Alternative respiration : a biochemical mechanism of resistance to azoxystrobin (ICIA 5504) in Septoria tritici

The mechanism of resistance to ICIA 5504 (azoxystrobin) in a Septoria tritici mutant raised in the laboratory has been investigated. This mutant was approximately 10 times less sensitive than the wild-type strain in in-vitro tests towards spore germination or fungal growth. Glucose oxidation in whole cells was inhibited in the wild type (80% inhibition at 0.1 μg ml -1 ), whereas in the resistant mutant, oxygen uptake was stimulated (50% stimulation at 1.0 μg ml -1 ). Respiration of the wild-type strain was inhibited by antimycin A and cyanide but not that of the mutant. These results indicate the existence of an efficient alternative respiratory pathway in the mutant, which was inhibited by the addition of 2 mM salicylhydroxamate (SHAM). Using mitochondria, antimycin A and ICIA 5504 did not completely inhibit NADH oxidation in either strain. Addition of SHAM inhibited part of the antimycin- and ICIA 5504-insensitive oxygen uptake only in mutant mitochondria. For complete inhibition of oxygen reduction, SHAM and cyanide need to be present. Thus, three systems of electron transfer from exogenous NADH to oxygen are present in S. tritici mitochondria: the cytochrome pathway which is sensitive to ICIA 5504 and antimycin A inhibition in both strains, the system of NADH-cytochrome c reductase which bypasses the methoxyacrylate inhibition at the cytochrome bc 1 complex, and the alternative oxidase which is inhibited by SHAM, and which is partially functioning only in mitochondria isolated from the ICIA 5504-resistant mutant. When the S. tritici isolates were tested for their in-vivo sensitivity to ICIA 5504 on wheat, the resistant strain was controlled better than the wild type. This indicates that the decreased ATP formation by the alternative pathway of respiration was inadequate for efficient parasitic growth on the host.