Temporal variation in spatial genetic structure during population outbreaks: Distinguishing among different potential drivers of spatial synchrony
Autor: | Jeremy Larroque, Sébastien Renaut, Michel Cusson, Patrick M. A. James, Lisa M. Lumley, Roger C. Levesque, Rob C. Johns, Simon Legault |
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Jazyk: | angličtina |
Rok vydání: | 2019 |
Předmět: |
0106 biological sciences
0301 basic medicine Population lcsh:Evolution Climate change SNP Biology 010603 evolutionary biology 01 natural sciences 03 medical and health sciences cyclic populations Genetics lcsh:QH359-425 spruce budworm insect outbreak education Ecology Evolution Behavior and Systematics Isolation by distance Spruce budworm education.field_of_study Genetic diversity temporal genetics spatial genetics synchrony Original Articles 15. Life on land biology.organism_classification Choristoneura fumiferana 030104 developmental biology Evolutionary biology Genetic structure Biological dispersal Original Article General Agricultural and Biological Sciences |
Zdroj: | Evolutionary Applications, Vol 12, Iss 10, Pp 1931-1945 (2019) Evolutionary Applications |
ISSN: | 1752-4571 |
Popis: | Spatial synchrony is a common characteristic of spatio‐temporal population dynamics across many taxa. While it is known that both dispersal and spatially autocorrelated environmental variation (i.e., the Moran effect) can synchronize populations, the relative contributions of each, and how they interact, are generally unknown. Distinguishing these mechanisms and their effects on synchrony can help us to better understand spatial population dynamics, design conservation and management strategies, and predict climate change impacts. Population genetic data can be used to tease apart these two processes as the spatio‐temporal genetic patterns they create are expected to be different. A challenge, however, is that genetic data are often collected at a single point in time, which may introduce context‐specific bias. Spatio‐temporal sampling strategies can be used to reduce bias and to improve our characterization of the drivers of spatial synchrony. Using spatio‐temporal analyses of genotypic data, our objective was to identify the relative support for these two mechanisms to the spatial synchrony in population dynamics of the irruptive forest insect pest, the spruce budworm (Choristoneura fumiferana), in Quebec (Canada). AMOVA, cluster analysis, isolation by distance, and sPCA were used to characterize spatio‐temporal genomic variation using 1,370 SBW larvae sampled over four years (2012–2015) and genotyped at 3,562 SNP loci. We found evidence of overall weak spatial genetic structure that decreased from 2012 to 2015 and a genetic diversity homogenization among the sites. We also found genetic evidence of a long‐distance dispersal event over >140 km. These results indicate that dispersal is the key mechanism involved in driving population synchrony of the outbreak. Early intervention management strategies that aim to control source populations have the potential to be effective through limiting dispersal. However, the timing of such interventions relative to outbreak progression is likely to influence their probability of success. |
Databáze: | OpenAIRE |
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