W. J. Owen scite author profile

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.

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Synthesis and biological activity of analogs of the antifungal antibiotic UK‐2A. I. Impact of picolinamide ring replacement

Owen¹,

Meyer²,

Slanec³

et al. 2018

Pest Management Science

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Comparison of glutathione S-transferases of Zea mays responsible for herbicide detoxification in plants and suspension-cultured cells

Edwards

Owen

1986

Planta

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The metabolism of the s-triazine herbicide atrazine has been compared in Zea mays seedlings and cell suspension cultures. The rapid detoxification observed in the shoots of whole plants was not seen in the cultured cells. This difference in metabolism could be accounted for by the varying substrate specificities of the isoenzymes of glutathione S-transferase (EC 2.5.1.18) present in the plant and the cells. A single form of the enzyme isolated from leaf tissue conjugated both atrazine and the chloracetanilide herbicide metolachlor. However, the two isoenzymes present in suspension-cultured cells although active against metolachlor, showed no activity toward atrazine. Following purification, the major form of transferase present in the cells was physically similar to the enzyme isolated from leaf (Mr=55000). Both proteins were dimers of subunit Mr=26300, and with isoelectric points in the range pH 4.3-4.9. The minor form of the enzyme present in culture showed a greater specificity for metolachlor than the major species. In addition the overall activity and ratio of the two isoenzymes varied over the culture growth cycle. These findings illustrate the need for characterizing enzymes involved in herbicide detoxification in plant cell cultures.

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

Owen¹,

Sullenberger²,

Meyer³

et al. 2014

Pest. Manag. Sci.

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Herbicide Metabolism as a Basis for Selectivity

Owen¹

1991

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The comparative metabolism of the S -triazine herbicides atrazine and terbutryne in suspension cultures of potato and wheat

Edwards

Owen

1989

Pesticide Biochemistry and Physiology

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Metabolism of metalaxyl in cell suspension cultures of Lactuca sativa L. and Vitis vinifera L

Cole

Owen

1987

Pesticide Biochemistry and Physiology

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The metabolism of chlortoluron, diuron, and CGA 43 057 in tolerant and susceptible plants

Ryan

Gross

Owen

et al. 1981

Pesticide Biochemistry and Physiology

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W. J. Owen

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

Synthesis and biological activity of analogs of the antifungal antibiotic UK‐2A. I. Impact of picolinamide ring replacement

Comparison of glutathione S-transferases of Zea mays responsible for herbicide detoxification in plants and suspension-cultured cells

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

Herbicide Metabolism as a Basis for Selectivity

The comparative metabolism of the S -triazine herbicides atrazine and terbutryne in suspension cultures of potato and wheat

Metabolism of metalaxyl in cell suspension cultures of Lactuca sativa L. and Vitis vinifera L

The metabolism of chlortoluron, diuron, and CGA 43 057 in tolerant and susceptible plants

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