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Breakdown of Host Resistance by Independent Evolutionary Lineages of Beet necrotic yellow vein virus Involves a Parallel C/U Mutation in Its p25 Gene

Acosta-Leal, Rodolfo, Bryan, Becky K., Smith, Jessica T., Rush, Charles M.
Phytopathology 2010 v.100 no.2 pp. 127-133
Beta vulgaris, sugar beet, Beet necrotic yellow vein virus, plant diseases and disorders, disease resistance, genetic resistance, host plants, microbial genetics, strain differences, phylogeny, mutation, disease incidence, signs and symptoms (plants), correlation, geographical variation, genetic distance, Wisconsin, California
Breakdown of sugar beet Rz1-mediated resistance against Beet necrotic yellow vein virus (BNYVV) infection was previously found, by reverse genetics, to be caused by a single mutation in its p25 gene. The possibility of alternative breaking mutations, however, has not been discarded. To explore the natural diversity of BNYVV in the field and its effects on overcoming Rz1, wild-type (WT) and resistance-breaking (RB) p25 genes from diverse production regions of North America were characterized. The relative titer of WT p25 was inversely correlated with disease expression in Rz1 plants from Minnesota and California. In Minnesota, the predominant WT p25 encoded the A67C68 amino acid signature whereas, in California, it encoded A67L68. In both locations, these WT signatures were associated with asymptomatic BNYVV infections of Rz1 cultivars. Further analyses of symptomatic resistant plants revealed that, in Minnesota, WT A67C68 was replaced by V67C68 whereas, in California, WT A67L68 was replaced by V67L68. Therefore, V67 was apparently critical in overcoming Rz1 in both pathosystems. The greater genetic distances between isolates from different geographic regions rather than between WT and RB from the same location indicate that the underlying C to U transition originated independently in both BNYVV lineages.