Plumbagin, a Potent Naphthoquinone from Nepenthes Plants with Growth Inhibiting and Larvicidal Activities.

Some plant species are less susceptible to herbivore infestation than others. The reason for this is often unknown in detail but is very likely due to an efficient composition of secondary plant metabolites. Strikingly, carnivorous plants of the genus Nepenthes show extremely less herbivory both in the field and in green house. In order to identify the basis for the efficient defense against herbivorous insects in Nepenthes, we performed bioassays using larvae of the generalist lepidopteran herbivore, Spodoptera littoralis. Larvae fed with different tissues from Nepenthes x ventrata grew significantly less when feeding on a diet containing leaf tissue compared with pitcher-trap tissue. As dominating metabolite in Nepenthes tissues, we identified a naphthoquinone, plumbagin (5-hydroxy-2-methyl-1,4-naphthoquinone). When plumbagin was added at different concentrations to the diet of S. littoralis larvae, an EC50 value for larval growth inhibition was determined with 226.5 µg g-1 diet. To further determine the concentration causing higher larval mortality, sweet potato leaf discs were covered with increasing plumbagin concentrations in no-choice-assays; a higher mortality of the larvae was found beyond 60 µg plumbagin per leaf, corresponding to 750 µg g-1. Plant-derived insecticides have long been proposed as alternatives for pest management; plumbagin and derivatives might be such promising environmentally friendly candidates.

Bioactive tigliane diterpenoids from the latex of Euphorbia fischeriana.

Latex is a type of sticky endogenous fluids derived from diverse plants including Euphorbia fischeriana, and is of great scientific and commercial values. In the current study, it was demonstrated that the latex extracted from E. fischeriana strongly respelled the growth of cotton bollworm, Helicoverpa armigera. Using spectroscopic methods, HPLC, and GC-MS analyses, six aliphatic tigliane diterpenoids were isolated from the latex of E. fischeriana, among which three compounds (2, 3, and 5) were new. Two major compounds (1 and 4) exhibited remarkable antifeedant activity against H. armigera, with EC50 values at 2.59 and 15.32 µg/cm2, respectively. In addition, the quantification analysis of diterpenoids in different organs indicated that 4 was the most abundant constituent and was highly accumulated in the latex. Collectively, the current study highlighted that the diterpenoids in latex of E. fischeriana had a considerable antifeedant function against H. armigera, which might be employed for the future development of natural insecticides for organic farming.

In silico prediction of active site and in vitro DNase and RNase activities of Helicoverpa-inducible pathogenesis related-4 protein from Cicer arietinum.

Plants are endowed with an innate immune system, which enables them to protect themselves from pest and pathogen. The participation of pathogenesis-related (PR) proteins is one of the most crucial events of inducible plant defense response. Herein, we report the characterization of CaHaPR-4, a Helicoverpa-inducible class II PR-4 protein from chickpea. Bioinformatic analysis of CaHaPR-4 protein indicated the presence of a signal peptide, barwin domain but it lacks the chitin-binding site/hevein domain. The recombinant CaHaPR-4 is bestowed with RNase and bivalent ion-dependent DNase activity. Further, the RNA and DNA binding sites were identified and confirmed by analyzing interactions between mutated CaHaPR-4 with the altered active site and ribonuclease inhibitor, 5'ADP and DNase inhibitor, 2­nitro­5­thiocyanobenzoic acid (NTCB) using 3D modeling and docking studies. Moreover, CaHaPR-4 shows antifungal activity as well as growth inhibiting properties against neonatal podborer larvae. To the best of our knowledge, this is the first report of a PR-4 showing RNase, DNase, antifungal and most importantly insect growth inhibiting properties against Helicoverpa armigera simultaneously.