Project description:Gut and rest of body tissue from fifth instar larvae which fed for three days a diet containing different doses of gossypol. Transcriptional profiling comparing gut and rest of body samples for three gossypol concentrations (0%, 0.016%-hormetic dose & 0.16%-detrimental dose). Hormesis is a biphasic biological response characterized by the stimulatory effect at relatively low amounts of chemical compounds otherwise known to be detrimental at higher concentrations. A hormetic response in larval growth rates has been observed in cotton-feeding insects in response to increasing concentrations of gossypol, a toxic metabolite found in the pigment glands of some Malvaceae plants. We investigated the developmental effect of gossypol in the cotton bollworm, Helicoverpa armigera, an important heliothine pest species, by exposing larvae to different doses of this metabolite in their diet. In addition, we sought to determine the underlying transcriptional responses to different gossypol doses. Larval weight gain, pupal weight and larval development time were measured in feeding experiments and a hormetic response was seen for the first two characters. On the basis of net larval weight gain responses to gossypol, three treatments, that is 0%, 0.016% and 0.16% gossypol , were selected for transcript profiling in the gut and the rest of the body in a two-color double reference design microarray experiment. Two-color double reference design. Reference sample was the 0% (CT) gossypol condition (either Gut or Rest of Body) or one of two experimental conditions {0.016(T5) and 0.16%(T7)}. Biological replicates: 4 (10 individuals per replicate). 32 samples total.

Project description:The transcriptional response of H. armigera larvae was analyzed after feeding on gossypol supplemented diet, a toxic secondary metabolite produced in cotton plants, to detect potential detoxification enzymes possibly involved in detoxification of gossypol by H. armigera. A one-color microarray-based gene expression analysis was performed with Cy3 labeled cRNA of gut and rest of the body of H. armigera larvae that fed on 0.016%, 0.16% gossypol and control diet. For each treatment and tissue four biological replicates were used.

Project description:The transcriptional response of H. virescens larvae was analyzed after feeding on gossypol supplemented diet, a toxic secondary metabolite produced in cotton plants, to detect potential detoxification enzymes possibly involved in detoxification of gossypol by H. virescens. A one-color microarray-based gene expression analysis was performed with Cy3 labeled cRNA of gut and rest of the body of H. virescens larvae that fed on 0.32% gossypol and control diet. For each treatment and tissue four biological replicates were used.

Project description:Hormesis is a dose response phenomenon characterized by a stimulation of an organismal response at low doses of a chemical and inhibition of the response (toxicity) at a higher dose. In the present study, Daphnia magna were exposed to the energetic compound 2,4,6-trinitrotoluene (TNT) for 21 days, and the endpoints survival, growth (length and dry weight), and reproduction (number of neonates per survivor) were assesed, identifying hormetic responses at the lower treatment levels. In order to elucidate the mechanisms leading to hormesis, microarray analysis was performed at 0.004 (hormetic), 0.12 (sometimes hormetic), and 1.85 (toxic) mg/L TNT. Functional and transcriptional benchmark dose analyses performed on differentially expressed genes suggested the involvement of lipid metabolism in hormetic responses and subsequently lipidomic analysis was performed on the same treatments. Lipid analysis supported the hypothesis that TNT exposure affected lipid metabolism, and showed that hormetic effects could be related to increases in some polyunsaturated fatty acids and ecosanoids known to be involved in Daphnia growth and reproduction.

Project description:Helicoverpa armigera gene expression on gossypol suppelemented diet, larval gut and rest of body

Project description:Heliothis virescens gene expression on gossypol suppelemented diet, larval gut and rest of body

Project description:The resistance mechanisms evolved by insects to overcome host-plant allelochemicals is a key consideration in pest management. Camphor oil (EO) and its main component (i.e D-camphor) form a specific terpenoid-defensive system in camphor trees, Cinnamomum camphora. However, an emerging insect pest, Pagiophloeus tsushimanus has recently caused serious damage to this intractable plant species, which is largely elusive. Here, we used feeding bioassays and RNA-seq to investigate the mechanism underlying the resistance of the beetle to host-specific terpenoid defenses. Firstly, a hormetic response in both larval weight and developmental time was observed in terpenoid-feeding individuals, which is a highly generalized dose-response phenomenon in toxicology whereas occurs infrequently in the context of insect-plant interactions. Then, comparative transcriptome analysis between terpenoid-feeding and control groups indicated that both CYP450s-mediated metabolic resistance and CPs-mediated cuticular resistance were jointly employed to cope with terpenoid-induced stress. In addition, a small portion of genes involved in glucose transport pathway were up-regulated at the low D-camphor dose, suggesting an extra intake of glucose used for larval growth may contribute to a hormetic response. These findings probably implied that the dual terpenoid-resistance mechanisms existing in this specialist is an essential precondition for hormetic response in larval growth, ultimately contributing to successfully colonize host camphor trees with impunity. Overall, our study will open new avenues for understanding the insect-plant coevolutionary adaptation and developing durable pest control strategies.

Project description:Hormesis is a dose response phenomenon characterized by a stimulation of an organismal response at low doses of a chemical and inhibition of the response (toxicity) at a higher dose. In the present study, Daphnia magna were exposed to the energetic compound 2,4,6-trinitrotoluene (TNT) for 21 days, and the endpoints survival, growth (length and dry weight), and reproduction (number of neonates per survivor) were assesed, identifying hormetic responses at the lower treatment levels. In order to elucidate the mechanisms leading to hormesis, microarray analysis was performed at 0.004 (hormetic), 0.12 (sometimes hormetic), and 1.85 (toxic) mg/L TNT. Functional and transcriptional benchmark dose analyses performed on differentially expressed genes suggested the involvement of lipid metabolism in hormetic responses and subsequently lipidomic analysis was performed on the same treatments. Lipid analysis supported the hypothesis that TNT exposure affected lipid metabolism, and showed that hormetic effects could be related to increases in some polyunsaturated fatty acids and ecosanoids known to be involved in Daphnia growth and reproduction. Chronic toxicity tests was designed to identify the hormetic range of D. magna responses to TNT. Daphnia magna younger than 24 h old and obtained from in-house cultures at the U.S. Army Engineer Research and Development Center, Environmental Laboratory (Vicksburg, MS) were used to initiate the bioassay. The experimental design consisted of one D. magna per test chamber and 10 test chambers per treatment level. In the microarray mass exposure, nominal treatment levels were 0.004, 0.02, 0.12, 0.44, and 1.85 mg/L. Based on the results of the testing in the 50 ml beakers, organisms from three treatments were selected for analysis of gene expression: 0.004, 0.12, and 1.85 mg/L. These treatments were selected to represent a hormetic concentration (0.004 mg/L), a toxic concentration (1.85 mg/L), and an intermediate concentration (0.12 mg/L). A total of 23 arrays used, with 5-6 replicates per each dose (solvent control, 0.004 mg/L, 0.12 mg/L, and 1.85 mg/L).

Project description:We investigated the hormetic effects of prenatal hyperbaric normoxia exposure on Drosophila healthspan related to molecular defense mechanisms. HN exposure had no disruptive effect on developmental rate or adult body weight. However, lifespan was clearly enhanced, as was resistance to oxidative and heat stress. In addition, levels of reactive oxygen species were significantly decreased and motor performance was increased. Furthermore, to determine the hormetic mechanism underlying these phenotypic and molecular changes, we performed a genome-wide profiling in HN-exposed and control flies. Genes encoding chitin metabolism were highly up-regulated in both sex, which could possibly serve to scavenge free radicals. These results identify prenatal HN exposure as a potential hormetic factor that may improve longevity and healthspan by enhancing defense mechanisms in Drosophila.

Project description:Transcriptional responses underlying the hormetic and detrimental effects of gossypol on Helicoverpa armigera