Project description:Juvenile rainbow trout were exposed to two different concentrations of 17β-estradiol (E2) (2 or 20 mg/kg feed), and then infected with three concentrations of Yersinia ruckeri, a bacterial pathogen causing massive losses in wild and farmed salmonid populations. Infection with Y. ruckeri caused mortality of trout, and this effect was significantly enhanced by simultaneous exposure to high E2 dose. Analysis of hepatic gene expression profiles revealed complex regulations of pathways involved in immune responses, stress responses and detoxicification pathways. E2 markedly reduced expression of several genes implicated in xenobiotic metabolism. The results suggest that the interaction between pathogen and E2 interfered with the fish’s capability of clearing toxic compounds. The findings of the current study add to our understanding of multiple exposure responses in fish.

Project description:In agroecosystems, a plant-usable form of nitrogen is mainly generated by legume-based biological nitrogen fixation, a process that requires phosphorus (P) as an essential nutrient. To investigate the physiological mechanism whereby phosphorus influences soybean nodule nitrogen fixation, soybean root nodules were exposed to four phosphate levels: 1 mg/L (P stress), 11 mg/L (P stress), 31 mg/L (Normal P), 61 mg/L (High P) then proteome analysis of nodules was conducted to identify phosphorus-associated proteome changes. We found that phosphorus stress-induced ribosomal protein structural changes were associated with altered key root nodule protein synthesis profiles. Importantly, up-regulated expression of peroxidase was observed as an important phosphorus stress-induced nitrogen fixation-associated adaptation that supported two nodule-associated activities: scavenging of reactive oxygen species (ROS) and cell wall growth. In addition, phosphorus transporter (PT) and purple acid phosphatase (PAPs) were up-regulated that regulated phosphorus transport and utilisation to maintain phosphorus balance and nitrogen fixation function in phosphorus-stressed root nodules.

Project description:Abstract — Insensitive munitions (IMs) improve soldier safety by decreasing sympathetic detonation during training and use in theatre. The environmental effects of IM constituents such as nitroguanidine (NQ) and IM mixture formulations such as IMX-101 remain largely unknown. In the present study, we investigated the acute (96h) toxicity of NQ and IMX-101 to zebrafish larvae, both in the parent IMs and in IMs irradiated with environmentally-relevant levels of ultraviolet (UV) energy. Zebrafish were exposed to control and ten concentrations of NQ ranging from 1 to 732 mg/L (measured concentrations) or seven concentrations of IMX-101 ranging from 2 to 122 mg/L (measured concentrations) of the parent material or material that had been UV-irradiated (UV-treated) at the equivalent of 24 hours of sunlight. The UV-treatment increased the toxicity of NQ by 17-fold, indicated by a decreased LC50 from 1323 mg/L (parent compound) to 77.2 mg/L. Similarly, UV-treatment increased the toxicity of IMX-101 by nearly two fold (LC50 decreased from 131.3 to 67.6 mg/L). Molecular responses to parent and UV-treated IMs were assessed using global transcript expression assays. Both gene set enrichment analysis (GSEA) and differential transcript expression analysis coupled with pathway and annotation cluster enrichment were conducted to provide functional interpretations of expression results and hypothetical modes of toxicity. The parent NQ exposure caused significant enrichment of functions related to immune responses and proteasome-mediated protein metabolism occurring primarily at low, sublethal exposure levels (5.5 and 45.6 mg/L). Enriched functions in the IMX-101 exposure were indicative of increased xenobiotic metabolism, oxidative stress mitigation, protein degradation, and anti-inflammatory responses, each of which displayed predominantly positive concentration-response relationships. UV-treated NQ had a fundamentally different transcriptomic expression profile relative to parent NQ where positive concentration-response relationships were observed for genes involved in oxidative-stress mitigation pathways whereby we hypothesize that the increased toxicity of UV-treated NQ resulted from increased oxidative stress. This hypothesis was supported by transcriptomic responses indicative of oxidative-stress responses involved in zebrafish development, especially neurological development of visual systems and the brain. Transcriptomic profiles were similar between UV-treated versus parent IMX-101 exposures, however, more significant and diverse enrichment as well as greater magnitudes of differential expression for oxidative stress responses were observed in UV-treated IMX-101 exposures. Further, transcriptomics indicated potential for cytokine signaling suppression providing potential connections between oxidative stress and anti-inflammatory responses. Given these result, we hypothesize that the increased toxicity of UV-irradiated NQ and the IMX-101 mixture result from breakdown products with increased potential to elicit oxidative stress.

Project description:Abstract — Insensitive munitions (IMs) improve soldier safety by decreasing sympathetic detonation during training and use in theatre. The environmental effects of IM constituents such as nitroguanidine (NQ) and IM mixture formulations such as IMX-101 remain largely unknown. In the present study, we investigated the acute (96h) toxicity of NQ and IMX-101 to zebrafish larvae, both in the parent IMs and in IMs irradiated with environmentally-relevant levels of ultraviolet (UV) energy. Zebrafish were exposed to control and ten concentrations of NQ ranging from 1 to 732 mg/L (measured concentrations) or seven concentrations of IMX-101 ranging from 2 to 122 mg/L (measured concentrations) of the parent material or material that had been UV-irradiated (UV-treated) at the equivalent of 24 hours of sunlight. The UV-treatment increased the toxicity of NQ by 17-fold, indicated by a decreased LC50 from 1323 mg/L (parent compound) to 77.2 mg/L. Similarly, UV-treatment increased the toxicity of IMX-101 by nearly two fold (LC50 decreased from 131.3 to 67.6 mg/L). Molecular responses to parent and UV-treated IMs were assessed using global transcript expression assays. Both gene set enrichment analysis (GSEA) and differential transcript expression analysis coupled with pathway and annotation cluster enrichment were conducted to provide functional interpretations of expression results and hypothetical modes of toxicity. The parent NQ exposure caused significant enrichment of functions related to immune responses and proteasome-mediated protein metabolism occurring primarily at low, sublethal exposure levels (5.5 and 45.6 mg/L). Enriched functions in the IMX-101 exposure were indicative of increased xenobiotic metabolism, oxidative stress mitigation, protein degradation, and anti-inflammatory responses, each of which displayed predominantly positive concentration-response relationships. UV-treated NQ had a fundamentally different transcriptomic expression profile relative to parent NQ where positive concentration-response relationships were observed for genes involved in oxidative-stress mitigation pathways whereby we hypothesize that the increased toxicity of UV-treated NQ resulted from increased oxidative stress. This hypothesis was supported by transcriptomic responses indicative of oxidative-stress responses involved in zebrafish development, especially neurological development of visual systems and the brain. Transcriptomic profiles were similar between UV-treated versus parent IMX-101 exposures, however, more significant and diverse enrichment as well as greater magnitudes of differential expression for oxidative stress responses were observed in UV-treated IMX-101 exposures. Further, transcriptomics indicated potential for cytokine signaling suppression providing potential connections between oxidative stress and anti-inflammatory responses. Given these result, we hypothesize that the increased toxicity of UV-irradiated NQ and the IMX-101 mixture result from breakdown products with increased potential to elicit oxidative stress.

Project description:Abstract — Insensitive munitions (IMs) improve soldier safety by decreasing sympathetic detonation during training and use in theatre. The environmental effects of IM constituents such as nitroguanidine (NQ) and IM mixture formulations such as IMX-101 remain largely unknown. In the present study, we investigated the acute (96h) toxicity of NQ and IMX-101 to zebrafish larvae, both in the parent IMs and in IMs irradiated with environmentally-relevant levels of ultraviolet (UV) energy. Zebrafish were exposed to control and ten concentrations of NQ ranging from 1 to 732 mg/L (measured concentrations) or seven concentrations of IMX-101 ranging from 2 to 122 mg/L (measured concentrations) of the parent material or material that had been UV-irradiated (UV-treated) at the equivalent of 24 hours of sunlight. The UV-treatment increased the toxicity of NQ by 17-fold, indicated by a decreased LC50 from 1323 mg/L (parent compound) to 77.2 mg/L. Similarly, UV-treatment increased the toxicity of IMX-101 by nearly two fold (LC50 decreased from 131.3 to 67.6 mg/L). Molecular responses to parent and UV-treated IMs were assessed using global transcript expression assays. Both gene set enrichment analysis (GSEA) and differential transcript expression analysis coupled with pathway and annotation cluster enrichment were conducted to provide functional interpretations of expression results and hypothetical modes of toxicity. The parent NQ exposure caused significant enrichment of functions related to immune responses and proteasome-mediated protein metabolism occurring primarily at low, sublethal exposure levels (5.5 and 45.6 mg/L). Enriched functions in the IMX-101 exposure were indicative of increased xenobiotic metabolism, oxidative stress mitigation, protein degradation, and anti-inflammatory responses, each of which displayed predominantly positive concentration-response relationships. UV-treated NQ had a fundamentally different transcriptomic expression profile relative to parent NQ where positive concentration-response relationships were observed for genes involved in oxidative-stress mitigation pathways whereby we hypothesize that the increased toxicity of UV-treated NQ resulted from increased oxidative stress. This hypothesis was supported by transcriptomic responses indicative of oxidative-stress responses involved in zebrafish development, especially neurological development of visual systems and the brain. Transcriptomic profiles were similar between UV-treated versus parent IMX-101 exposures, however, more significant and diverse enrichment as well as greater magnitudes of differential expression for oxidative stress responses were observed in UV-treated IMX-101 exposures. Further, transcriptomics indicated potential for cytokine signaling suppression providing potential connections between oxidative stress and anti-inflammatory responses. Given these result, we hypothesize that the increased toxicity of UV-irradiated NQ and the IMX-101 mixture result from breakdown products with increased potential to elicit oxidative stress.

Project description:Abstract — Insensitive munitions (IMs) improve soldier safety by decreasing sympathetic detonation during training and use in theatre. The environmental effects of IM constituents such as nitroguanidine (NQ) and IM mixture formulations such as IMX-101 remain largely unknown. In the present study, we investigated the acute (96h) toxicity of NQ and IMX-101 to zebrafish larvae, both in the parent IMs and in IMs irradiated with environmentally-relevant levels of ultraviolet (UV) energy. Zebrafish were exposed to control and ten concentrations of NQ ranging from 1 to 732 mg/L (measured concentrations) or seven concentrations of IMX-101 ranging from 2 to 122 mg/L (measured concentrations) of the parent material or material that had been UV-irradiated (UV-treated) at the equivalent of 24 hours of sunlight. The UV-treatment increased the toxicity of NQ by 17-fold, indicated by a decreased LC50 from 1323 mg/L (parent compound) to 77.2 mg/L. Similarly, UV-treatment increased the toxicity of IMX-101 by nearly two fold (LC50 decreased from 131.3 to 67.6 mg/L). Molecular responses to parent and UV-treated IMs were assessed using global transcript expression assays. Both gene set enrichment analysis (GSEA) and differential transcript expression analysis coupled with pathway and annotation cluster enrichment were conducted to provide functional interpretations of expression results and hypothetical modes of toxicity. The parent NQ exposure caused significant enrichment of functions related to immune responses and proteasome-mediated protein metabolism occurring primarily at low, sublethal exposure levels (5.5 and 45.6 mg/L). Enriched functions in the IMX-101 exposure were indicative of increased xenobiotic metabolism, oxidative stress mitigation, protein degradation, and anti-inflammatory responses, each of which displayed predominantly positive concentration-response relationships. UV-treated NQ had a fundamentally different transcriptomic expression profile relative to parent NQ where positive concentration-response relationships were observed for genes involved in oxidative-stress mitigation pathways whereby we hypothesize that the increased toxicity of UV-treated NQ resulted from increased oxidative stress. This hypothesis was supported by transcriptomic responses indicative of oxidative-stress responses involved in zebrafish development, especially neurological development of visual systems and the brain. Transcriptomic profiles were similar between UV-treated versus parent IMX-101 exposures, however, more significant and diverse enrichment as well as greater magnitudes of differential expression for oxidative stress responses were observed in UV-treated IMX-101 exposures. Further, transcriptomics indicated potential for cytokine signaling suppression providing potential connections between oxidative stress and anti-inflammatory responses. Given these result, we hypothesize that the increased toxicity of UV-irradiated NQ and the IMX-101 mixture result from breakdown products with increased potential to elicit oxidative stress.

Project description:Abstract — Insensitive munitions (IMs) improve soldier safety by decreasing sympathetic detonation during training and use in theatre. The environmental effects of IM constituents such as nitroguanidine (NQ) and IM mixture formulations such as IMX-101 remain largely unknown. In the present study, we investigated the acute (96h) toxicity of NQ and IMX-101 to zebrafish larvae, both in the parent IMs and in IMs irradiated with environmentally-relevant levels of ultraviolet (UV) energy. Zebrafish were exposed to control and ten concentrations of NQ ranging from 1 to 732 mg/L (measured concentrations) or seven concentrations of IMX-101 ranging from 2 to 122 mg/L (measured concentrations) of the parent material or material that had been UV-irradiated (UV-treated) at the equivalent of 24 hours of sunlight. The UV-treatment increased the toxicity of NQ by 17-fold, indicated by a decreased LC50 from 1323 mg/L (parent compound) to 77.2 mg/L. Similarly, UV-treatment increased the toxicity of IMX-101 by nearly two fold (LC50 decreased from 131.3 to 67.6 mg/L). Molecular responses to parent and UV-treated IMs were assessed using global transcript expression assays. Both gene set enrichment analysis (GSEA) and differential transcript expression analysis coupled with pathway and annotation cluster enrichment were conducted to provide functional interpretations of expression results and hypothetical modes of toxicity. The parent NQ exposure caused significant enrichment of functions related to immune responses and proteasome-mediated protein metabolism occurring primarily at low, sublethal exposure levels (5.5 and 45.6 mg/L). Enriched functions in the IMX-101 exposure were indicative of increased xenobiotic metabolism, oxidative stress mitigation, protein degradation, and anti-inflammatory responses, each of which displayed predominantly positive concentration-response relationships. UV-treated NQ had a fundamentally different transcriptomic expression profile relative to parent NQ where positive concentration-response relationships were observed for genes involved in oxidative-stress mitigation pathways whereby we hypothesize that the increased toxicity of UV-treated NQ resulted from increased oxidative stress. This hypothesis was supported by transcriptomic responses indicative of oxidative-stress responses involved in zebrafish development, especially neurological development of visual systems and the brain. Transcriptomic profiles were similar between UV-treated versus parent IMX-101 exposures, however, more significant and diverse enrichment as well as greater magnitudes of differential expression for oxidative stress responses were observed in UV-treated IMX-101 exposures. Further, transcriptomics indicated potential for cytokine signaling suppression providing potential connections between oxidative stress and anti-inflammatory responses. Given these result, we hypothesize that the increased toxicity of UV-irradiated NQ and the IMX-101 mixture result from breakdown products with increased potential to elicit oxidative stress.

Project description:Abstract — Insensitive munitions (IMs) improve soldier safety by decreasing sympathetic detonation during training and use in theatre. The environmental effects of IM constituents such as nitroguanidine (NQ) and IM mixture formulations such as IMX-101 remain largely unknown. In the present study, we investigated the acute (96h) toxicity of NQ and IMX-101 to zebrafish larvae, both in the parent IMs and in IMs irradiated with environmentally-relevant levels of ultraviolet (UV) energy. Zebrafish were exposed to control and ten concentrations of NQ ranging from 1 to 732 mg/L (measured concentrations) or seven concentrations of IMX-101 ranging from 2 to 122 mg/L (measured concentrations) of the parent material or material that had been UV-irradiated (UV-treated) at the equivalent of 24 hours of sunlight. The UV-treatment increased the toxicity of NQ by 17-fold, indicated by a decreased LC50 from 1323 mg/L (parent compound) to 77.2 mg/L. Similarly, UV-treatment increased the toxicity of IMX-101 by nearly two fold (LC50 decreased from 131.3 to 67.6 mg/L). Molecular responses to parent and UV-treated IMs were assessed using global transcript expression assays. Both gene set enrichment analysis (GSEA) and differential transcript expression analysis coupled with pathway and annotation cluster enrichment were conducted to provide functional interpretations of expression results and hypothetical modes of toxicity. The parent NQ exposure caused significant enrichment of functions related to immune responses and proteasome-mediated protein metabolism occurring primarily at low, sublethal exposure levels (5.5 and 45.6 mg/L). Enriched functions in the IMX-101 exposure were indicative of increased xenobiotic metabolism, oxidative stress mitigation, protein degradation, and anti-inflammatory responses, each of which displayed predominantly positive concentration-response relationships. UV-treated NQ had a fundamentally different transcriptomic expression profile relative to parent NQ where positive concentration-response relationships were observed for genes involved in oxidative-stress mitigation pathways whereby we hypothesize that the increased toxicity of UV-treated NQ resulted from increased oxidative stress. This hypothesis was supported by transcriptomic responses indicative of oxidative-stress responses involved in zebrafish development, especially neurological development of visual systems and the brain. Transcriptomic profiles were similar between UV-treated versus parent IMX-101 exposures, however, more significant and diverse enrichment as well as greater magnitudes of differential expression for oxidative stress responses were observed in UV-treated IMX-101 exposures. Further, transcriptomics indicated potential for cytokine signaling suppression providing potential connections between oxidative stress and anti-inflammatory responses. Given these result, we hypothesize that the increased toxicity of UV-irradiated NQ and the IMX-101 mixture result from breakdown products with increased potential to elicit oxidative stress.

Project description:Basal leaf removal has been widely practiced to increase cluster sunlight exposure, control berry rot and eventually improve grape berry quality. Early leaf removal performed in cool region appeared to benefit the accumulation of norisoprenoids and monoterpenes. However, effects of this canopy management and leaf moving on volatile profiles and transcriptome of grape berry in warm region characterized with strong sunshine and arid climate were paid less attention. To cope with multiple possible effects caused by global warming, researches in warm region are urgently needed to provide a guide for adjusting the sunlight exposure treatment to adapt the climate change.In Manas county of Xinjiang province, sunlight exposure treatments performed in this study resulted in decreased β-carotene and lutein, which mainly responsible for the reduced norisoprenoids in ripening grapes. Substrate competition due to the up-regulation of VvTPS-a and VvNCED3 may contribute to the decreased concentration of monoterpenes in exposed berries. The notable increased C6 alcohols in the grape berries treated by leaf removal applied at veraison (LR-V), was mainly attribute to the enhanced substrate availability of linoleic acid and linolenic acid together with the higher expression of VvLOXO and VvADH1. Free C6 aldehyde was reduced by half leaf removal applied at veraison (HLR-V), leaf moving at veraison (LM-V) and leaf removal applied at berry pepper-corn size (LR-PS). Moreover, transcriptomic analysis indicated that both LR-V and LM-V treated grape berry implemented multiple stress-mitigation strategies to acclimate the improved sunlight exposure. Interestingly, photosynthesis-related genes in grape berry were primarily up-regulated by LR-V as a consequence of carbohydrate source removal rather than improved sunlight exposure. Weighted gene co-expression network analysis (WGCNA) suggested that the genes encoding malate synthase and 3-oxoacyl-(acyl carrier protein) reductase show a significant correlation with the accumulation of C6 alcohol.

Project description:Nitrogen removal