The biological activities of prothioconazole enantiomers and their toxicity assessment on aquatic organisms.

Chiral fungicide prothioconazole has a wide range of antifungal spectrum; however, little research has been conducted to evaluate prothioconazole on an enantiomeric level. Five target pathogens and three common aquatic organisms were tested for the enantioselective bioactivity and toxicity of prothioconazole in this work. The antifungal activity of the enantiomers against wheat phytoalexin, rice blast fungus, exserohilum turcicum, Alternaria triticina, and Fusarium avenaceum was determined, and it was found that (-)-prothioconazole were 85 to 2768 times more active than (+)-prothioconazole toward these target organisms. In order to reflect the risk to aquatic ecosystem, the acute toxicity of the enantiomers to Daphnia magna, Chlorella pyrenoidosa, and Lemna minor L. was assessed. It was observed that the toxicity of (-)-prothioconazole to D. magna was 2.2 times higher than (+)-prothioconazole, but it was lower to C. pyrenoidosa and L. minor L. The toxicities of (+)-enantiomer and (-)-enantiomer to D. magna and C. pyrenoidosa were synergy, indicating that the racemate had higher threat to the organisms. It could be concluded that the effects of prothioconazole on target organisms and the acute toxicity to nontarget species were enantioselective with (-)-enantiomer possessing higher efficiency and lower toxicity. Such enantiomeric differences should be taken into consideration when assessing the performance of prothioconazole.

[1]  D. Carrão,et al.  Metabolism studies of chiral pesticides: A critical review. , 2018, Journal of pharmaceutical and biomedical analysis.

[2]  Ya Zhang,et al.  Effects and inhibition mechanism of phenazine-1-carboxamide on the mycelial morphology and ultrastructure of Rhizoctonia solani. , 2017, Pesticide biochemistry and physiology.

[3]  Miaomiao Teng,et al.  Enantioselective bioaccumulation of hexaconazole and its toxic effects in adult zebrafish (Danio rerio). , 2015, Chemosphere.

[4]  Á. Mesterházy,et al.  Distribution of prothioconazole and tebuconazole between wheat ears and flag leaves following fungicide spraying with different nozzle types at flowering. , 2015, Pest management science.

[5]  Á. Mesterházy,et al.  Translocation and degradation of tebuconazole and prothioconazole in wheat following fungicide treatment at flowering. , 2013, Pest management science.

[6]  Xingang Liu,et al.  Chiral triazole fungicide difenoconazole: absolute stereochemistry, stereoselective bioactivity, aquatic toxicity, and environmental behavior in vegetables and soil. , 2013, Environmental science & technology.

[7]  C. Deweer,et al.  Protective and curative efficacy of prothioconazole against isolates of Mycosphaerella graminicola differing in their in vitro sensitivity to DMI fungicides. , 2011, Pest management science.

[8]  H. Kaneko Pyrethroids: mammalian metabolism and toxicity. , 2011, Journal of agricultural and food chemistry.

[9]  J. Gan,et al.  Stereoisomeric separation and toxicity of the nematicide fosthiazate , 2007, Environmental toxicology and chemistry.

[10]  Huayun Yang,et al.  Stereoisomeric separation and toxicity of a new organophosphorus insecticide chloramidophos. , 2007, Chemical research in toxicology.

[11]  Charles S Wong,et al.  Environmental fate processes and biochemical transformations of chiral emerging organic pollutants , 2006, Analytical and bioanalytical chemistry.

[12]  Daniel Schlenk,et al.  Enantioselectivity in environmental safety of current chiral insecticides. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[13]  P. Hedden,et al.  COMPARATIVE ACTIVITY OF THE ENANTIOMERS OF TRIADIMENOL AND PACLOBUTRAZOL AS INHIBITORS OF FUNGAL GROWTH AND PLANT STEROL AND GIBBERELLIN BIOSYNTHESIS , 1987 .

[14]  Ll Marking Method for assessing additive toxicity of chemical mixtures , 1977 .

[15]  F. Wilcoxon,et al.  A simplified method of evaluating dose-effect experiments. , 1948, The Journal of pharmacology and experimental therapeutics.

[16]  D. R. Hoagland OPTIMUM NUTRIENT SOLUTIONS FOR PLANTS. , 1920, Science.