David M. Webb

Genetic mapping of soybean cyst nematode race-3 resistance loci in the soybean PI 437.654.

Resistance to the soybean cyst nematode (SCN) (Heterodera glycines Ichinohe) is difficult to evaluate in soybean [Glycine max (L.) Merr.] breeding. PI 437.654 has resistance to more SCN race isolates than any other known soybean. We screened 298 F6∶7 recombinant-inbred lines from a cross between PI 437.654 and ‘BSR101’ for SCN race-3 resistance, genetically mapped 355 RFLP markers and the I locus, and tested these markers for association with resistance loci. The Rhg4 resistance locus was within 1 cM of the I locus on linkage group A. Two additional QTLs associated with SCN resistance were located within 3cM of markers on groups G and M. These two loci were not independent because 91 of 96 lines that had a resistant-parent marker type on group G also had a resistant-parent marker type on group M. Rhg4 and the QTL on G showed a significant interaction by together providing complete resistance to SCN race-3. Individually, the QTL on G had greater effect on resistance than did Rhg4, but neither locus alone provided a degree of resistance much different from the susceptible parent. The nearest markers to the mapped QTLs on groups A and G had allele frequencies from the resistant parent indicating 52 resistant lines in this population, a number not significantly different from the 55 resistant lines found. Therefore, no QTLs from PI 437.654 other than those mapped here are expected to be required for resistance to SCN race-3. All 50 lines that had the PI 437.654 marker type at the nearest marker to each of the QTLs on groups A and G were resistant to SCN race-3. We believe markers near to these QTLs can be used effectively to select for SCN race-3 resistance, thereby improving the ability to breed SCN-resistant soybean varieties.

DNA extraction from a previously recalcitrant plant genus

Numerous DNA extraction methods failed to remove contaminants that interfere with restriction digests ofCuphea DNA. The method described here removes those contaminants and maintains relatively high DNA yields. The primary purification process consists of washing the DNA with phenol while it is complexed with CTAB and dissolved in 1 M NaCl.

Rpg1, a soybean gene effective against races of bacterial blight, maps to a cluster of previously identified disease resistance genes

Abstract Alleles, or tightly linked genes, at the soybean (Glycine max L. Merr.) Rpg1 locus confer resistance to races of Pseudomonas syringae pv. glycinea that express the avirulence genes avrB or avrRpm1. In this study we demonstrate that Rpg1 maps to a cluster of previously identified resistance genes, including those effective against fungal, viral and nematode pathogens. Rpg1 is in molecular linkage group (MLG) F, flanked by the markers K644 and B212. The RFLP markers R45, php2265 and php2385 cosegregated with Rpg1, as did the marker nbs61, which encodes a protein related to previously isolated resistance genes.

Allele-specific hybridization markers for soybean

Abstract Soybean (Glycine max) is one of the world’s most important crop plants due to extensive genetic improvements using traditional breeding approaches. Recently, marker-assisted selection has enhanced the ability of traditional breeding programs to improve soybeans. Most methods of assessing molecular markers involve electrophoretic techniques that constrain the ability to perform high-throughput analyses on breeding populations and germplasm. In order to develop a high-capacity system, we have developed allele-specific hybridization (ASH) markers for soybean. As one example, restriction fragment length polymorphism (RFLP) locus A519-1 (linkage group B) was converted into an ASH marker by (1) sequencing the pA519 cloned insert, (2) designing locus-specific PCR amplification primers, (3) comparative sequencing of A519-1 amplicons from important soybean ancestors, and (4) designing allele-specific oligonucleotide probes around single nucleotide polymorphisms (SNPs) among soybean genotypes. Two SNPs were identified within approximately 400 bp of the sequence. Allele-specific probes generated a 100-fold greater signal to target amplicons than to targets that differed by only a single nucleotide. The A519-1 ASH marker is shown to cosegregate with the A519-1 RFLP locus. In order to determine ASH usefulness, we genotyped 570 soybean lines from the Pioneer Hi-Bred soybean improvement using both A519-1 SNPs. Combined haplotype diversity (D) was 0.43 in this adapted germplasm set. These results demonstrate that ASH markers can allow for high-throughput screening of germplasm and breeding populations, greatly enhancing breeders’ capabilities to do marker-assisted selection.