Fusarium solani species complex genomes reveal bases of compartmentalisation and animal pathogenesis

Abstract

AbstractThe Fusarium solani species complex (FSSC) comprises fungal pathogens responsible for mortality in a diverse range of animals and plants, but their genome diversity and transcriptome responses in animal pathogenicity remain to be elucidated. We sequenced and compared six chromosome-level FSSC clade 3 genomes of aquatic animal and plant host origins and revealed a spectrum of conservation patterns in chromosomes categorised into three compartments: core, fast-core (FC), and lineage-specific (LS). Each chromosome type varied in structural architectures, with FC and LS chromosomes containing significantly higher proportions of repetitive elements and methylation levels than core chromosomes, with genes exhibiting higher dN/dS and enriched in functions related to pathogenicity and niche expansion. Mesosynteny were detected between FC chromosomes of Fusarium genomes, indicating that these chromosomes were present in a common ancestor that predated FSSC species. These findings provide evidence that genome compartmentalisation was the outcome of multi-speed evolution amongst FSSC chromosomes. We further demonstrated that F. falciforme and F. keratoplasticum are opportunistic pathogens by inoculating Pelodiscus sinensis eggs and identified differentially expressed genes also associated with plant pathogenicity. These included the most upregulated genes encoding the CFEM (Common in Fungal Extracellular Membrane) domain. The study establishes genomic resources and an animal model for fungal pathogens of trans-kingdom hosts.