Geographical isolation versus dispersal: Relictual alpine grasshoppers support a model of interglacial diversification with limited hybridization

Alpine biotas are paradigmatic of the countervailing roles of geographical isolation and dispersal during diversification. In temperate regions, repeated distributional shifts driven by Pleistocene climatic oscillations produced both recurrent pulses of population fragmentation and opportunities for...

Full description

Saved in:
Bibliographic Details
Published in:Molecular ecology 2022-01, Vol.31 (1), p.296-312
Main Authors: Ortego, Joaquín, Knowles, L. Lacey
Format: Article
Language:English
Subjects:
Animals
Demographics
Dispersal
Dispersion
distributional shifts
Divergence
Evolution
Gene Flow
genetic cohesiveness
Genetic structure
Genomics
Geographical distribution
Geographical isolation
Geography
Grasshoppers
Grasshoppers - genetics
Hybridization
Hybridization, Genetic
introgression
Islands
Orthoptera
Oscillations
Phylogeny
Pleistocene
Population decline
Range extension
Reproductive isolation
reticulate evolution
Spatial distribution
speciation
Species
Taxa
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Alpine biotas are paradigmatic of the countervailing roles of geographical isolation and dispersal during diversification. In temperate regions, repeated distributional shifts driven by Pleistocene climatic oscillations produced both recurrent pulses of population fragmentation and opportunities for gene flow during range expansions. Here, we test whether a model of divergence in isolation vs. with gene flow is more likely in the diversification of flightless alpine grasshoppers of the genus Podisma from the Iberian Peninsula. The answer to this question can also provide key insights about the pace of evolution. Specifically, if the data fit a divergence in isolation model, this suggests rapid evolution of reproductive isolation. Genomic data confirm a Pleistocene origin of the species complex, and multiple analytical approaches revealed limited asymmetric historical hybridization between two taxa. Genomic‐based demographic reconstructions, spatial patterns of genetic structure and range shifts inferred from palaeodistribution modelling suggest severe range contraction accompanied by declines in effective population sizes during interglacials (i.e., contemporary populations confined to sky islands are relicts) and expansions during the coldest stages of the Pleistocene in each taxon. Although limited hybridization during secondary contact leads to phylogenetic uncertainty if gene flow is not accommodated when estimating evolutionary relationships, all species exhibit strong genetic cohesiveness. Our study lends support to the notion that the accumulation of incipient differences during periods of isolation were sufficient to lead to lineage persistence, but also that the demographic changes, dispersal constraints and spatial distribution of the sky islands themselves mediated species diversification in temperate alpine biotas.
ISSN:0962-1083
1365-294X
DOI:10.1111/mec.16225