Abstract
BackgroundAlfalfa, a perennial, outcrossing species, is a widely planted forage legume producing highly nutritious biomass. Currently, improvement of cultivated alfalfa mainly relies on recurrent phenotypic selection. Marker assisted breeding strategies can enhance alfalfa improvement efforts, particularly if many genome-wide markers are available. Transcriptome sequencing enables efficient high-throughput discovery of single nucleotide polymorphism (SNP) markers for a complex polyploid species.ResultThe transcriptomes of 27 alfalfa genotypes, including elite breeding genotypes, parents of mapping populations, and unimproved wild genotypes, were sequenced using an Illumina Genome Analyzer IIx. De novo assembly of quality-filtered 72-bp reads generated 25,183 contigs with a total length of 26.8 Mbp and an average length of 1,065 bp, with an average read depth of 55.9-fold for each genotype. Overall, 21,954 (87.2%) of the 25,183 contigs represented 14,878 unique protein accessions. Gene ontology (GO) analysis suggested that a broad diversity of genes was represented in the resulting sequences. The realignment of individual reads to the contigs enabled the detection of 872,384 SNPs and 31,760 InDels. High resolution melting (HRM) analysis was used to validate 91% of 192 putative SNPs identified by sequencing. Both allelic variants at about 95% of SNP sites identified among five wild, unimproved genotypes are still present in cultivated alfalfa, and all four US breeding programs also contain a high proportion of these SNPs. Thus, little evidence exists among this dataset for loss of significant DNA sequence diversity from either domestication or breeding of alfalfa. Structure analysis indicated that individuals from the subspecies falcata, the diploid subspecies caerulea, and the tetraploid subspecies sativa (cultivated tetraploid alfalfa) were clearly separated.ConclusionWe used transcriptome sequencing to discover large numbers of SNPs segregating in elite breeding populations of alfalfa. Little loss of SNP diversity was evident between unimproved and elite alfalfa germplasm. The EST and SNP markers generated from this study are publicly available at the Legume Information System ( http://medsa.comparative-legumes.org/) and can contribute to future alfalfa research and breeding applications.
Highlights
Alfalfa, a perennial, outcrossing species, is a widely planted forage legume producing highly nutritious biomass
The EST and single nucleotide polymorphism (SNP) markers generated from this study are publicly available at the Legume Information System and can contribute to future alfalfa research and breeding applications
Framework genetic linkage maps have been constructed for diploid and tetraploid alfalfa using a limited number of AFLP, RFLP, and SSR markers [3,4,5,6,7], and QTL associated with agronomic traits have been identified, albeit within relatively large genomic regions [8,9,10,11,12]
Summary
A perennial, outcrossing species, is a widely planted forage legume producing highly nutritious biomass. RNA-seq, large numbers of SNPs have been identified recently within and between two highly divergent alfalfa genotypes [17,18] and a high resolution melting technology has been implemented to assay individual SNP markers in tetraploid alfalfa [19]. While these experiments identified numerous SNPs that can be used as markers, the source genotypes were not derived from elite breeding populations, and one of the individuals was derived from subsp. Further transcriptome sequencing of a broader array of germplasm, including diverse elite breeding genotypes, could identify SNPs that would be more useful in modern alfalfa breeding programs
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