Construction and expression of a synthetic wheat storage protein gene.

A synthetic wheat high-molecular-weight (HMW) glutenin storage protein gene analog was constructed for expression in E. coli. This first synthetic HMW-glutenin gene and future modifications are intended to allow systematic dissection of the molecular basis of HMW-glutenin role in the visco-elastic properties critical for wheat product processing and utilization. The design of the gene included four features: different construction strategies for the separate assembly of major polypeptide domains, the inclusion of convenient restriction sites for modifications, use of a codon selection similar to E. coli highly expressed genes, and the ability to produce repetitive sequence domains of exact numbers of defined repeats. The complete synthetic HMW-glutenin construct was 1908 bp, and contained 32 identical copies of one of the HMW-glutenin repetitive domain motifs. The gene expressed the novel HMW-glutenin protein to relatively high levels in bacterial cultures and the protein exhibited the known anomalous behavior of HMW-glutenins in SDS-PAGE.

Characterization and mapping of Rpi1, a late-blight resistance locus from diploid (1EBN) Mexican Solanum pinnatisectum.

Solanum is a diverse genus with over 200 species occupying a range of habitats from the Southwestern United States to Central Chile. Germplasm evaluations have focused on species that can be crossed with S. tuberosum, while Mexican diploid (2n = 2x = 24) Solanum species with an Endosperm Balance Number (EBN) of 1 have received less attention because of poor crossability due to their ploidy and EBN. Recent changes in Phytophthora infestans populations have increased the need for new sources of genetic resistance to this fungus. We have characterized resistance to P. infestans in the Mexican 2x(1EBN) species S. pinnatisectum. An interspecific hybrid between resistant S. pinnatisectum and susceptible S. cardiophyllum plants was backcrossed to S. cardiophyllum to generate a family segregating for late-blight resistance. The diploid (1EBN) genetic map generated with 99 RFLP markers revealed extensive synteny with previously published potato maps. A single dominant late-blight resistance locus (Rpi1) from S. pinnatisectum was mapped to chromosome 7, a region previously not associated with late-blight resistance. Characterization of the P.infestans isolate used for disease evaluations revealed that it possessed the avirulence gene corresponding to the R9 resistance locus, indicating that Rpi1 could possibly correspond to R9.