Riders in the Sky (islands): Using a Mega-phylogenetic Approach to Understand Plant Species Distribution and Coexistence at the Altitudinal Limits of Angiosperm Plant Life

Overview

Journal J Biogeogr

Specialty Biology

Date 2017 Dec 19

PMID 29249850

Citations 5

Authors

Hannah E Marx

Cedric Dentant

Julien Renaud

Romain Delunel

David C Tank

Sebastien Lavergne

Affiliations

Soon will be listed here.

Abstract

Aim: Plants occurring on high-alpine summits are generally expected to persist due to adaptations to extreme selective forces caused by the harshest climates where angiosperm life is known to thrive. We assessed the relative effects of this strong environmental filter and of other historical and stochastic factors driving plant community structure in very high-alpine conditions (up to 4,000m).

Location: European Alps, Écrins National Park, France.

Methods: Using species occurrence data collected from floristic surveys on 15 summits (2,791 m - 4,102 m a.s.l.) throughout the Écrins range, along with existing molecular sequence data obtained from GenBank, we used a mega-phylogenetic approach to evaluate the phylogenetic structure of high-alpine plant species assemblages. We used three nested species pools and two null models to address the importance of species-specific and species-neutral processes for driving coexistence.

Results: Compared to the entire species pool of the study region, alpine summits exhibited a strong signal of phylogenetic clustering. Restricting statistical sampling to environmentally and historically defined species pools reduced the significance of this pattern. However, we could not reject a model that explicitly incorporates neutral colonization and local extinction in shaping community structure for dominant plant orders. Between summits, phylogenetic turnover was generally lower than expected. Environmental drivers did not explain overall phylogenetic patterns, but we found significant geographic and climatic structure in phylogenetic diversity at finer taxonomic scales.

Main Conclusions: Although we found evidence for strong phylogenetic clustering within alpine summits, we were not able to reject models of species-neutral processes to explain patterns of floristic diversity. Our results suggest that plant community structure in high-alpine regions can also be shaped by neutral processes, and not through the sole action of environmental selection as traditionally assumed for harsh and stressful environments.

Citing Articles

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Community-level phylogenetic diversity does not differ between rare and common lineages across tallgrass prairies in the northern Great Plains.

Herzog S, Latvis M Ecol Evol. 2022; 12(11):e9453.

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Phylogenetic diversity and community assembly in a naturally fragmented system.

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Alpine lichen diversity in an isolated sky island in the Colorado Plateau, USA-Insight from an integrative biodiversity inventory.

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Discovery of cryptic plant diversity on the rooftops of the Alps.

Boucher F, Dentant C, Ibanez S, Capblancq T, Boleda M, Boulangeat L Sci Rep. 2021; 11(1):11128.

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