Using gradient Forest to predict climate response and adaptation in Cork oak

Climate change is impacting locally adapted species such as the keystone tree species cork oak (Quercus suber L.). Quantifying the importance of environmental variables in explaining the species distribution can help build resilient populations in restoration projects and design forest management st...

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Bibliographic Details
Published in:Journal of evolutionary biology 2021-06, Vol.34 (6), p.910-923
Main Authors: Vanhove, Mathieu, Pina‐Martins, Francisco, Coelho, Ana Cristina, Branquinho, Cristina, Costa, Augusta, Batista, Dora, Príncipe, Adriana, Sousa, Paulo, Henriques, André, Marques, Isabel, Belkadi, Bouchra, Knowles, L. Lacey, Paulo, Octávio S.
Format: Article
Language:English
Subjects:
Adaptation
Climate
Climate change
Climate prediction
Cork
Forest management
Genomics
Genotyping
Geographical distribution
Gradient Forest
Haplotypes
Keystone species
Landscape
landscape genomics
local adaptation
Nucleotides
Oak
Plant species
Polymorphism
Population structure
Project management
Quercus suber
Quercus suber L
Single-nucleotide polymorphism
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Summary:Climate change is impacting locally adapted species such as the keystone tree species cork oak (Quercus suber L.). Quantifying the importance of environmental variables in explaining the species distribution can help build resilient populations in restoration projects and design forest management strategies. Using landscape genomics, we investigated the population structure and ecological adaptation of this tree species across the Mediterranean Basin. We applied genotyping by sequencing and derived 2,583 single nucleotide polymorphism markers genotyped from 81 individuals across 17 sites in the studied region. We implemented an approach based on the nearest neighbour haplotype ‘coancestry’ and uncovered a weak population structure along an east–west climatic gradient across the Mediterranean region. We identified genomic regions potentially involved in local adaptation and predicted differences in the genetic composition across the landscape under current and future climates. Variants associated with temperature and precipitation variables were detected, and we applied a nonlinear multivariate association method, gradient forest, to project these gene–environment relationships across space. The model allowed the identification of geographic areas within the western Mediterranean region most sensitive to climate change: south‐western Iberia and northern Morocco. Our findings provide a preliminary assessment towards a potential management strategy for the conservation of cork oak in the Mediterranean Basin. Gradient Forest applied to SNPs variation associated with climate variables and projected across space allows the identification of geographic areas within the Mediterranean basin most sensitive to climate change for Cork Oak, the larger “genetic offset” in 2070 is predicted to occur in Southwest Portugal, Baetic region and Northern Morocco.
ISSN:1010-061X
1420-9101
DOI:10.1111/jeb.13765