Gradual Distance Dispersal Shapes the Genetic Structure in an Alpine Grasshopper.

Juan Carlos Illera,José Ramón Obeso,Paola Laiolo,Carlos A López-Sánchez,Miguel Arenas

doi:10.3390/genes10080590

Juan Carlos Illera, José Ramón Obeso + Show 3 more

Open Access

https://doi.org/10.3390/genes10080590

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Journal: Genes	Publication Date: Aug 5, 2019
Citations: 4	License type: CC BY 4.0

Affiliation: University of Oviedo, Universidade de Vigo

Abstract

The location of the high mountains of southern Europe has been crucial in the phylogeography of most European species, but how extrinsic (topography of sky islands) and intrinsic features (dispersal dynamics) have interacted to shape the genetic structure in alpine restricted species is still poorly known. Here we investigated the mechanisms explaining the colonisation of Cantabrian sky islands in an endemic flightless grasshopper. We scrutinised the maternal genetic variability and haplotype structure, and we evaluated the fitting of two migration models to understand the extant genetic structure in these populations: Long-distance dispersal (LDD) and gradual distance dispersal (GDD). We found that GDD fits the real data better than the LDD model, with an onset of the expansion matching postglacial expansions after the retreat of the ice sheets. Our findings suggest a scenario with small carrying capacity, migration rates, and population growth rates, being compatible with a slow dispersal process. The gradual expansion process along the Cantabrian sky islands found here seems to be conditioned by the suitability of habitats and the presence of alpine corridors. Our findings shed light on our understanding about how organisms which have adapted to live in alpine habitats with limited dispersal abilities have faced new and suitable environmental conditions.

Highlights

Understanding the evolution of Pleistocene glacial periods in temperate regions has been instrumental in disentangling much of the biogeographic distributions and genetic structure of their biotas
We evaluated how two migration models, long-distance dispersal (LDD) and gradual distance dispersal (GDD), fit the real data
We applied 31 SS: (i) Genetic diversity in every group and in all groups together, and (ii) genetic differentiation (FST) among every combination of two groups and from all groups together. We found that this set of SS provides robust approximate Bayesian computation (ABC) inferences

Summary

Introduction

Understanding the evolution of Pleistocene glacial periods in temperate regions has been instrumental in disentangling much of the biogeographic distributions and genetic structure of their biotas. The role of the southern European peninsulas acting as glacial refugia for terrestrial biotas during glacial periods, and serving as the cradle for postglacial expansions after the retreat of the ice sheets, has been confirmed in Mediterranean, continental and alpine species [5,6,7,8]. Among these groups, alpine taxa have been most strongly shaped in their evolutionary history by the geographic location and complexity of the European high mountains, and a large number of taxa are endemic to these mountain ranges [9,10,11]. We are far from a detailed understanding about the genetic consequences of shifting distributions in taxa with restricted dispersal abilities, and especially on species living along the sky islands of southern Europe.

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