The study will utilise quantitative gene expression data from well-defined populations of segregating Brassica napus genotypes, and integrate the segregating transcriptome data with quantitative metabolite and phenotype data using a systems-genetics approach that combines an analysis of gene co-expression networks with expression QTL approaches. Furthermore, a public B. napus SNP array will be developed and used for association analyses in a large genotype diversity set of B. napus accessions. The expression of genes (i) for which eQTL hotspots are observed in the linkage mapping populations, and (ii) which are identified as candidates by systems genetics approaches based on global gene expression and hormone profiles, will be examined in the genotype diversity set by quantitative real-time PCR. This data will then be used for associative expression mapping.The work will initially focus on seedling development traits and their relationship to heterosis as a case study for a highly complex interactive system that is genetically very poorly understood, but is agronomically extremely important. The network analysis tools will also be applied for a systems analysis of important seed quality characters to identify key regulatory factors involved in biosynthesis of oil, protein and fibre components. The project will incorporate the most recent technological developments in the field of next-generation sequencing for ultra-deep transcription profiling, and will integrate gene coexpression network analysis, classical QTL analysis, genetical genomics and association genetics concepts in a manner that to date has not been used for functional genomics of complex traits in a crop plant.

DFG Programme Research Grants

International Connection Canada, United Kingdom

Participating Persons Dr. Sue Abrams; Professor Dr. Ian Bancroft; Dr. Pierre R. Fobert; Dr. Isobel Parkin; Dr. Andrew G. Sharpe