Abstract
Key requirements for microbes to initiate and establish mutualistic symbiotic interactions with plants are evasion of potential host defense responses and strict control of microbial growth. We have recently shown that reactive oxygen species (ROS) produced by a specific fungal NADPH oxidase isoform NoxA, have a critical role in regulating hyphal growth in the mutualistic interaction between Epichloë festucae and perennial ryegrass. Regulation of ROS production in the symbiosis requires two additional components, NoxR and RacA, homologues of the mammalian p67phox and Rac2. Perennial ryegrass host plants containing noxA or noxR mutants lose apical dominance, become severely stunted, and undergo precocious senescence. Our working model proposes that hyphal tip growth and branching is controlled by localized bursts of ROS catalysed by NoxA, following recruitment of NoxR and RacA from the cytosol to the membrane in response to signaling from the grass host.
Figures and Tables
Figure 1 In planta phenotype of E. festucae noxR mutant. (A and B) Transmission electron micrographs of cross sections of E. festucae Fl1 wild-type (A) and noxR mutant (B) hyphae (arrowheads) in the intercellular space of perennial ryegrass. pc: plant cell. Bars = 1 µm. (C and D) Confocal depth series images of hyphal morphology of GFP expressing E. festucae wild-type (C) and noxR mutant (D) in perennial ryegrass leaf blade Bars = 10 µm.
![Figure 1 In planta phenotype of E. festucae noxR mutant. (A and B) Transmission electron micrographs of cross sections of E. festucae Fl1 wild-type (A) and noxR mutant (B) hyphae (arrowheads) in the intercellular space of perennial ryegrass. pc: plant cell. Bars = 1 µm. (C and D) Confocal depth series images of hyphal morphology of GFP expressing E. festucae wild-type (C) and noxR mutant (D) in perennial ryegrass leaf blade Bars = 10 µm.](/cms/asset/4692e49b-d3a5-420e-8223-a519e86da84b/kpsb_a_10903725_f0001.gif)
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