Discovery and optimization of spirocyclic lactams that inhibit acyl-ACP thioesterase.

BACKGROUND: 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. RESULTS: 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. CONCLUSION: 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.

A Study in Scaffold Hopping: Discovery and Optimization of Thiazolopyridines as Potent Herbicides That Inhibit Acyl-ACP Thioesterase.

In the search for new chemical entities that can control resistant weeds by addressing novel modes of action (MoAs), we were interested in further exploring a compound class that contained a 1,8-naphthyridine core. By leveraging scaffold hopping methodologies, we were able to discover the new thiazolopyridine compound class that act as potent herbicidal molecules. Further biochemical investigations allowed us to identify that the thiazolopyridines inhibit acyl-acyl carrier protein (ACP) thioesterase (FAT), with this being further confirmed via an X-ray cocrystal structure. Greenhouse trials revealed that the thiazolopyridines display excellent control of grass weed species in pre-emergence application coupled with dose response windows that enable partial selectivity in certain crops.

Designing New Protoporphyrinogen Oxidase-Inhibitors Carrying Potential Side Chain Isosteres to Enhance Crop Safety and Spectrum of Activity.

There are several methods to control weeds, which impose particular challenges for farmers in all parts of the world, although applying small molecular compounds still remains the most efficient technology to date. However, plants can evolve to become resistant toward active ingredients which is also the case for protoporphyrinogen oxidase (PPO) inhibitors, a class of highly effective herbicides in use for more than 50 years. Hence, it is essential to continuously discover and develop new herbicidal PPO inhibitors with enhanced intrinsic activity, an improved resistance profile, enhanced crop safety, favorable physicochemical properties, and a clean toxicological profile. By modifying structural key features from known PPO inhibitors such as tiafenacil, inspired by isostere and mix&match concepts in combination with modeling investigations based on a wild-type Amaranthus crystal structure, we have found new promising lead structures showing strong activity in vitro and in vivo against several notorious dicotyledon and monocotyledon weeds with emerging resistance (e.g., Amaranthus palmeri, Amaranthus tuberculatus, Lolium rigidum, and Alopecurus myosuroides). While several phenyl uracils carrying an isoxazoline motif in their thio-linked side chain showed promising resistance-breaking potential against different Amaranthus species, introducing a thioacrylamide side chain afforded outstanding efficacy against resistant grass weeds.

Design, synthesis and screening of herbicidal activity for new phenyl pyrazole-based protoporphyrinogen oxidase-inhibitors (PPO) overcoming resistance issues.

BACKGROUND: Whilst there are several methods to control weeds, which continuously plague farmers around the globe, the application of small molecular compounds is still the most effective technology to date. Plants can evolve to become resistant to PPO-inhibitors, a class of herbicides in commercial use since the 1960s. It is therefore essential to continuously develop new herbicides based on this mode-of-action with enhanced intrinsic activity, an improved resistance profile and favourable physicochemical properties. Based on an Amaranthus PPO crystal structure and subsequent modelling studies, halogen-substituted pyrazoles have been investigated as isosteres of uracil-based PPO-inhibitors. RESULTS: By combining structural features from the commercial PPO-inhibitors tiafenacil and pyraflufen-ethyl and by investigating receptor-binding properties, we identified new promising pyrazole-based lead structures showing strong activity in vitro and in vivo against economically important weeds of the Amaranthus genus: A. retroflexus, and resistant A. palmeri and A. tuberculatus. CONCLUSION: The present work covers a series of novel PPO-inhibiting compounds that contain a pyrazole ring and a substituted thioacetic acid sidechain attached to the core phenyl group. These compounds show good receptor fit in line with excellent herbicidal activity against weeds that plague corn and rice crops with low application rates. This, in combination with promising selectivity in corn, have the potential to mitigate and affect weeds that have become resistant to some of the current market standards. Remarkably, some of the novel PPO-inhibitors outlined herein show efficacies against economically important weeds that were superior to recently commercialized and structurally related tiafenacil. © 2023 Society of Chemical Industry.

Synthesis of fluorescently labeled mono- and diprenylated Rab7 GTPase.

Modification of proteins with isoprenoid lipids is a widespread phenomenon in eukaryotic organisms that has received much attention due to its involvement in the progression of several diseases including cancer. Progress in studies of prenylated proteins has been hampered by difficulties associated with isolation of these proteins from native or recombinant sources. Small GTPases of the Rab family represent a particularly difficult example since they are doubly C-terminally geranylgeranylated and in some cases methylated. Here, we report an efficient and versatile strategy for the synthesis of mono- and digeranylgeranylated fluorescent RabGTPases using a combination of chemical synthesis and expressed protein ligation. Using this approach we generated fluorescent mono- and diprenylated Rab7 proteins that display near-native properties and form stoichiometric complexes with their natural chaperone REP-1. We demonstrate that the complex formed from semisynthetic monoprenylated Rab7 and REP-1 represents a genuine intermediate of the Rab prenylation reaction and thus provides a unique tool for studies of the Rab prenylation mechanism. Semisynthetic Rab7 proteins were used to develop a novel fluorescence-based in vitro prenylation assay. Using this assay we dissected the mechanism of the Rab7 double-geranylgeranylation reaction mediated by Rab geranylgeranyl transferase. We conclude that the reaction follows a random sequential mechanism. These results highlight the usefulness of the semisynthetic reaction intermediates in the study of protein posttranslational modification.

Synthesis of lipidated peptides.

This chapter describes general methodologies for the synthesis of lipidated, that is, prenylated and/or palmitoylated peptides. Standard operating procedures are given for peptide synthesis both on the polymeric support and in solution.

Intein-mediated synthesis of geranylgeranylated Rab7 protein in vitro.

Production of recombinant proteins is an important prerequisite for biotechnology and life sciences in general. However, there is a paucity of methods for production of posttranslationally modified recombinant proteins or proteins with non-native functional groups, such as fluorophores, spin labels, and so forth. In this work we have used a combination of organic synthesis and in vitro protein ligation to construct monoprenylated Rab7 GTPase. The protein was prepared from a recombinant N-terminal portion and a peptide mimicking the C terminus of Rab7. For construction of a synthetic six-amino-acid-long fluorescent monoprenylated peptide, we used a block condensation strategy. Ligation was achieved with a yield of >70%. The resulting protein was purified from the unligated peptide by a combination of organic extraction and phase partitioning and refolding. The refolded monoprenylated semisynthetic Rab7 protein (Rab7GG) formed a stable complex with its natural chaperone REP-1 (Rab escort protein 1) and could serve as an acceptor of the second prenyl group in the enzymatic prenylation reaction. Using fluorescence spectroscopy, we characterized the interaction of the Rab7GG:REP-1 complex with Rab geranylgeranyl transferase and came to the conclusion that it functioned as a genuine intermediate of the prenylation reaction. Thus, we present the first example of the in vitro generation of a semisynthetic lipidated protein using the native chemical ligation method.