Asmus Elisabeth, Barber David M, Bojack Guido, Bollenbach-Wahl Birgit, Brown Ronald W, Döller Uwe, Freigang Jörg, Gatzweiler Elmar, Getachew Rahel, Heinemann Ines, Hohmann Sabine, Ko Kwang-Yoon, Laber Bernd, Lange Gudrun, Mattison Rebecca L, Minn Klemens, Müller Thomas, Petry Thomas, Reingruber Anna M, Schmutzler Dirk, Svejda Andrea, Frackenpohl Jens
Research & Development, Weed Control, Division Crop Science, Bayer AG, Industriepark Höchst, Frankfurt, Germany.
Pest Manag Sci. 2025 May;81(5):2598-2616. doi: 10.1002/ps.8015. Epub 2024 Feb 26.
There are various methods to control weeds, that represent considerable challenges for farmers around the globe, although applying small molecular compounds is still the most effective and versatile technology to date. In the search for novel chemical entities with new modes-of-action that can control weeds displaying resistance, we have investigated two spirocyclic classes of acyl-ACP thioesterase inhibitors based on X-ray co-crystal structures and subsequent modelling studies.
By exploiting scaffold-hopping and isostere concepts, we were able to identify new spirolactam-based lead structures showing promising activity in vivo against commercially important grass weeds in line with strong target affinity.
The present work covers a series of novel herbicidal lead structures that contain a spirocyclic lactam as a structural key feature carrying ortho-substituted benzyl or heteroarylmethylene side chains. These new compounds show good acyl-ACP thioesterase inhibition in line with strong herbicidal activity. Glasshouse trials showed that the spirolactams outlined herein display promising control of grass-weed species in pre-emergence application combined with dose-response windows that enable partial selectivity in wheat and corn. Remarkably, some of the novel acyl-ACP thioesterase-inhibitors showed efficacy against resistant grass weeds such as Alopecurus myosuroides and Lolium spp. on competitive levels compared with commercial standards. © 2024 Society of Chemical Industry.
控制杂草有多种方法,这对全球农民来说是巨大挑战,尽管应用小分子化合物仍是迄今为止最有效且用途广泛的技术。在寻找具有新作用模式、能控制抗性杂草的新型化学实体的过程中,我们基于X射线共晶体结构及后续建模研究,对两类螺环类酰基 - ACP硫酯酶抑制剂进行了研究。
通过利用骨架跃迁和电子等排体概念,我们能够鉴定出基于螺内酰胺的新先导结构,这些结构在体内对具有商业重要性的禾本科杂草显示出有前景的活性,且具有很强的靶标亲和力。
目前的工作涵盖了一系列新型除草先导结构,其含有螺环内酰胺作为结构关键特征,并带有邻位取代的苄基或杂芳基亚甲基侧链。这些新化合物显示出良好的酰基 - ACP硫酯酶抑制作用以及很强的除草活性。温室试验表明,本文所述的螺内酰胺在芽前施用时对禾本科杂草种类显示出有前景的防除效果,同时具有剂量 - 反应窗口,能够在小麦和玉米中实现部分选择性。值得注意的是,一些新型酰基 - ACP硫酯酶抑制剂在与商业标准相比的竞争水平上,对诸如黑麦草和看麦娘等抗性禾本科杂草显示出药效。© 2024化学工业协会。
