BACKGROUNDThe 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.RESULTSFenpicoxamid 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.CONCLUSIONSThe 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. © 2017 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.
The 3-hydroxy-4-methoxy picolinic acid moiety of UK-2A can be replaced by a variety of o-hydroxy-substituted arylcarboxylic acids that retain strong activity against Z. tritici and other agriculturally relevant fungi. © 2018 Society of Chemical Industry.
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.
BACKGROUND Following the introduction of fenpicoxamid, a natural product‐based fungicide targeting the Qi site of mitochondrial cytochrome bc1 complex, a second generation fully synthetic picolinamide, florylpicoxamid, was discovered and its biological activity and attributes were characterized. RESULTS In vitro fungal growth inhibition assays and in planta glasshouse biological activity evaluations showed florylpicoxamid was active against 21 different plant pathogenic fungi within the phyla Ascomycota and Basidiomycota. Among the pathogens evaluated, florylpicoxamid was most potent against Zymoseptoria tritici, the causal organism of wheat leaf blotch, providing 80% growth inhibition in vitro at 0.0046 mg L−1 and 80% disease control in planta at 0.03 mg L−1 when applied as a preventative treatment. Florylpicoxamid was more efficacious than epoxiconazole, fluxapyroxad, and benzovindiflupyr versus a Z. tritici wild‐type isolate when applied as curative and preventative treatments, with superior 10‐day curative reachback activity. Analytical studies and in planta tests demonstrated that florylpicoxamid partitioned into plants quickly and showed good systemicity and translaminar activity on both monocot and dicot plants. No cross‐resistance was observed between florylpicoxamid and strobilurin or azole fungicides. Florylpicoxamid exerts its preventative effect by preventing spore germination on the leaf surface and curative activity by arresting mycelial growth and pycnidia development in leaf tissue. CONCLUSIONS With strong broad spectrum fungicidal activity, florylpicoxamid delivers an innovative solution for growers to sustain high productivity and quality of many crops, and also provides a new option for developing effective strategies for fungicide resistance management. © 2021 Society of Chemical Industry.
BACKGROUND: UK-2A is an antifungal antibiotic produced by Streptomyces sp. 517-02. Derivatization of its picolinamide OH to form the isobutyryl acetal led to the discovery of fenpicoxamid (InatreqTM active), which is currently under development as a fungicide by Dow AgroSciences LLC. This paper documents efforts to achieve additional efficacy enhancements through semi-synthetic modification of the benzyl substituent of the UK-2A macrocycle.RESULTS: Of 34 analogs prepared, the most active had mitochondrial electron transport IC 50 values 1.5-to 3.7-fold higher than UK-2A (IC 50 0.86 nM). The cyclohexyl analog (38, IC 50 1.23 nM) was the most intrinsically active derivative, and inhibited in vitro growth of Zymoseptoria tritici (EC 50 2.8 ppb) and Leptosphaeria nodorum (EC 50 6.2 ppb) more strongly than UK-2A (EC 50 5.3 and 11.3 ppb for Z. tritici and L. nodorum, respectively). Heterocyclic ring systems and polar linker functionalities resulted in substantial activity loss . Several analogs (20, 22, 23, 24, 36 and 38) translated Z. tritici in vitro growth inhibition activity to in planta disease control more effectively than did UK-2A, with log D being a key factor in this regard. CONCLUSIONS: UK-2A is amenable to further modification at the benzyl position on the macrocycle, which provides opportunities for manipulation of physical properties while retaining strong intrinsic and antifungal activity.
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