Abstract
Celangulin V (CV) is the main insecticidal constituent of Celastrus angulatus. The V-ATPase H subunit of the midgut cells of lepidopteran larvae is the putative target protein of CV. Here, we compared the effects of CV on the midgut membrane potentials of Mythimna separata and Agrotis ipsilon larvae with those of the Cry1Ab toxin from Bacillus thuringiensis and with those of inactive CV-MIA, a synthetic derivative of CV. We investigated the changes in the apical membrane potentials (Vam) and basolateral membrane potentials (Vbm) of the midguts of sixth-instar larvae force-fed with the test toxins. We also measured the Vam and Vbm of larval midguts that were directly incubated with the test toxins. Similar to the effect of Cry1Ab, the Vam of CV-treated midguts rapidly decayed over time in a dose-dependent manner. By contrast, CV-MIA did not influence Vam. Meanwhile, the Vam of A. ipsilon larval midguts directly incubated with CV decayed less than that of M. separata larval midguts, whereas that of larvae force-fed with CV did not significantly change. Similar to Cry1Ab, CV did not affect the Vbm of isolated midguts. CV significantly inhibited V-ATPase activity in a dose-dependent manner. Therefore, CV initially inhibits V-ATPase in the apical membrane and affects intracellular pH, homeostasis, and nutrient transport mechanisms in lepidopteran midgut cells.
Highlights
Insecticides are key control agents of insect pests that threaten agricultural production and spread diseases [1]
The above results demonstrated that Celangulin V (CV) depolarizes the apical membranes of the midgut cells of M. separata and A. ipsilon larvae in a concentration- and time-dependent manner
Enzymology studies indicated that CV significantly inhibits V-ATPase activity in the midguts of M. separata larvae
Summary
Insecticides are key control agents of insect pests that threaten agricultural production and spread diseases [1]. Given that an increasing number of insecticides have been subjected to regulatory restrictions or banned [2], biologically based alternatives to chemical insecticides have been extensively explored [3]. The use of plant-derived secondary metabolites as insecticides has been investigated because of their superior effectiveness, safety, and ecological acceptability [4]. Active insecticide components such as pyrethrin, nicotine, and rotenone have been successfully isolated from numerous plants and widely utilized in pest management [5,6,7,8,9]. With significant advancements in natural product science, such compounds have been used or characterized as primary compounds in Toxins 2017, 9, 393; doi:10.3390/toxins9120393 www.mdpi.com/journal/toxins
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