Evolution of a Complex Disease Resistance Gene Cluster in DiploidPhaseolusand TetraploidGlycine

Tom Ashfield,Roxanne Denny,M.A Saghai Maroof,Bernard E Pfeil,Nicolas W.G Chen,Nevin D Young,Ram Podicheti,Bruce A Roe,Ashley N Egan,Carine Ameline-Torregrosa,Roger W Innes,Milind B Ratnaparkhe,Jeff J Doyle,Valérie Geffroy,Steven Cannon

doi:10.1104/pp.112.195040

Abstract

We used a comparative genomics approach to investigate the evolution of a complex nucleotide-binding (NB)-leucine-rich repeat (LRR) gene cluster found in soybean (Glycine max) and common bean (Phaseolus vulgaris) that is associated with several disease resistance (R) genes of known function, including Rpg1b (for Resistance to Pseudomonas glycinea1b), an R gene effective against specific races of bacterial blight. Analysis of domains revealed that the amino-terminal coiled-coil (CC) domain, central nucleotide-binding domain (NB-ARC [for APAF1, Resistance genes, and CED4]), and carboxyl-terminal LRR domain have undergone distinct evolutionary paths. Sequence exchanges within the NB-ARC domain were rare. In contrast, interparalogue exchanges involving the CC and LRR domains were common, consistent with both of these regions coevolving with pathogens. Residues under positive selection were overrepresented within the predicted solvent-exposed face of the LRR domain, although several also were detected within the CC and NB-ARC domains. Superimposition of these latter residues onto predicted tertiary structures revealed that the majority are located on the surface, suggestive of a role in interactions with other domains or proteins. Following polyploidy in the Glycine lineage, NB-LRR genes have been preferentially lost from one of the duplicated chromosomes (homeologues found in soybean), and there has been partitioning of NB-LRR clades between the two homeologues. The single orthologous region in common bean contains approximately the same number of paralogues as found in the two soybean homeologues combined. We conclude that while polyploidization in Glycine has not driven a stable increase in family size for NB-LRR genes, it has generated two recombinationally isolated clusters, one of which appears to be in the process of decay.

Highlights

We used a comparative genomics approach to investigate the evolution of a complex nucleotide-binding (NB)-leucine-rich repeat (LRR) gene cluster found in soybean (Glycine max) and common bean (Phaseolus vulgaris) that is associated with several disease resistance (R) genes of known function, including Rpg1b, an R gene effective against specific races of bacterial blight
NB-LRR ORFs are present in both soybean homeologous regions homeologue 1 (H1) and homeologue 2 (H2), these ORFs display only limited conservation of synteny, based on alignments of flanking low-copy genes (Fig. 1B; Table I)
Given that the total number of intact NB-LRR genes in both Gmw H1 and Gmw H2 combined is 17, it is apparent that the polyploidization event in the Glycine lineage does not correlate with a large, stable increase in the number of intact NB-LRR genes derived from the ancestral Rpg1b region over that seen in bean