Exploring mediterranean durum wheat wild relatives and elite diversity panel for future breeding

Durum wheat (Triticum durum) is an important crop that has been used for millennia for human consumption, and modern breeding can take advantage of the wide variability useful for the adaptation to new challenges. Novel beneficial alleles can be found in wild relatives and landraces thus enhancing crop adaptation to many biotic and abiotic stresses. This dissertation considers the source of variability from both before and after wheat domestication, that caused a loss of potentially useful alleles. Chapter 1. is the thesis introduction, which outlines the importance of wheat in the world, providing an historical overview of the domestication, the evolution mechanisms that led to the current forms of durum wheat and the use of wild relatives as a source of germplasm for future breeding programs is crucial. Moreover, the emergence of Z. tritici has been considered as the main pathogen of wheat since it contains extremely high levels of genetic variability and is thus difficult to control. Chapter 2. Considers the contribution of the phenotypic diversity of 242 accessions of Aegilops tauschii from the Open Wild Wheat Consortium, involved in wheat domestication, provided with whole-genome resequencing. The accessions were phenotyped both in the field and in controlled conditions and A k-mer-based GWAS was performed to identify genomic regions involved in useful traits. Chapter 3. Describes the genetic basis of resistance to Z. tritici in a durum wheat elite diversity panel representative of the germplasm bred in Mediterranean. Quantitative trait loci (QTL) analysis results revealed several loci involved in the STB response that were found in several chromosome regions with a high infection rate. The genomic regions associated with STB resistance identified in this study could be of interest for marker assisted selection (MAS) in durum wheat breeding programs.

Molecular strategies for genetic diversity analysis and development of markers linked to resistance traits in apple

The goal of many plant scientists’ research is to explain natural phenotypic variation in term of simple changes in DNA sequence. DNA-based molecular markers are extensively used for the construction of genome-wide molecular maps and to perform genetic analysis for simple and complex traits. The PhD thesis was divided into two main research lines according to the different approaches adopted. The first research line is to analyze the genetic diversity in an Italian apple germplasm collection for the identification of markers tightly linked to targeted genes by an association genetic method. This made it possible to identify synomym and homonym accessions and triploids. The fruit red skin color trait has been used to test the reliability of the genetic approaches in this species. The second line is related to the development of molecular markers closely linked to the Rvi13 and Rvi5 scab resistance genes, previously mapped on apple’s chromosome 10 and 17 respectively by using the traditional linkage mapping method. Both region have been fine-mapped with various type of markers that could be used for marker-assisted selection in future breeding programs and to isolate the two resistance genes.