Plant resistance to rusts and mildews: genetic control and possible mechanisms.

Genes in plants that confer race-specific resistance to rusts and mildews are widely exploited in agriculture and can prevent huge losses at little cost. However, nothing is known of the molecular basis of their action. Genetic studies, together with observations of responses at the ultrastructural level, can provide broad insights into how resistance is achieved, which may help in cloning resistance genes.

Deletion mutation as a means of isolating avirulence genes in flax rust.

The interaction between flax rust,Melampsora lini, and its host, flax,Linum usitatissimum, has been extensively studied, and certain genetic features make the system an appropriate choice to utilize in isolating genes conferring avirulence in rust. A mutant that was selected for virulence on Lx plants was isolated, after treatment with gamma rays, from a strain that is genotypicallyA-L5,A-L6,A-L7,A-Lx/A-L5,A-L6,a-L7,a-Lx. These four specificities are tightly linked. Breeding tests showed that this mutant was genotypicallyA-L5,A-L6,a-L7,a-Lx/a-L5,a-L6,a-L7,a-Lx and, when made homozygous for the mutant chromosome, was virulent onL5,L6,L7, andLx. This result excludes somatic recombination as a source of the mutation and indicates deletion as a likely cause. A 250 bp genomic sequence from a strain of rust homozygous for these four linked avirulence genes (A-L5,A-L6,A-L7,A-Lx) was isolated, using a method that allows the differential cloning of the specific DNA sequences located within a deletion in the mutant genome. This clone hybridized to two EcoRI bands in genomic DNA from the strain homozygous for the four linked avirulence genes and from the strain homozygousA-L5 andA-L6 and heterozygousA-L7 andA-Lx, but showed no homology to DNA from the strain carrying the putative chromosomal deletion. The correlation between the genetically characterized deletion mutation and the isolation of a sequence from within a region of chromosome missing from this strain of rust suggests that this 250 bp tract may be part of, or closely linked to, the defined set of avirulence genes.

Recombination among genes at the L group in flax conferring resistance to rust.

Fourteen of the known genes conferring resistance to rust in flax occur in the L group, and recombinational analysis has been used to study their fine structure. Three important features were observed. (a) Similar to the findings of Shepherd and Mayo, only susceptible recombinants were detected among the testcross progeny of 11 of the 15 heterozygotes involving pairs of L genes. Some of these recombinants showed variation in the degree of their susceptibility and appeared to be unstable in nature. (b) A new class of recombinants exhibiting a modified type of resistance was recovered. They occurred rarely but consistently, with frequencies similar to that of susceptible recombinants. (c) Rare resistant plants occurred among the progeny of susceptible recombinants. In each case, the specificity of the resistant plant corresponded to only one of the parental types. The relative roles of seed contamination, mutation, recombination and the transposition of genetic elements are discussed to account for these features.

Genes conferring specific plant disease resistance.

Genes conferring host resistance to an obligate parasite, grouped together in complex loci provide opportunities to study their structure. By means of an appropriate operational definition of these genes, a modified cis-trans test was used to interpret the position effects of codominant genes mutually recombined within each of two complex loci of flax, with the use of a specially developed method of analysis among F(2) segregants. The different behavior of genes in the M and L groups may reflect a difference in their structure sufficient to raise important implications in the theory of specific host-parasite interactions.