Genetic patterns of habitat fragmentation and past climate-change effects in the Mediterranean high-mountain plant Armeria caespitosa (Plumbaginaceae)

• Premise of the Study: Mountain plants are among the species most vulnerable to global warming, because of their isolation, narrow geographic distribution, and limited geographic range shifts. Stochastic and selective processes can act on the genome, modulating genetic structure and diversity. Frag...

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Bibliographic Details
Published in:American journal of botany 2013-08, Vol.100 (8), p.1641-1650
Main Authors: García-Fernández, Alfredo, Iriondo, Jose M, Escudero, Adrián, Aguilar, Javier Fuertes, Feliner, Gonzalo Nieto
Format: Article
Language:English
Subjects:
Altitude
amplified fragment length polymorphism
Amplified Fragment Length Polymorphism Analysis
Armeria
Bayesian analysis
Botany
Climate
Climate Change
divergent selection
Ecological genetics
Ecosystem
Flowers & plants
Gene Flow
Genetic diversity
Genetic Loci
genetic structure
Genetic Structures
Genetic Variation
Genetics
Genetics, Population
genome
Genome, Plant - genetics
geographical distribution
Geography
global warming
habitat fragmentation
Habitats
indigenous species
loci
Microsatellite Repeats - genetics
mountain habitat
Mountains
outlier loci
Plants
plants (botany)
Plumbaginaceae
Plumbaginaceae - genetics
Population Biology
Population ecology
Population genetics
Population structure
Spain
spatial autocorrelation
Species
stochastic processes
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Summary:• Premise of the Study: Mountain plants are among the species most vulnerable to global warming, because of their isolation, narrow geographic distribution, and limited geographic range shifts. Stochastic and selective processes can act on the genome, modulating genetic structure and diversity. Fragmentation and historical processes also have a great influence on current genetic patterns, but the spatial and temporal contexts of these processes are poorly known. We aimed to evaluate the microevolutionary processes that may have taken place in Mediterranean high-mountain plants in response to changing historical environmental conditions.• Methods: Genetic structure, diversity, and loci under selection were analyzed using AFLP markers in 17 populations distributed over the whole geographic range of Armeria caespitosa, an endemic plant that inhabits isolated mountains (Sierra de Guadarrama, Spain). Differences in altitude, geographic location, and climate conditions were considered in the analyses, because they may play an important role in selective and stochastic processes.• Key Results: Bayesian clustering approaches identified nine genetic groups, although some discrepancies in assignment were found between alternative analyses. Spatially explicit analyses showed a weak relationship between genetic parameters and spatial or environmental distances. However, a large proportion of outlier loci were detected, and some outliers were related to environmental variables.• Conclusions: A. caespitosa populations exhibit spatial patterns of genetic structure that cannot be explained by the isolation-by-distance model. Shifts along the altitude gradient in response to Pleistocene climatic oscillations and environmentally mediated selective forces might explain the resulting structure and genetic diversity values found.
ISSN:0002-9122
1537-2197
DOI:10.3732/ajb.1200653