Pleiotropic Phenotypes of the Tomato diageotropica Mutant Enable Resistance to Ralstonia solanacearum.

Quantitative disease resistance (QDR) is the most common form of disease resistance in crops, but is challenging to understand at the cellular level due to the involvement of many genes and biological processes. Ralstonia solanacearum, the causal agent of bacterial wilt disease, is a destructive plant pathogen of Solanaceous species that is best controlled by quantitatively resistant varieties, but few QDR genes are known. We previously found that a tomato auxin pathway mutant known as diageotropica (dgt) has enhanced resistance to R. solanacearum. Here we show that, like wild-type quantitatively resistant tomato plants, resistance in dgt is the result of multiple mechanisms. Mock-inoculated dgt roots have endogenously higher levels of the plant defense hormone salicylic acid (SA). However, the SA-deficient double mutant dgtNahG is still resistant to R. solanacearum, indicating that SA-independent pathways are also required for resistance. Scanning electron microscopy revealed that R. solanacearum colonization of root xylem is delayed in dgt. We found an increased number of lignified xylem cells and altered root vasculature anatomy in dgt, and dgt root length was not impacted by R. solanacearum treatment. Similar to the wilt-resistant wild-type tomato Hawaii7996, RNA-seq results suggested that dgt may tolerate R. solanacearum-induced water stress better than the wilt-susceptible parent. Thus, resistance in dgt is due to several pathways, including pre-activated SA defenses, physical barriers in the xylem, and an ability to tolerate water stress. The pleiotropic nature of this single mutation appears to mimic quantitative resistance.