Abstract
BackgroundBreeding livestock for improved resistance to disease is an increasingly important selection goal. However, the risk of pathogens adapting to livestock bred for improved disease resistance is difficult to quantify. Here, we explore the possibility of gastrointestinal worms adapting to sheep bred for low faecal worm egg count using computer simulation. Our model assumes sheep and worm genotypes interact at a single locus, such that the effect of an A allele in sheep is dependent on worm genotype, and the B allele in worms is favourable for parasitizing the A allele sheep but may increase mortality on pasture. We describe the requirements for adaptation and test if worm adaptation (1) is slowed by non-genetic features of worm infections and (2) can occur with little observable change in faecal worm egg count.ResultsAdaptation in worms was found to be primarily influenced by overall worm fitness, viz. the balance between the advantage of the B allele during the parasitic stage in sheep and its disadvantage on pasture. Genetic variation at the interacting locus in worms could be from de novo or segregating mutations, but de novo mutations are rare and segregating mutations are likely constrained to have (near) neutral effects on worm fitness. Most other aspects of the worm infection we modelled did not affect the outcomes. However, the host-controlled mechanism to reduce faecal worm egg count by lowering worm fecundity reduced the selection pressure on worms to adapt compared to other mechanisms, such as increasing worm mortality. Temporal changes in worm egg count were unreliable for detecting adaptation, despite the steady environment assumed in the simulations.ConclusionsAdaptation of worms to sheep selected for low faecal worm egg count requires an allele segregating in worms that is favourable in animals with improved resistance but less favourable in other animals. Obtaining alleles with this specific property seems unlikely. With support from experimental data, we conclude that selection for low faecal worm egg count should be stable over a short time frame (e.g. 20 years). We are further exploring model outcomes with multiple loci and comparing outcomes to other control strategies.
Highlights
Breeding livestock for improved resistance to disease is an increasingly important selection goal
We investigate whether the expectation of worm adaptation to low worm egg count (WEC) sheep is realistic and attempt to determine factors that influence this potential rate of evolution
This paper examined the conditions required for adaptation of worms at a single locus to sheep with an allele that confers low WEC, and tested two hypotheses related to rates of worm adaptation
Summary
Breeding livestock for improved resistance to disease is an increasingly important selection goal. Sheep selected over many generations for low faecal worm egg count (WEC) show large reductions in WEC when infected with gastro-intestinal parasites [1,2,3] This reduction in WEC indicates a reduced reproductive capacity, or reduced fitness, for worms in these hosts. It is important to know which factors might be applicable to other livestock disease systems (i.e. species and pathogens) such as selection of salmon or chickens for improved resistance to bacterial or viral infections. This investigation aims at identifying the key theoretical parameters that determine adaptation of nematodes in sheep. Results of this study may give insight into the possible influence of these parameters in other situations
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