A single nuclear locus phylogeny of soybean based on DNA sequence

Abstract

Soybean [Glycine max (L.) Merr.] evolution was examined by sequencing portions of the restriction fragment length polymorphism (RFLP) locus A-199a of 21 taxa from the Glycininae and 1 from the Phaseoleae. Four hundred nucleotides were determined in each, aligned, and then compared for these taxa. Within the annual soybean subgenus (Soja), the four accessions differed at as many as 2.2% of the nucleotides. Among 13 perennial soybean species (subgenus Glycine), nucleotide variation ranged from 1.7% to 8.4%. The nucleotide difference between the two soybean subgenera was 3.0-7.0%. Nucleotide variation between the genus Glycine and the related genera of Neonotonia, Amphicarpa, Teramnus, and Phaseolus ranged from 8.2% to 16.4%. In addition to nucleotide substitutions, insertions/deletions (indels) differences were also observed and were consistent with nucleotide-based analysis. Cladistic analysis of the A-199a sequences was performed using Wagner parsimony to construct a soybean phylogeny. Sixteen equally parsimonious trees were produced from these data. The trees were 246 steps in length with a consistency index of 0.78. Indels distribution upon the consensus topology revealed a pattern congruent with the nucleotide-based phylogeny. The current taxonomic status of the soybean subgenera and the related genera of Neonotonia, Amphicarpa, and Teramnus were well-supported and appear monophyletic in this analysis. Homoplasy within the subgenus Glycine led to a lack of resolved topology for many of these 13 taxa. However, the Glycine clade topology was consistent with phylogenies proposed using crossing experiments and cpDNA RFLPs. These genera were arranged from ancestral to derived as: Teramnus, Amphicarpa, Neonotonia, and Glycine when Phaseolus vulgaris was used as an outgroup.