Abstract
BackgroundCotton (Gossypium spp.) is the largest producer of natural fibers for textile and is an important crop worldwide. Crop production is comprised primarily of G. hirsutum L., an allotetraploid. However, elite cultivars express very small amounts of variation due to the species monophyletic origin, domestication and further bottlenecks due to selection. Conversely, wild cotton species harbor extensive genetic diversity of prospective utility to improve many beneficial agronomic traits, fiber characteristics, and resistance to disease and drought. Introgression of traits from wild species can provide a natural way to incorporate advantageous traits through breeding to generate higher-producing cotton cultivars and more sustainable production systems. Interspecific introgression efforts by conventional methods are very time-consuming and costly, but can be expedited using marker-assisted selection.ResultsUsing transcriptome sequencing we have developed the first gene-associated single nucleotide polymorphism (SNP) markers for wild cotton species G. tomentosum, G. mustelinum, G. armourianum and G. longicalyx. Markers were also developed for a secondary cultivated species G. barbadense cv. 3–79. A total of 62,832 non-redundant SNP markers were developed from the five wild species which can be utilized for interspecific germplasm introgression into cultivated G. hirsutum and are directly associated with genes. Over 500 of the G. barbadense markers have been validated by whole-genome radiation hybrid mapping. Overall 1,060 SNPs from the five different species have been screened and shown to produce acceptable genotyping assays.ConclusionsThis large set of 62,832 SNPs relative to cultivated G. hirsutum will allow for the first high-density mapping of genes from five wild species that affect traits of interest, including beneficial agronomic and fiber characteristics. Upon mapping, the markers can be utilized for marker-assisted introgression of new germplasm into cultivated cotton and in subsequent breeding of agronomically adapted types, including cultivar development.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-945) contains supplementary material, which is available to authorized users.
Highlights
Cotton (Gossypium spp.) is the largest producer of natural fibers for textile and is an important crop worldwide
single nucleotide polymorphism (SNP) development Utilizing the G. hirsutum transcriptome assembly produced by Ashrafi et al consisting of 72,450 contigs covering over 70 M bp with N50 of 1,100 bp, transcriptome sequence reads (Table 1) were aligned and utilized to identity and filter a total of 10,888 SNPs in silico for G. barbadense line 3–79 relative to G. hirsutum line TM-1
With the same bioinformatic pipeline, SNPs were developed for G. tomentosum (9,520), G. mustelinum (10,988), G. armourianum (26,974), and G. longicalyx (38,217)
Summary
Cotton (Gossypium spp.) is the largest producer of natural fibers for textile and is an important crop worldwide. Introgression of traits from wild species can provide a natural way to incorporate advantageous traits through breeding to generate higher-producing cotton cultivars and more sustainable production systems. Cotton (Gossypium spp.) is the leading natural fiber crop worldwide and an important contributor to the economies of nearly 100 countries. The genus Gossypium is an important model species for polyploidy and the biological processes of cell wall elongation and cellulose biosynthesis in fiber cells. This clade consists of approximately 45 diploid species and five allotetraploid species. Upland cotton cultivation represents over 95% of the fiber produced worldwide due to its high yield, but generally Pima cotton the most cultivated cotton, exhibits longer, stronger, and finer fiber
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