Abstract
The genetic and environmental homogeneity in agricultural ecosystems is thought to impose strong and uniform selection pressures. However, the impact of this selection on plant pathogen genomes remains largely unknown. We aimed to identify the proportion of the genome and the specific gene functions under positive selection in populations of the fungal wheat pathogen Zymoseptoria tritici. First, we performed genome scans in four field populations that were sampled from different continents and on distinct wheat cultivars to test which genomic regions are under recent selection. Based on extended haplotype homozygosity and composite likelihood ratio tests, we identified 384 and 81 selective sweeps affecting 4% and 0.5% of the 35 Mb core genome, respectively. We found differences both in the number and the position of selective sweeps across the genome between populations. Using a XtX‐based outlier detection approach, we identified 51 extremely divergent genomic regions between the allopatric populations, suggesting that divergent selection led to locally adapted pathogen populations. We performed an outlier detection analysis between two sympatric populations infecting two different wheat cultivars to identify evidence for host‐driven selection. Selective sweep regions harboured genes that are likely to play a role in successfully establishing host infections. We also identified secondary metabolite gene clusters and an enrichment in genes encoding transporter and protein localization functions. The latter gene functions mediate responses to environmental stress, including interactions with the host. The distinct gene functions under selection indicate that both local host genotypes and abiotic factors contributed to local adaptation.
Highlights
Agricultural plant pathogens are responsible for widespread epidemics and can quickly overcome control methods (McDonald & Stukenbrock, 2016)
We aimed to identify the proportion of the genome and the specific gene functions under positive selection in populations of the fungal wheat pathogen Zymoseptoria tritici
Based on extended haplotype homozygosity and composite likelihood ratio tests, we identified 384 and 81 selective sweeps affecting 4% and 0.5% of the 35 Mb core genome, respectively
Summary
Agricultural plant pathogens are responsible for widespread epidemics and can quickly overcome control methods (McDonald & Stukenbrock, 2016). The fixation of adaptive mutations in the mitochondrial cytochrome b gene and the CYP51 gene contributed to strobilurin and azole fungicide resistance, respectively (Brunner, Stefanato, & Mcdonald, 2008; Brunner, Stefansson, Fountaine, Richina, & McDonald, 2015; Delmas et al, 2017; Estep et al, 2015; Pereira, McDonald, & Brunner, 2017; Torriani, Brunner, McDonald, & Sierotzki, 2009) Despite these examples, the proportion of the genome under positive selection and the functions of the loci in these selected regions remain largely unknown. Because similar agricultural practices can lead to similar environments (e.g., by planting genetically identical crops, applying the same fertilizers and spraying the same fungicides) for pathogen populations on different continents, there are opportunities for parallel adaptation affecting the same pathogen traits It remains largely unknown whether the same loci will be affected in the same way by similar selection pressures applied in different regions (Croll & McDonald, 2016). The analyses of the two sympatric populations revealed genes likely to be involved in host adaptation
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