The isolated essential oils from seven air-dried plant species were analyzed by gas chromatography-mass spectrometry (GC-MS). Thymus vulgaris (thyme), Origanum vulgare (oregano), and Origanumdictamus (dictamus) essential oils were found to be rich in phenolic compounds representing 65.8, 71.1, and 78.0% of the total oil, respectively. Origanum majorana (marjoram) oil was constituted of hydrocarbons (42.1%), alcohols (24.3%), and phenols (14.2%). The essential oil from Lavandula angustifolia Mill. (lavender) was characterized by the presence of alcohols (58.8%) and esters (32.7%). Ethers predominated in Rosmarinus officinalis (rosemary) and Salvia fruticosa (sage) essential oils, constituting 88.9 and 78.0%, respectively. The radial growth, conidial germination, and production of Penicillium digitatum were inhibited completely by oregano, thyme, dictamus, and marjoram essential oils at relatively low concentrations (250-400 microg/mL). Lavender, rosemary, and sage essential oils presented less inhibitory effect on the radial growth and conidial germination of P. digitatum. Conidial production of P. digitatum was not affected by the above oils at concentrations up to 1000 microg/mL. Apart from oregano oil, all essential oils were more effective in the inhibition of conidial germination than of radial growth. The monoterpene components, which participate in essential oils in different compositions, seem to have more than an additive effect in fungal inhibition.
: 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 0É1 kg ml~1), whereas in the resistant mutant, oxygen uptake was stimulated (50% stimulation at 1É0 kg 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 complex, bc 1 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.
Mutants of Botrytis cinerea with moderate and high resistance to pyraclostrobin, a Qo inhibitor of mitochondrial electron transport at the cytochrome bc 1 complex, were isolated at a high mutation frequency, after nitrosoguanidine mutagenesis and selection on medium containing pyraclostrobin and salicylhydroxamate (SHAM), a specific inhibitor of cyanide-resistant (alternative) respiration. Oxygen uptake in whole cells was strongly inhibited in the wild-type strain by pyraclostrobin and SHAM, but not in the mutant isolates. Cross-resistance studies with other Qo and Qi inhibitors (QoIs and QiIs) of cytochrome bc 1 complex of mitochondrial respiration showed that the mutation(s) for resistance to pyraclostrobin also reduced the sensitivity of mutant strains to other QoIs as azoxystrobin, fluoxastrobin, trifloxystrobin and picoxystrobin, but not to famoxadone and to the QiIs cyazofamid and antimycin-A. An increased sensitivity of pyraclostrobin-resistant strains to the carboxamide boscalid, an inhibitor of complex II, and to the anilinopyrimidine cyprodinil, a methionine biosynthesis inhibitor, was observed. Moreover, no effect of pyraclostrobin resistance mutation(s) on fungitoxicity of the hydroxyanilide fenhexamid, the phenylpyrrole fludioxonil, the benzimidazole benomyl, and to the phenylpyridinamine fluazinam, which affect other cellular pathways, was observed. Study of fitness parameters in the wild-type and pyraclostrobin-resistant mutants of B. cinerea showed that most mutants had a significant reduction in the sporulation, conidial germination and sclerotia production. Experiments on the stability of the pyraclostrobin-resistant phenotype showed a reduction of resistance, mainly in moderate resistant strains, when the mutants were grown on inhibitor-free medium. However, a rapid recovery of the resistance level was observed after the mutants were returned to a selective medium. Studies on the competitive ability of mutant isolates against the wild-type parent strain, by applications of a mixed conidial population, showed that, in vitro, all mutants were less competitive than the wild-type strain. However, the competitive ability of high resistant mutants was higher than the moderate ones. Pathogenicity tests on cucumber seedlings showed that all mutant strains tested exhibited an infection ability similar with the wild-type parent strain. Preventive applications of the commercial product of F-500 25EC (pyraclostrobin) were effective against lesion development on cotyledons by the wild-type, but ineffective, even at high concentrations, against disease caused by the pyraclostrobin-resistant isolates. Boscalid (F-510 50WG) was found equally effective against the disease caused by the wild-type or pyraclostrobin-resistant mutants. This is the first report indicating the appearance of B. cinerea strains resistant to QoI fungicides by the biochemical mechanism of site modification and the risk for field resistance.
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