers for chromosome regions of interest for barley genetic and plant breeding studies.

QTL mapping of chromosomal regions conferring reproductive frost tolerance in barley (Hordeum vulgare L.)

Spring radiation frost is a major abiotic stress in southern Australia, reducing yield potential and grain quality of barley by damaging sensitive reproductive organs in the latter stages of development. Field-based screening methods were developed, and genetic variation for reproductive frost tolerance was identified. Mapping populations that were segregating for reproductive frost tolerance were screened and significant QTL identified. QTL on chromosome 2HL were identified for frost-induced floret sterility in two different populations at the same genomic location. This QTL was not associated with previously reported developmental or stress-response loci. QTL on chromosome 5HL were identified for frost-induced floret sterility and frost-induced grain damage in all three of the populations studied. The locations of QTL were coincident with previously reported vegetative frost tolerance loci close to the vrn-H1 locus. This locus on chromosome 5HL has now been associated with response to cold stress at both vegetative and reproductive developmental stages in barley. This study will allow reproductive frost tolerance to be seriously pursued as a breeding objective by facilitating a change from difficult phenotypic selection to high-throughput genotypic selection.

QTL analysis of malting quality traits in two barley populations

Selection for malting quality traits is a major breeding objective for barley breeding programs. With molecular markers linked to loci affecting these traits, this selection can be undertaken at an earlier stage of the breeding program than is possible using conventional tests. Quantitative trait loci (QTLs) associated with malting quality traits were mapped in 2 populations derived from parents with elite malting quality. Progeny from an Arapiles/Franklin population grown in 4 environments and an Alexis/Sloop population grown in 5 environments were tested for grain protein percentage, α-amylase activity, diastatic power, hot water extract, wort viscosity, wort β-glucan, β-glucanase, and free α-amino acids. QTL analysis was performed using a one-stage approach, which allowed for modelling of spatial variation in the field, and in each phase of the malting quality analysis in the laboratory. QTLs for malting quality traits were detected on all chromosomes and for both populations. Few of these QTLs were significant in all of the environments, indicating that QTL × environment interactions were important. There were many coincident QTLs for traits that are expected to be related such as diastatic power and α-amylase activity, wort β-glucan and wort viscosity and for some traits that are not expected to be related such as hot water extract and malt viscosity.

Mapping and QTL analysis of the barley population Clipper × Sahara

A genetic linkage map consisting of 211 molecular markers has been generated using a doubled-haploid population derived from a cross between the Australian barley variety Clipper and the Algerian landrace Sahara 3771. The map was used in subsequent trait mapping studies to locate the genes conferring boron tolerance and cereal cyst nematode resistance from Sahara 3371 and to map several plant type and developmental genes. Closely linked markers to the trait loci have been identified and are now being widely implemented in Australian breeding programs.

Mapping of genomic regions associated with net form of netblotch resistance in barley

Quantitative trait loci (QTLs) associated with resistance to net blotch and their chromosomal locations were determined from analyses of doubled haploid progeny of Alexis/Sloop, Arapiles/Franklin, Sloop/Halcyon, and recombinant inbred lines of Sloop-sib/Alexis. Five QTLs on chromosomes 2H, 3H, and 4H were found to be associated with seedling resistance to the net form of net blotch. In Arapiles/Franklin and Alexis/Sloop populations, 4 significant QTLs explaining 9–17% of the variation in net blotch resistance were detected on 2H and 3H. A major locus, QRpts4L accounting for 64% of the variation in infection type, was detected on 4H in the Sloop/Halcyon population. In Sloop/Halcyon, 2 microsatellite markers, EBmac0906 and GMS089, and AFLP marker P13/M50-108, co-segregated and detected maximum variability for net blotch resistance as revealed by bootstrap analysis. EBmac0906 and Bmac0181 were validated in F2 progeny of an Ant29/Halcyon population and reliably predicted phenotypes of 93% of lines resistant and susceptible to net blotch. These markers may be used within breeding programs to select alleles favourable for net blotch resistance derived from Halcyon.

The determinants and genome locations influencing grain weight and size in barley (Hordeum vulgare L.)

Grain weight and size are traits important to malting and feed barley. Understanding the determinants of grain weight and size, especially under stressful growing environments, will aid breeding efforts to improve these traits. The determinants of grain weight and size are discussed in relation to the pre- and post-anthesis periods of barley development. Genetic mapping of the loci influencing grain weight and size has provided a fundamental understanding of these traits, and a summary of mapped quantitative trait loci (QTLs) from Australian and international mapping populations is presented. The influence of developmental loci on grain weight and size QTLs, approaches to discovering non-developmentally related loci, and prospects for a marker assisted selection approach to improving grain weight and size are discussed.

Mapping and QTL analysis of the barley population Chebec × Harrington

A doubled haploid population of 120 individuals was produced from the parents Chebec, an Australian 2-row barley of feed quality with resistance to the cereal cyst nematode, and Harrington, a 2-rowed, Canadian variety of premium malting quality. This paper describes 18 field and laboratory experiments conducted with the population and summarises the traits mapped and analysed. The genomic location of 25 traits and genes is described and marker–trait associations for 5 traits (malt extract, diastatic power, resistance to cereal cyst nematode, early flowering, resistance to pre-harvest sprouting) important to Australian efforts to improve malting barley varieties have been used in practical breeding programs. Detailed maps for these populations are shown in this paper, while a consensus map incorporating these maps and further experiments on the populations are described elsewhere in this issue.

Mapping and QTL analysis of the barley population Mundah × Keel

The barley mapping population Mundah × Keel was devised to characterise and map chromosome regions associated with improved growth and grain yield on sandy soils of low fertility. A low level of polymorphism between the parents proved problematic for the construction of a detailed linkage map of this population. Despite this, significant quantitative trait loci (QTLs) for specific traits were detected, providing an insight into the probable chromosome regions associated with sand adaptation. In addition, this population is being employed to identify loci associated with the expression of traits for moisture stress and frost tolerance, and resistance to spot form of net blotch and leaf scald.

Mapping and QTL analysis of the barley population Galleon × Haruna Nijo

A genetic linkage map consisting of 435 molecular markers has been constructed using a doubled-haploid mapping population derived from a cross between the Australian barley feed variety Galleon and Haruna Nijo, a Japanese barley cultivar of high malting quality. This map was used to locate the genes conferring CCN and SFNB resistance from Galleon and to locate malting and brewing quality genes from Haruna Nijo. Closely linked markers to the trait loci have been identified and are now being widely implemented in Australian breeding programs.

Mapping and QTL analysis of the barley population Alexis × Sloop

Two populations between the German malting variety Alexis and the Australian malting variety Sloop were constructed, mapped, phenotyped, and subjected to quantitative trait loci analysis. One population consisted of 153 F4-derived recombinant inbred lines and the other of 111 doubled haploid lines. This paper describes 18 field and laboratory experiments conducted with the populations and summarises the traits mapped and analysed. The genetic basis of 5 traits (malt extract, resistance to leaf rust, resistance to powdery mildew, early flowering, plant stature) important to Australian efforts to improve malting barley varieties was elucidated. Detailed maps for these populations are shown in this paper, while a consensus map incorporating these maps and further experiments on the populations are described elsewhere in this issue.