Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.

Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.

Lucanus cervus (L.), the stag beetle, is a saproxylic beetle species distributed widely across Europe. Throughout its distribution the species has exhibited pronounced declines and is widely considered threatened. Conservation efforts may be hindered by the lack of population genetic data and unders...

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Main Authors: Karen Cox, Niall McKeown, Gloria Antonini, Deborah Harvey, Emanuela Solano, An Van Breusegem, Arno Thomaes
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2019-01-01
Series:PLoS ONE
Online Access:https://doi.org/10.1371/journal.pone.0215860
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spelling doaj-63750e367d2a46a283a1687751ae31a22021-03-03T20:42:57ZengPublic Library of Science (PLoS)PLoS ONE1932-62032019-01-01144e021586010.1371/journal.pone.0215860Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.Karen CoxNiall McKeownGloria AntoniniDeborah HarveyEmanuela SolanoAn Van BreusegemArno ThomaesLucanus cervus (L.), the stag beetle, is a saproxylic beetle species distributed widely across Europe. Throughout its distribution the species has exhibited pronounced declines and is widely considered threatened. Conservation efforts may be hindered by the lack of population genetic data and understanding of the spatial scale of population connectivity. To address this knowledge gap this research details the first broad scale phylogeographic study of L. cervus based on mitochondrial DNA (mtDNA) sequencing and microsatellite analysis of samples collected from 121 localities across Europe. Genetic data were complemented by palaeo-distribution models of spatial occupancy during the Last Glacial Maximum to strengthen inferences of refugial areas. A salient feature of the mtDNA was the identification of two lineages. Lineage I was widespread across Europe while lineage II was confined to Greece. Microsatellites supported the differentiation of the Greek samples and alongside palaeo-distribution models indicated this area was a glacial refuge. The genetic endemism of the Greek samples, and demographic results compatible with no signatures of spatial expansion likely reflects restricted dispersal into and out of the area. Lineage I exhibited a shallow star like phylogeny compatible with rapid population expansion across Europe. Demographic analysis indicated such expansions occurred after the Last Glacial Maximum. Nuclear diversity and hindcast species distribution models indicated a central Italian refuge for lineage I. Palaeo-distribution modelling results also suggested a western refuge in northern Iberia and south-west France. In conclusion the results provide evidence of glacial divergence in stag beetle while also suggesting high, at least on evolutionary timescales, gene flow across most of Europe. The data also provide a neutral genetic framework against which patterns of phenotypic variation may be assessed.https://doi.org/10.1371/journal.pone.0215860
collection DOAJ
language English
format Article
sources DOAJ
author Karen Cox
Niall McKeown
Gloria Antonini
Deborah Harvey
Emanuela Solano
An Van Breusegem
Arno Thomaes
spellingShingle Karen Cox
Niall McKeown
Gloria Antonini
Deborah Harvey
Emanuela Solano
An Van Breusegem
Arno Thomaes
Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.
PLoS ONE
author_facet Karen Cox
Niall McKeown
Gloria Antonini
Deborah Harvey
Emanuela Solano
An Van Breusegem
Arno Thomaes
author_sort Karen Cox
title Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.
title_short Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.
title_full Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.
title_fullStr Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.
title_full_unstemmed Phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the European stag beetle.
title_sort phylogeographic structure and ecological niche modelling reveal signals of isolation and postglacial colonisation in the european stag beetle.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2019-01-01
description Lucanus cervus (L.), the stag beetle, is a saproxylic beetle species distributed widely across Europe. Throughout its distribution the species has exhibited pronounced declines and is widely considered threatened. Conservation efforts may be hindered by the lack of population genetic data and understanding of the spatial scale of population connectivity. To address this knowledge gap this research details the first broad scale phylogeographic study of L. cervus based on mitochondrial DNA (mtDNA) sequencing and microsatellite analysis of samples collected from 121 localities across Europe. Genetic data were complemented by palaeo-distribution models of spatial occupancy during the Last Glacial Maximum to strengthen inferences of refugial areas. A salient feature of the mtDNA was the identification of two lineages. Lineage I was widespread across Europe while lineage II was confined to Greece. Microsatellites supported the differentiation of the Greek samples and alongside palaeo-distribution models indicated this area was a glacial refuge. The genetic endemism of the Greek samples, and demographic results compatible with no signatures of spatial expansion likely reflects restricted dispersal into and out of the area. Lineage I exhibited a shallow star like phylogeny compatible with rapid population expansion across Europe. Demographic analysis indicated such expansions occurred after the Last Glacial Maximum. Nuclear diversity and hindcast species distribution models indicated a central Italian refuge for lineage I. Palaeo-distribution modelling results also suggested a western refuge in northern Iberia and south-west France. In conclusion the results provide evidence of glacial divergence in stag beetle while also suggesting high, at least on evolutionary timescales, gene flow across most of Europe. The data also provide a neutral genetic framework against which patterns of phenotypic variation may be assessed.
url https://doi.org/10.1371/journal.pone.0215860
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