W. John Owen

Synthesis and antifungal activity of 3‐aryl‐1,2,4‐triazin‐6‐one derivatives

BACKGROUND As a result of resistance development in many plant-pathogenic fungi to agricultural fungicides, there is an ongoing need to discover novel antifungal chemistries to help sustain efficient crop production. A fungicide screening program identified 3-phenyl-1-(2,2,2-trifluoroethyl)-1,2,4-triazin-6(1H)-one (5) as a promising new starting point for further activity optimization. A series of analogs were designed, prepared and evaluated in growth inhibition assays using four plant-pathogenic fungi. RESULTS Thirty nine analogs (compounds 5 to 43) were prepared to explore structure-activity relationships at R1 and R2, and all targeted structures were characterized by (1)H NMR and MS. All compounds were in vitro tested against three ascomycetes [Leptosphaeria nodorum, Magnaporthe grisea and Zymoseptoria tritici (syn. Mycosphaerella graminicola)] and one basidiomycete (Ustilago maydis) pathogen. When R2 was trifluoroethyl, fungicidal activity was enhanced by a single electron-withdrawing substitution, such as Br, Cl and CF3 in the 3-position at R1 (compounds 9, 10 and 12), of which the 3-bromo compound (10) was the most active (EC50 = 0.08, averaged across four pathogens). More subtle activity improvement was found by addition of a second halogen substituent in the 4-position, with the 3-Br-4-F analog (20) being the most active against the commercially important cereal pathogen Z. tritici. Replacement of the R2 haloalkyl group with benzyl, alkyl (e.g. n-butyl, i-butyl, n-pentyl) and, particularly, CH2 -cycloalkyls (e.g. CH2-cyclopropyl, CH2-cyclobutyl) resulted in further activity enhancements against the ascomycete fungi, but was either neutral or detrimental to activity against U. maydis. One of the most active compounds in this series (41) gave control of Z. tritici, with an EC50 of 0.005 ppm, comparable with that of the commercial strobilurin fungicide azoxystrobin (EC50 0.002 ppm). CONCLUSIONS The present work demonstrated that the 3-phenyl-1,2,4-triazin-6-ones are a novel series of compounds with highly compelling levels of antifungal activity against agriculturally relevant plant-pathogenic fungi.

Biological characterization of fenpicoxamid, a new fungicide with utility in cereals and other crops

Abstract BACKGROUND The development of novel highly efficacious fungicides that lack cross‐resistance is extremely desirable. Fenpicoxamid (Inatreq™ active) possesses these characteristics and is a member of a novel picolinamide class of fungicides derived from the antifungal natural product UK‐2A. RESULTS Fenpicoxamid strongly inhibited in vitro growth of several ascomycete fungi, including Zymoseptoria tritici (EC50, 0.051 mg L−1). Fenpicoxamid is converted by Z. tritici to UK‐2A, a 15‐fold stronger inhibitor of Z. tritici growth (EC50, 0.0033 mg L−1). Strong fungicidal activity of fenpicoxamid against driver cereal diseases was confirmed in greenhouse tests, where activity on Z. tritici and Puccinia triticina matched that of fluxapyroxad. Due to its novel target site (Qi site of the respiratory cyt bc1 complex) for the cereals market, fenpicoxamid is not cross‐resistant to Z. tritici isolates resistant to strobilurin and/or azole fungicides. Across multiple European field trials Z. tritici was strongly controlled (mean, 82%) by 100 g as ha−1 applications of fenpicoxamid, which demonstrated excellent residual activity. CONCLUSIONS The novel chemistry and biochemical target site of fenpicoxamid as well as its lack of cross‐resistance and strong efficacy against Z. tritici and other pathogens highlight the importance of fenpicoxamid as a new tool for controlling plant pathogenic fungi.