Abstract
Comparative studies of genetic diversity and population structure can shed light on the ecological and evolutionary factors governing host–parasite interactions. Even though invasive parasites are considered of major biological importance, little is known about their adaptative potential when infesting the new hosts. Here, the genetic diversification of Varroa destructor, a novel parasite of Apis mellifera originating from Asia, was investigated using population genetics to determine how the genetic structure of the parasite changed in distinct European populations of its new host. To do so, mites infesting two categories of hosts in four European regions were compared: (a) adapted hosts surviving through means of natural selection, thereby expected to impose strong selective pressure on the mites, and (b) treated host populations, surviving mite infestations because acaricides are applied, therefore characterized by a relaxed selection imposed by the host on the mites. Significant genetic divergence was found across regions, partially reflecting the invasion pattern of V. destructor throughout Europe and indicating local adaptation of the mite to the host populations. Additionally, varying degrees of genotypic changes were found between mites from adapted and treated colonies. Altogether, these results indicate that V. destructor managed to overcome the genetic bottlenecks following its introduction in Europe and that host‐mediated selection fostered changes in the genetic structure of this mite at diverse geographic scales. These findings highlight the potential of parasites to adapt to their local host populations and confirm that adaptations developed within coevolutionary dynamics are a major determinant of population genetic changes.
Highlights
Coevolution is a process of reciprocal evolutionary changes between interacting species (Ehrlich & Raven, 1964; Thompson, 2005)
Our results suggest that the genetic structure of European V. destructor is shaped by their interactions with their local host populations
These findings reveal that sympatric and allopatric mite populations are experiencing significant levels of genetic divergence that are probably caused by both unique host population traits and environmental differences across locations
Summary
Coevolution is a process of reciprocal evolutionary changes between interacting species (Ehrlich & Raven, 1964; Thompson, 2005). Out of the many V. destructor haplotypes found in A. cerana colonies (Navajas, 2010), only two are known to have switched to A. mellifera and to have emigrated from Asia (Anderson & Trueman, 2000) In addition to this original bottleneck, and coupled with the incestuous mating behavior of the mite (Rosenkranz et al 2010), the host shift and subsequent spread of the pest has resulted in a highly homogenous genetic population structure within the invasive populations of V. destructor (Solignac et al, 2005). The genetic structure of V. destructor populations infesting honey bee colonies that are adapted to the mite versus those that are susceptible and require mite control for survival may follow different evolutionary paths and result in a geographic mosaic of coevolution (Thompson, 2005). Our results show significant genetic diversification across V. destructor populations in the studied regions and host populations, thereby suggesting that mites have overcome the initial bottleneck of their introduction and are adapting to their local host populations as predicted by the geographic mosaic of coevolution theory (Thompson, 2005)
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