Natural products are an abundant and environmentally friendly source for controlling plant pathogens and insect pests. Toward the development of new natural product-based pesticides, here, a series of osthole-based isoxazoline derivatives were prepared by [3 + 2] annulation and evaluated for their insecticidal activities and toxicities. The structures of all osthole-based isoxazoline derivatives were characterized by various spectral analyses, and derivative B13 was further confirmed by X-ray crystallography. Among all the osthole derivatives, B2 displayed the most promising growth inhibitory effect on Mythimna separata with a final corrected mortality rate of 96.4% ± 3.3, which was 1.80 times higher than those of both osthole and toosendanin. Derivative B13 displayed the most promising larvicidal activity against Plutella xylostella with an LC 50 value of 0.220 mg/mL, which was superior to rotenone. Furthermore, both B13 and B21 also exhibited better control efficacy against P. xylostella than rotenone in the pot experiments. Additionally, the toxicity evaluation suggested that these osthole-based isoxazoline derivatives showed relatively low toxicity toward nontarget organisms. Given these results, osthole derivatives B2, B13, and B21 could be deeply developed as natural insecticidal agents in agriculture.
Infections caused by multidrug-resistant (MDR) bacteria
are increasing
worldwide, and with limited clinically available antibiotics, it is
urgent to develop new antimicrobials to combat these MDR bacteria.
Here, a class of novel amphiphilic xanthohumol derivatives were prepared
using a building-block approach. Bioactivity assays showed that the
molecule IV15 not only exhibited a remarkable antibacterial
effect against clinical methicillin-resistant Staphylococcus
aureus (MRSA) isolates (MICs: 1–2 μg/mL)
but also had the advantages of rapid bactericidal properties, low
toxicity, good plasma stability, and not readily inducing bacterial
resistance. Mechanistic studies indicated that IV15 has
good membrane-targeting ability and can bind to phosphatidylglycerol
and cardiolipin in bacterial membranes, thus disrupting the bacterial
cell membranes and causing increased intracellular reactive oxygen
species and leakage of proteins and DNA, eventually resulting in bacterial
death. Notably, IV15 exhibited remarkable in
vivo anti-MRSA efficacy, superior to vancomycin, making it
a potential candidate to combat MRSA infections.
To discover novel natural-product-based insecticide candidates, herein, a variety of osthole-derived Nbenzoylthioureas were synthesized and assessed for their insecticidal activities against three insect pests. An insecticidal assay showed that most of the target osthole-derived N-benzoylthioureas displayed a more potent and broad-spectrum insecticidal effect than the parent osthole after the introduction of N-benzoylthioureas on the C-3′ position of osthole. Compound B24 displayed the most potent growth inhibitory (GI) effect on Mythimna separata Walker, with a final corrected mortality rate of 82.1% when treated with a concentration of 1 mg/mL, which was 1.64-and 1.53-fold higher in comparison to osthole and the botanical insecticide toosendanin, respectively. Compounds B22, B23, and B25 displayed a more promising aphicidal effect on Myzus persicae Sulzer, and their LD 50 values were 0.015, 0.017, and 0.019 μg/larvae, respectively, superior to the commercially available insecticide rotenone (0.024 μg/larvae). Derivatives B19, B20, B23, and B25 displayed more potent larvicidal activity against Plutella xylostella Linnaeus, with LC 50 values of 0.22, 0.26, 0.15, and 0.30 mg/mL, respectively, exceeding that of rotenone (0.37 mg/mL). Furthermore, both compounds B19 and B23 against P. xylostella were found to be more effective than rotenone in a control efficacy assay under greenhouse conditions. The structure−activity relationship (SAR) suggested that osthole-derived N-benzoylthioureas are more active in most cases when the R group is an electron-withdrawing group than when it is an electron-donating group, especially for halogenated groups. Additionally, the potent compounds B19 and B23 possessed good selectivity and were less toxic to non-target organisms. This study suggests that these osthole-derived N-benzoylthioureas could be further studied in depth as eco-friendly natural product pesticides in crop protection.
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