Population genomic analyses reveal connectivity via human-mediated transport across Populus plantations in North America and an undescribed sub-population of Sphaerulina musiva.

Abstract

Domestication of plant species has impacted the evolutionary dynamics of plant pathogens in agriculture and forestry. A model system for studying the consequences of plant domestication on the evolution of an emergent plant disease is the fungal pathogen Sphaerulina musiva. This ascomycete causes leaf spot and stem canker disease of Populus and its hybrids. A population genomics approach was used to determine the degree of population structure and evidence for selection on the North American population of S. musiva. A total of 122 samples of the fungus were genotyped identifying 120,016 single nucleotide polymorphisms (SNP) after quality filtering. In North America S. musiva has low to moderate degrees of differentiation among locations. Three main genetic clusters were detected: Southeastern US (SE-US), Midwest US/Canada (US-CAN), and a new British Columbia cluster (BC2). Population genomics suggest that BC2 is a novel genetic cluster from central British Columbia, clearly differentiated from previously reported S. musiva from coastal British Columbia, product of a single migration event. Phenotypic measurements from greenhouse experiments indicate lower aggressiveness of BC2 on Populus trichocarpa. In summary, S. musiva has geographic structure across broad regions indicative of gene flow among clusters. The interconnectedness of the North American S. musiva populations across large geographic distances further supports the hypothesis of anthropogenic facilitated transport of the pathogen.