Andrew Jamnik
University of Toronto, Canada
Title: The adaptation of the bacterial plant pathogen Pseudomonas syringae onto a novel host through experimental evolution
Biography
Biography: Andrew Jamnik
Abstract
The bacterial plant pathogen Pseudomonas syringae is a highly diverse species complex, with the ability to cause disease on a wide range of hosts, including many economically important crops. Although P. syringae as a species has a very large host range, individual strains are highly host specific. The inability of a strain to infect plant species outside of its host range is generally due to its inability to suppress and evade the host’s innate immunity. Few studies to date have tested how plant pathogens evolve to overcome novel host immunity, and a further understanding of this could help in uncovering how newly emerging diseases arise. In this study, we are currently experimentally evolving P. syringae pv. phaseolicola (Pph) 1448A, a strain which causes disease on many cultivars of the common bean (Phaseolus vulagris), on the non-host Arabidopsis thaliana (Arabidopsis) through in planta experimental evolution. Although Pph 1448A is unable to cause disease on Arabidopsis, its ability to grow and persist on Arabidopsis has given this strain the potential to adapt within this novel environment. We have constructed 12 uniquely barcoded hyper mutating lineages of Pph 1448A for this experiment, to increase the evolvability of the lineages and to allow us to study mutations associated with adaptation towards Arabidopsis. By using highly sensitive in planta competition assays on Arabidopsis, we’ve shown that after 80 days of in planta growth on Arabidopsis, two lineages have shown significant gains in fitness on the novel host. Additionally, one of these lineages has shown a gradual increase in fitness throughout the experimental evolution. Population sequencing of these adapted lineages will give us the ability to identify candidate mutations responsible for this novel host adaptation. Overall, this work will provide a further understanding of the early adaptive processes underlying the spread of existing pathogens to new hosts.