The relationship between pathogen life-history traits and metapopulation dynamics

Plant pathogen traits, such as transmission mode and overwintering strategy, may have important effects on dispersal and persistence, and drive disease dynamics. Still, we lack insights into how life-history traits influence spatiotemporal disease dynamics. We adopted a multifaceted approach, combining experimental assays, theory and field surveys, to investigate whether information about two pathogen life-history traits - infectivity and overwintering strategy - can predict pathogen metapopulation dynamics in natural systems. For this, we focused on four fungal pathogens (two rust fungi, one chytrid fungus and one smut fungus) on the forest herb Anemone nemorosa. Pathogens infecting new plants mostly via spores (the chytrid and smut fungi) had higher patch occupancies and colonization rates than pathogens causing mainly systemic infections and overwintering in the rhizomes (the two rust fungi). Although the rust fungi more often occupied well-connected plant patches, the chytrid and smut fungi were equally or more common in isolated patches. Host patch size was positively related to patch occupancy and colonization rates for all pathogens. Predicting disease dynamics is crucial for understanding the ecological and evolutionary dynamics of host-pathogen interactions, and to prevent disease outbreaks. Our study shows that combining experiments, theory and field observations is a useful way to predict disease dynamics.

Automated summary

Plant pathogen traits, such as transmission mode and overwintering strategy, have significant effects on disease dynamics. Combining experimental assays, theory and field surveys, this study shows that pathogen life-history traits can predict pathogen metapopulation dynamics. Fungal pathogens infecting new plants via spores had higher patch occupancies and colonization rates compared to pathogens causing systemic infections and overwintering in rhizomes. Host patch size was positively related to patch occupancy and colonization rates for all pathogens.