Abstract
The use of herbicide safeners can significantly alleviate herbicide injury to protect crop plants and expand the application scope of the existing herbicides in the field. Sanshools, which are well known as spices, are N-alkyl substituted compounds extracted from the Zanthoxylum species and have several essential physiological and pharmacological functions. Sanshools display excellent safener activity for the herbicide metolachlor in rice seedlings. However, the high cost of sanshools extraction and difficulties in the synthesis of their complicated chemical structures limit their utilization in agricultural fields. Thus, the present study designed and synthesized various N-alkyl amide derivatives via the scaffold-hopping strategy to solve the challenge of complicated structures and find novel potential safeners for the herbicide metolachlor. In total, 33 N-alkyl amide derivatives (2a–k, 3a–k, and 4a–k) were synthesized using amines and saturated and unsaturated fatty acids as starting materials through acylation and condensation. The identity of all the target compounds was well confirmed by 1H-NMR, 13C-NMR, and high-resolution mass spectrometry (HRMS). The primary evaluation of safener activities for the compounds by the agar method indicated that most of the target compounds could protect rice seedlings from injury caused by metolachlor. Notably, compounds 2k and 4k displayed excellent herbicide safener activities on plant height and demonstrated relatively similar activities to the commercialized compound dichlormid. Moreover, we showed that compounds 2k and 4k had higher glutathione S-transferase (GST), superoxide dismutase (SOD), catalase (CAT), peroxidase (POD), and polyphenol oxidase (PPO) activities in rice seedlings, compared to the metolachlor treatment. In particular, 2k and 4k are safer for aquatic organisms than dichlormid. Results from the current work exhibit that compounds 2k and 4k have excellent crop safener activities toward rice and can, thus, be promising candidates for further structural optimization in rice protection.
Highlights
Weeds compete with crop plants for various resources, such as nutrients, water, and sunlight, which significantly affect crop productivity
The rice plants revealed thatthat the the target compounds and and dichlormid had Thephytotoxicity phytotoxicitytesting testingresults resultsonon rice plants revealed target compounds dichlormid very low inhibitory effects on the of riceofseedlings
As dichlormid has been reported to pose potential risks to aquatic organisms, such as fish, we further evaluated the acute toxicity (96 h) of 2k, 4k, and dichlormid on zebrafish embryo; a model frequently used to evaluate the toxicity of various compounds to aquatic organisms [52,53]
Summary
Weeds compete with crop plants for various resources, such as nutrients, water, and sunlight, which significantly affect crop productivity. Weeds increase crop protection costs because they harbor pests and bacterial diseases [1,2,3]. Herbicide application has been a prominent weed-control measure in recent decades under field conditions [4,5]. Metolachlor, one of the most widely used chloroacetanilide herbicides, is applied to crops (e.g., rice, corn, and soybean) to control pre-emergent and early post-emergent broadleaf and grass weeds [6,7,8,9,10,11]. The use of herbicides as metolachlor for weed controls is phytotoxic to crop plants [12,13,14].
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