Plant Genomics and Breeding

DU1 K06-48-A' - 'Plant genetics and genomics'
Genome architecture. Different components of the eukaryotic genome: single DNA sequences, single genes and gene families, repetitive DNA sequences, tandem and intersperse repeats. Genetic maps: visible phenotypic markers, DNA molecular markers and linkage analysis. Transposable elements (TE): class I and II elements, molecular and functional features; main TE families in maize, from their discovery to the study of their role in genome and gene evolution. Comparative analysis of plant genome structure and size, colinearity of genomes in cereal species. Orthologous and paralogous genes, evolution of gene families.
Gene expression. Different levels of regulation of gene expression. Regulation of transcription: cis-regulatory sequences and transcription factors; epigenetic changes, DNA methylation and histone modifications. Role of environmental (light, temperature) and internal (developmental stage, hormones) signals on gene expression. Variants of transcription factors and their role in the
The course will offer the students the main knowledge of genome structure, organization and evolution in model systems and in crops. The course will also provide a detailed description of the main mechanisms of regulation of gene expression and analyze principles and methodologies for forward and reverse genetic analysis. Furthermore the course will offer to the students the Essential of genetics improvement in plant breeding.
domestication process, examples in rice, maize and tomato. Regulation of gene expression and plant development: seed origin and domain differentiation.
Functional genomics. Forward genetics: mutagenesis, detection and characterization of knockout mutants. Genetic dissection of biosynthetic pathways and developmental processes. TE mutagenesis: co-segregation analysis and gene sequence isolation. Reverse genetics: organization of mutant collections, survey for single mutant detection, insertion libraries assembly. Single gene variants in crop improvement: genes of the green revolution.
UD2. 'K06-48-B' - 'Advanced plant breeding'
Genome architecture. Different components of the eukaryotic genome: single DNA sequences, single genes and gene families, repetitive DNA sequences, tandem and intersperse repeats. Genetic maps: visible phenotypic markers, DNA molecular markers and linkage analysis. Transposable elements (TE): class I and II elements, molecular and functional features; main TE families in maize, from their discovery to the study of their role in genome and gene evolution. Comparative analysis of plant genome structure and size, colinearity of genomes in cereal species. Orthologous and paralogous genes, evolution of gene families.
Gene expression. Different levels of regulation of gene expression. Regulation of transcription: cis-regulatory sequences and transcription factors; epigenetic changes, DNA methylation and histone modifications. Role of environmental (light, temperature) and internal (developmental stage, hormones) signals on gene expression. Variants of transcription factors and their role in the domestication process, examples in rice, maize and tomato. Regulation of gene expression and plant development: seed origin and domain differentiation.
Functional genomics. Forward genetics: mutagenesis, detection and characterization of knockout mutants. Genetic dissection of biosynthetic pathways and developmental processes. TE mutagenesis: co-segregation analysis and gene sequence isolation. Reverse genetics: organization of mutant collections, survey for single mutant detection, insertion libraries assembly. Single gene variants in crop improvement: genes of the green revolution.