Abstract
Flax is one of the eight founder crops of agriculture. It is believed to have been domesticated as a long-day plant that has since spread to survive in a wide range of eco-geographic regions extending from the warm Indian subcontinent to the low latitude east African highlands and to the cool and high-latitude Eurasia. Understanding the genetic basis underlying its adaptation and selection events throughout its dispersion is essential to develop cultivars adapted to local environmental conditions.Here we detected genetic signatures of local adaptation and selection events of flax based on 385 accessions from all major flax growing regions of the world using genome scan methods and three genomic datasets: (1) a genome-wide dataset of more than 275K single nucleotide polymorphisms (SNPs), (2) a filtered dataset of 23K SNPs with minor allele frequency >10% and, (3) a 34K exon-derived SNP dataset.Principal component (PC) and fixation index (FST)-based genome scans yielded consistent outlier SNP loci on chromosomes 1, 8, 9 and 12. Additional loci on chromosomes 3, 7, 8, 10, 11, 13 and 14 were detected using both the PC and FST methods in two of the three datasets. A genome-environment association (GEA) analysis using the 23K dataset and the first PC of cropping season temperature, day-length and latitude identified significant SNPs on chromosomes 3, 7, 9 and 13.Most of the loci detected by the three methods harbored relevant genes for local adaptation, including some that play roles in day-length, light and other biotic and abiotic stresses responses. Such genetic signatures may help to select pre-breeding materials potentially adapted to specific growing niches prior to field performance trials. Given the current low genotyping cost and freely available environmental data, the genome scans along with GEA can readily provide opportunity to sort out materials suitable to various environmental conditions from large set of germplasm in gene banks and/or in situ, thereby assisting the breeding and genetic conservation efforts.
Highlights
Adaptation of a species to a gradient of environmental conditions is attributed to the phenotypic plasticity and genetic variation within the gene pool of the species [1, 2]
Natural selection in a wide-range of environmental gradients leads to genetic divergence and selection of adapted variants [51]
Environmental variations along the latitudinal gradient are major forces of selection that lead to genetic divergence in plants [52]
Summary
Adaptation of a species to a gradient of environmental conditions is attributed to the phenotypic plasticity and genetic variation within the gene pool of the species [1, 2]. Domesticated crops have spread to extensive eco-geographic ranges, far from where their wild ancestors originated Their success along latitudinal gradients is usually governed by their phenological behavior in response to spatial variations in climate and related factors, especially day-length and temperature [6]. The agricultural founder crops that are believed to have been domesticated in the Fertile Crescent were presumed to be adapted to vernalization and long-day flowering [6] These crops are well spread throughout the world and adapted to a range of eco-geographic conditions; postdomestication genetic divergence can be observed among eco-spatially separated populations [7]. Such divergence is presumably attributed to loci selected in specific environments with high coefficients of genetic differentiation between populations that specify the genetic basis underlying the adaptation [8]
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