Invasive pathogens are a threat to forest and agroecosystems, as well as animal and human health. Identifying genomic determinants of pathogen evolution, as well as investigations into the genetic structure of invasive pathogen populations provide fundamental insights to why species can emerge as invasive pathogens. In this PhD project I investigated the emergence and population genomics of the invasive chestnut blight fungus Cryphonectria parasitica, using comparative and population genomic approaches. C. parasitica recently emerged as an invasive bark pathogen on non-Asian Castanea species in North America and Europe. In the first chapter, I investigated genomic determinants of lifestyle transitions in the genus Cryphonectria, by genome comparisons of C. parasitica and its sister species. The study uncovered a striking loss of genes associated with carbohydrate metabolism in the invasive pathogen C. parasitica, which may have promoted its pathogenicity on Castanea species. The second chapter explores the emergence and diversification of a highly invasive chestnut blight lineage across south-eastern Europe. By analyzing the genome-wide diversity of a large set of C. parasitica isolates of predominantly European origin, the study showed that a highly successful clonal pathogen lineage can emerge from a recombinant bridgehead population within Europe. Interestingly, the emergence of this clonal lineage was accompanied by an evolutionary transition from mixed mating type populations to single mating type outbreak populations. Lastly, in the third chapter I investigated temporal changes in genetic diversity of established C. parasitica populations in southern Switzerland, as well as potential links between the presence of the deleterious hyperparasitic mycovirus Cryphonectria hypovirus 1 (CHV1) and fungal genome-wide diversity. The results indicate increased mating among related fungal individuals, resulting in high genetic similarity of genotypes and facilitated CHV1 transmission. There were no substantial changes in fungal population structure and after ˜30 years and no detectable impact of CHV1 presence on fungal genome-wide diversity. Although our results show stable CHV1 incidence in fungal populations over three decades, the short-term interaction dynamics are likely highly volatile. The overall findings of this PhD thesis highlight the relevance of genomic determinants facilitating pathogen emergence and invasions. C. parasitica is a useful model to study fundamental questions of pathogen evolution and invasive processes, as well as antagonistic pathogen-hyperparasite interactions.
Pathogen evolution: How good bacteria go bad
