Jianqiang Miao1, Guosen Zhao1, Bin Wang2,3, Yixin Du4, Zhiwen Li5, Xuheng Gao1, Can Zhang2, Xili Liu1. 1. State Key Laboratory of Crop Stress Biology for Arid Areas, Northwest A&F University, Yangling, China. 2. Department of Plant Pathology, , China Agricultural University, Beijing, China. 3. State Key Laboratory of Discovery and Development of Novel Pesticide, Shenyang Sinochem Agrochemicals R&D Co., Ltd, Shenyang, China. 4. Institute of Plant Protection, Fujian Academy of Agricultural Science, Fuzhou, China. 5. Institute for the Control of Agrochemicals of Shaanxi Province, Xi'an, China.
Abstract
BACKGROUND: Rice blast, caused by Magnaporthe oryzae, is the most devastating disease in rice. Recently, trifloxystrobin was registered for the control of M. oryzae in China. The resistance profile and mechanism of M. oryzae to trifloxystrobin were investigated in the present study, providing important data for the recommended use of trifloxystrobin. RESULTS: The baseline sensitivity was established at a half maximal effective concentration (EC50 ) of 0.024 μg mL-1 . Nine stable trifloxystrobin-resistant mutants were generated with EC50 values ranging from 12.75 to 171.49 μg mL-1 . The mutants exhibited strong adaptive traits in sporulation, conidial germination, and pathogenicity. Positive cross-resistance was only observed between trifloxystrobin and azoxystrobin, but not between trifloxystrobin and carbendazim, isoprothiolane, prochloraz, or chlorothalonil. The point mutation G143S in cytochrome b (cyt b) protein was found in eight high-resistance mutants with resistant factor ranging from 2295.16 to 13 200.00; and the double mutation G137R/M296V only occurred in Mg117-1 with resistance factor ≈ 900. The G143S mutation weakened hydrogen bond interactions, and G137R/M296V changed the conformation of trifloxystrobin in the cyt b binding pocket. A molecular detection method was established for the rapid detection of G143S mutants in M. oryzae. CONCLUSION: The resistance risk of M. oryzae to trifloxystrobin could be moderate to high. Two genotypes with three point-mutations G143S, G137R, and M296V conferred resistance to trifloxystrobin in M. oryzae.
BACKGROUND:Rice blast, caused by Magnaporthe oryzae, is the most devastating disease in rice. Recently, trifloxystrobin was registered for the control of M. oryzae in China. The resistance profile and mechanism of M. oryzae to trifloxystrobin were investigated in the present study, providing important data for the recommended use of trifloxystrobin. RESULTS: The baseline sensitivity was established at a half maximal effective concentration (EC50 ) of 0.024 μg mL-1 . Nine stable trifloxystrobin-resistant mutants were generated with EC50 values ranging from 12.75 to 171.49 μg mL-1 . The mutants exhibited strong adaptive traits in sporulation, conidial germination, and pathogenicity. Positive cross-resistance was only observed between trifloxystrobin and azoxystrobin, but not between trifloxystrobin and carbendazim, isoprothiolane, prochloraz, or chlorothalonil. The point mutation G143S in cytochrome b (cyt b) protein was found in eight high-resistance mutants with resistant factor ranging from 2295.16 to 13 200.00; and the double mutation G137R/M296V only occurred in Mg117-1 with resistance factor ≈ 900. The G143S mutation weakened hydrogen bond interactions, and G137R/M296V changed the conformation of trifloxystrobin in the cyt b binding pocket. A molecular detection method was established for the rapid detection of G143S mutants in M. oryzae. CONCLUSION: The resistance risk of M. oryzae to trifloxystrobin could be moderate to high. Two genotypes with three point-mutations G143S, G137R, and M296V conferred resistance to trifloxystrobin in M. oryzae.