Abstract
Rotating crop cultivars with different resistance genes could slow the evolution of virulent strains of fungal pathogens, but could also produce highly virulent pathogen strains. We present a new model that links polycyclic pathogen epidemiology and population genetics in order to predict how different strategies of rotating cultivars with different resistances will affect the evolution of pathogen virulence and the breakdown of crop resistance. We modelled a situation where there were four different resistance genes that can be deployed within each crop cultivar, and four virulence genes that may be present within the pathogen. We simulated four different rotational management strategies: (i) no rotation; (ii) a different gene every year; (iii) a different gene every 5 years; and (iv) a different combination of two stacked genes each year. Results indicate that rotating cultivars can lead to longer periods of disease suppression but also to the selection of highly virulent strains. The efficacy and relative advantage of different resistant cultivar rotation strategies depended on the fitness penalties, initial virulence allele frequencies, and ability of non-virulent pathogen genotypes to grow and reproduce on resistant cultivars. By capturing the essential processes involved, our model provides a useful new tool for investigating the evolutionary dynamics of pathogen virulence and crop resistance breakdown.
Highlights
Rotating crop cultivars with different resistance genes could slow the evolution of virulent strains of fungal pathogens, but could produce highly virulent pathogen strains
Crop resistance can be circumvented by adaptation of the pathogen if the same type of resistance is deployed over several years, as occurs with Leptosphaeria maculans populations[20,21]
Some localities are more prone to resistance breakdown events than others; for example, the mean number of virulence alleles per L. maculans isolate is higher in Australia (5.11 virulence alleles) than in Europe (4.33) and Canada (3.46)[21]
Summary
Rotating crop cultivars with different resistance genes could slow the evolution of virulent strains of fungal pathogens, but could produce highly virulent pathogen strains. We present a new model that links polycyclic pathogen epidemiology and population genetics in order to predict how different strategies of rotating cultivars with different resistances will affect the evolution of pathogen virulence and the breakdown of crop resistance. Fast paced modernisation of agricultural systems combined with significant resource input greatly impact evolutionary trajectories of pathogens and pests[8] These practices may lead to unintended outcomes, such as disease epidemics that are more severe and harder to c ontrol[3]. Crop management strategies targeting resistance durability and epidemiological control have to be developed and deployed to avoid and/or delay the evolution of virulence and the breakdown of crop resistance[2,6,20,30,31]. While rotation and/or stacking of resistance genes are efficient crop management strategies, their deployment can potentially lead to the development of ‘super-virulent’ strains
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