2020
DOI: 10.1111/mec.15615
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Genomic evidence of introgression and adaptation in a model subtropical tree species, Eucalyptus grandis

Abstract: The genetic consequences of adaptation to changing environments can be deciphered using population genomics, which may help predict species' responses to global climate change. Towards this, we used genome‐wide SNP marker analysis to determine population structure and patterns of genetic differentiation in terms of neutral and adaptive genetic variation in the natural range of Eucalyptus grandis, a widely cultivated subtropical and temperate species, serving as genomic reference for the genus. We analysed intr… Show more

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Cited by 16 publications
(18 citation statements)
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“…Population differentiation patterns were investigated and compared among breeding populations, and between breeding populations, wild E. grandis (including 362 individuals from three subpopulations; Mostert‐O'Neill et al ., 2021) and other Latoangulatae species as published by Silva‐Junior et al . (2015) using four approaches: principal component analysis (PCA) with normalization to each marker’s standard deviation in S VS 8; sparse nonnegative matrix factorization (sNMF) using the lea R package (Frichot et al ., 2014; Frichot & François, 2015) – the values for K tested were K = 2 to K = 10 with five repetitions of each value and the minimum cross‐entropy (CE) was determined for each value of K and visualized; discriminant analysis of principal components (DAPC) using the adegenet R package (Jombart, 2008; Jombart et al ., 2010) with Bayesian information criterion (BIC) used to determine the most probable cluster number in the data set with K = 1 to K = 15 tested; and the extent of differentiation among breeding populations, and between breeding and wild E. grandis populations was quantified as F ‐statistics, F ST , as described by Weir & Cockerham (1984), with 95% confidence intervals in S VS 8.…”
Section: Methodsmentioning
confidence: 89%
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“…Population differentiation patterns were investigated and compared among breeding populations, and between breeding populations, wild E. grandis (including 362 individuals from three subpopulations; Mostert‐O'Neill et al ., 2021) and other Latoangulatae species as published by Silva‐Junior et al . (2015) using four approaches: principal component analysis (PCA) with normalization to each marker’s standard deviation in S VS 8; sparse nonnegative matrix factorization (sNMF) using the lea R package (Frichot et al ., 2014; Frichot & François, 2015) – the values for K tested were K = 2 to K = 10 with five repetitions of each value and the minimum cross‐entropy (CE) was determined for each value of K and visualized; discriminant analysis of principal components (DAPC) using the adegenet R package (Jombart, 2008; Jombart et al ., 2010) with Bayesian information criterion (BIC) used to determine the most probable cluster number in the data set with K = 1 to K = 15 tested; and the extent of differentiation among breeding populations, and between breeding and wild E. grandis populations was quantified as F ‐statistics, F ST , as described by Weir & Cockerham (1984), with 95% confidence intervals in S VS 8.…”
Section: Methodsmentioning
confidence: 89%
“…(2019a) and Mostert‐O’Neill et al . (2021). Two sets of genes, within 2 and 6 kb, were analysed based on the lower and upper estimates of LD decay as determined by Silva‐Junior & Grattapaglia (2015), to account for large variations in genome‐wide LD patterns in the breeding populations.…”
Section: Methodsmentioning
confidence: 99%
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