Host adaptation and genome evolution of the broad host range fungal rust pathogen, Austropuccinia psidii

Rust diseases on plants are caused by fungi in the order Pucciniales. Typically, rust fungi have narrow host specificity however the pandemic biotype of Austropuccinia psidii has an unusually broad host range causing disease on over 480 myrtaceous species globally. We assembled and analysed a fully phased chromosome-level genome for the pandemic A. psidii and addressed key outstanding questions of its infection biology. Our research revealed a conserved rust fungal karyotype of 18 haploid chromosomes, in line with fungi for distantly related cereal rusts. We observed chromosomal re-assortment between the two nuclei, with one nucleus carrying 19 and the other 17 chromosomes. The synteny of universal single-copy orthologs is mostly maintained with the distantly related rust fungus Puccinia graminis f. sp. tritici . In contrast, nucleotide composition and methylation profiles of A. psidii are distinct compared to rust fungi with smaller genome sizes that have not undergone massive transposable element expansions. Our analysis of mating type loci supports a tetrapolar mating system for A. psidii with a novel finding of expanded numbers of pheromone peptide precursors. We show that infection dynamics of A. psidii are consistent on four different susceptible host species separated by 65 mya of evolution and that transcriptional regulation during infection reveals two distinct waves of gene expression in early and late infection, including allele-specific expression of candidate effectors. Together, these findings enhance the understanding of the genome biology and pathology of A. psidii , while also providing a valuable resource for future research on this serious rust pathogen.