Genomics of temperature response in plants. Climate change is predicted to have negative impacts on Australian agriculture. This project will use genomic tools to uncover biological mechanisms for plant response to temperature that will help design crop varieties that are more tolerant to higher temperatures.
Genome dynamics following plastid endosymbiosis. Plastid endosymbiosis events (enslavement of an algal cell inside of a host cell to form a plastid) are difficult to pinpoint because the genomic data required for a broad array of species are rarely available. Furthermore, the classical method used to infer endosymbiotic gene transfers is being criticised. This project will elucidate the origin of chlorarachniophyte and dinoflagellate plastids and characterise the genome dynamics following endosy ....Genome dynamics following plastid endosymbiosis. Plastid endosymbiosis events (enslavement of an algal cell inside of a host cell to form a plastid) are difficult to pinpoint because the genomic data required for a broad array of species are rarely available. Furthermore, the classical method used to infer endosymbiotic gene transfers is being criticised. This project will elucidate the origin of chlorarachniophyte and dinoflagellate plastids and characterise the genome dynamics following endosymbiosis. It uses densely sampled genome data obtained with high-throughput sequencing technologies. Simulation studies will be used to evaluate methods for inferring endosymbiotic gene transfer and alignment-free methods will be used to improve phylogenomic pipelines.Read moreRead less