Page Banner

United States Department of Agriculture

Agricultural Research Service

Title: Genetic Engineering of Disease Resistance in Cereals

Authors
item Bushnell, William
item Somers, David - UNIVERSITY OF MINNESOTA
item Giroux, Randal - FORMER ARS EMPLOYEE
item Szabo, Les
item Zeyen, Richard - UNIVERSITY OF MINNESOTA

Submitted to: Canadian Journal of Plant Pathology
Publication Type: Review Article
Publication Acceptance Date: March 30, 1998
Publication Date: N/A

Technical Abstract: Transformation procedures have been developed for introducing cloned genes into all major cereals. These procedures are beginning to be used to enhance disease resistance, although progress is slowed by the eight to ten months required to obtain seed from the first generation of transformed plants. Genotype dependence, somaclonal variation, and lack of stability in ninheritance and expression also limit output of useful transformants. Nevertheless, several types of genes with potential to enhance disease resistance, as demonstrated in tobacco or other easily transformed plants, are available for introduction into cereals. For virus diseases, these include pathogen-derived genes for coat protein and antisense versions of replicase or other factors required for virus replication. For fungal diseases, candidates include genes for chitinase and Beta-1,3-glucanase, for several classes of low molecular weight antifungal proteins, for pathogenesis related protein-1, and for enzymes that detoxify pathogen toxins, disable hydrolytic enzymes of the pathogen, or enhance phytoalexin production. Isolation of race-specific genes for resistance from cereals and avirulence genes from cereal pathogens will offer new opportunities for engineering disease resistance using transgenes. To select among multiple candidate genes for stable transformation, a transient expression assay is described using barley epidermal cells inoculated with Blumeria (Erysiphe) graminis. For optimum efficiency and durability, gene expression in stable transformants needs to be targeted at infection sites in tissues and cells located in the invasion path of individual pathogens.

Last Modified: 7/22/2014
Footer Content Back to Top of Page