The present work aimed to provide detailed genotyping and phenotyping data on the complete landrace collection encompassing 200 wheat landraces in parallel to 70 modern wheat cultivars. Genotyping was carried out using a high-density 20K Illumina SNP genotyping array with 17.905 gene-based single-nucleotide polymorphism (SNP) probes. We analysed the geographic distribution of the genetic variability and chromosome distribution of polymorphic markers. Our results showed that landrace accessions had a greater percentage of polymorphic markers on the homoeologous group 2 and 7 chromosomes. The group 2 and 7 chromosomes contain several genes of great agronomic importance including the photoperiod response genes, semi-dwarfing genes, fungal disease resistance genes and the thousand grain weight gene. Structure and principal component analysis showed considerable differences among landraces and modern wheat cultivars, thus breeders can select genetically distant parents for crossing in breeding.
We characterised the ecological adaptation of landraces and wheat cultivars through measuring phenological and morphological traits under field conditions. Determination of the high temperature and the drought tolerance of the landrace collection was carried out in a controlled chamber test and rain-out shelter, respectively. On the whole set of genotypes evaluation of disease resistance was tested for three pathogens ( leaf rust, stem rust and fusarium head blight) under field conditions in artificially inoculated nurseries. In the case of fusarium head blight, the type II resistance (spreading of the disease in the spike) was also evaluated in green-house tests. The physical properties and the bread-making quality parameters were measured on the whole set of genotypes. Comparisons to modern bread wheat cultivars were presented and Genome-Wide Association Study (GWAS) was performed with a focus on associations between SNPs and agronomically important traits. Our analysis identified several marker-trait associations for further exploration and validation for marker-assisted breeding.
In the frame of our project, we actively disseminated the results for the scientific and wider community. We have published the results in peer-reviewed open access scientific journals and made poster- and oral presentations in scientific and educational conferences. The wider audience has been informed about the project through the project home page. Other dissemination was Marie Curie Ambassador activates by popularizing Marie Skłodowska-Curie actions among students and PostDoc researchers in my institute (Centre for Agricultural Research, Hungary) and high school.