The Evolution of Host‐Parasite Range

Best, Alex; White, Ann; Kisdi, Éva; Antonovics, Janis; Brockhurst, Michael A.; Boots, Mike

doi:10.1086/653002

Cited by 69 publications

(134 citation statements)

References 53 publications

(61 reference statements)

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“…More broadly, our model of within-population structuring owing to local interactions predicts that spatial structure makes diversity through evolutionarybranching less likely, contrasting with the predicted effects on diversity in gene-for-gene with metapopulation structure [27]. This emphasizes not only the importance of the infection genetics to the coevolution of diversity in hosts and parasites [41] but also the fact that different forms of spatial structure may cause different selective pressures [34]. Figure 4.…”

Section: Discussionmentioning

confidence: 86%

Host resistance and coevolution in spatially structured populations

et al. 2010

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Natural, agricultural and human populations are structured, with a proportion of interactions occurring locally or within social groups rather than at random. This within-population spatial and social structure is important to the evolution of parasites but little attention has been paid to how spatial structure affects the evolution of host resistance, and as a consequence the coevolutionary outcome. We examine the evolution of resistance across a range of mixing patterns using an approximate mathematical model and stochastic simulations. As reproduction becomes increasingly local, hosts are always selected to increase resistance. More localized transmission also selects for higher resistance, but only if reproduction is also predominantly local. If the hosts disperse, lower resistance evolves as transmission becomes more local. These effects can be understood as a combination of genetic (kin) and ecological structuring on individual fitness. When hosts and parasites coevolve, local interactions select for hosts with high defence and parasites with low transmissibility and virulence. Crucially, this means that more population mixing may lead to the evolution of both fast-transmitting highly virulent parasites and reduced resistance in the host.

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Section: Discussionmentioning

confidence: 86%

Host resistance and coevolution in spatially structured populations

et al. 2010

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“…Gandon and Michalis, 2000;Bull and Ebert, 2008). On the other hand, the hostparasite relationship of a host with long life span and a parasite with long infective periods is supposed to create diversity among both hosts and parasites (Best et al, 2010), which could thus re-balance relationship of A. astaci and, at least, its North American hosts in Europe. Environmental conditions could, in their part, also be a driving force of the host-parasite coevolution (Wolinska and King, 2009;Biron and Loxdale, 2013) and thus might also be affecting the aforementioned balance.…”

Section: Introductionmentioning

confidence: 99%

Aphanomyces astaciPsI-genotype isolates from different Finnish signal crayfish stocks show variation in their virulence but still kill fast

Jussila

Kokko

Kortet

et al. 2013

Knowl. Managt. Aquatic Ecosyst.

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Key-words:crayfish plague, noble crayfish, potent killer, Psorospermium haeckeliWe detected significant virulence differences among five tested (PsI-Puujärvi, PsI-Pyhäjärvi, PsI-Kukkia, PsI-Saimaa I and PsI-Saimaa II) PsI-genotype crayfish plague (Aphanomyces astaci) isolates against lake Mikitänjärvi noble crayfish population. The crayfish were inoculated with a dose of 300 m·L −1 A. astaci spores in ambient water under experimental conditions. Mortalities started from four to seven days after inoculation, depending on the PsI-genotype isolate. In all the experimentally infected groups it took no more than three days for all the crayfish to die after the first mortality. The PsI-Puujärvi isolate proved to be the most virulent strain, while PsI-Kukkia was the least virulent. The average day of death for these experimental groups was fifth and ninth day, respectively. We did not discover correlation between the average day of death and gender or level of additional Psorospermium haeckeli infestation. Our results show that there are, from the practical point of view, minor virulence differences among PsI-genotype A. astaci isolates, and that all the tested five isolates are highly virulent. The present results emphasize the necessity to prevent all further spread of highly virulent strains of A. astaci to aid and shelter successful conservations attempts of the native European crayfishes.

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“…This in effect creates two niches for parasitism, and therefore again allows for evolutionary branching. A similar effect was shown where hosts and parasites could coevolve their respective resistance and infection 'ranges' [31]. They found the potential for multiple branching events leading to high levels of diversity in both hosts and parasites as well as for evolutionary cycles.…”

Section: Introductionmentioning

confidence: 55%

“…We note that MI is now a stability condition in its own right. As for either strain to be able to branch again it is required that it must have MI , 0, and that the trade-off curvature can always be chosen to satisfy the other conditions [31,35,36], we therefore limit our analysis to determining the sign of this condition. After some work, we find this condition reduces to (appendix B)…”

Section: Two-strain Systemmentioning

confidence: 99%

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A limited host immune range facilitates the creation and maintenance of diversity in parasite virulence

Best

Hoyle

2013

Interface Focus.

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A vast theoretical literature has explored the evolutionary dynamics of parasite virulence. The classic result from this modelling work is that, assuming a saturating transmission–virulence trade-off, there is a single evolutionary optimum where the parasite optimizes the epidemiological R0. However, there are an increasing number of models that have shown how ecological and epidemiological feedbacks to evolution can instead result in the creation and maintenance of multiple parasite strains. Here, we fully explore one such example, where recovered hosts have a limited ‘immune range’ resulting in partial cross-immunity to parasite strains that they have not previously encountered. Taking an adaptive dynamics approach, we show that, provided this immune range is not too wide, high levels of diversity can evolve and be maintained through multiple branching events. We argue that our model provides a more realistic picture of disease dynamics in vertebrate host populations and may be a key explanatory factor in the high levels of parasite diversity seen in natural systems

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The Evolution of Host‐Parasite Range

Cited by 69 publications

References 53 publications

Host resistance and coevolution in spatially structured populations

Host resistance and coevolution in spatially structured populations

Aphanomyces astaciPsI-genotype isolates from different Finnish signal crayfish stocks show variation in their virulence but still kill fast

A limited host immune range facilitates the creation and maintenance of diversity in parasite virulence

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