Replicated Radiations of the Alpine Genus (Primulaceae) Driven by Range Expansion and Convergent Key Innovations

Overview

Journal J Biogeogr

Specialty Biology

Date 2014 May 3

PMID 24790287

Citations 18

Authors

Cristina Roquet

Florian C Boucher

Wilfried Thuiller

Sebastien Lavergne

Affiliations

Soon will be listed here.

Abstract

Aim: We still have limited understanding of the contingent and deterministic factors that have fostered the evolutionary success of some species lineages over others. We investigated how the interplay of intercontinental migration and key innovations promoted diversification of the genus .

Location: Mountain ranges and cold steppes of the Northern Hemisphere.

Methods: We reconstructed ancestral biogeographical ranges at regional and continental scales by means of a dispersal-extinction-cladogenesis analysis using dated Bayesian phylogenies and contrasting two migration scenarios. Based on diversification analyses under two frameworks, we tested the influence of life form on speciation rates and whether diversification has been diversity-dependent.

Results: We found that three radiations occurred in this genus, at different periods and on different continents, and that life form played a critical role in the history of . Short-lived ancestors first facilitated the expansion of the genus' range from Asia to Europe, while cushions, which appeared independently in Asia and Europe, enhanced species diversification in alpine regions. One long-distance dispersal event from Europe to North America led to the diversification of the nested genus . We found support for a model in which speciation of the North American-European clade is diversity-dependent and close to its carrying capacity, and that the diversification dynamics of the North American subclade are uncoupled from this and follow a pure birth process.

Main Conclusions: The contingency of past biogeographical connections combined with the evolutionary determinism of convergent key innovations may have led to replicated radiations of in three mountain regions of the world. The repeated emergence of the cushion life form was a convergent key innovation that fostered radiation into alpine habitats. Given the large ecological similarity of species, allopatry may have been the main mode of speciation.

Citing Articles

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Whole-genome analyses disentangle reticulate evolution of primroses in a biodiversity hotspot.

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Replicated radiation of a plant clade along a cloud forest archipelago.

Donoghue M, Eaton D, Maya-Lastra C, Landis M, Sweeney P, Olson M Nat Ecol Evol. 2022; 6(9):1318-1329.

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Tempo and drivers of plant diversification in the European mountain system.

Smycka J, Roquet C, Boleda M, Alberti A, Boyer F, Douzet R Nat Commun. 2022; 13(1):2750.

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