Project description:Background: Herbicides are environmental contaminants that have gained much attention due to the potential hazards they pose to human health. Glyphosate, the active ingredient in many commercial herbicides, is the most heavily applied herbicide worldwide. The recent rise in glyphosate application to corn and soy crops correlates positively with increased death rates due to Alzheimer's disease and other neurodegenerative disorders. Glyphosate has been shown to cross the blood-brain barrier in in vitro models, but has yet to be verified in vivo. Additionally, reports have shown that glyphosate exposure increases pro-inflammatory cytokines in blood plasma, particularly TNFα. Methods: Here, we examined whether glyphosate infiltrates the brain and elevates TNFα levels in 4-month-old C57BL/6J mice. Mice received either 125, 250, or 500 mg/kg/day of glyphosate, or a vehicle via oral gavage for 14 days. Urine, plasma, and brain samples were collected on the final day of dosing for analysis via UPLC-MS and ELISAs. Primary cortical neurons were derived from amyloidogenic APP/PS1 pups to evaluate in vitro changes in Aβ40-42 burden and cytotoxicity. RNA sequencing was performed on C57BL/6J brain samples to determine changes in the transcriptome. Results: Our analysis revealed that glyphosate infiltrated the brain in a dose-dependent manner and upregulated TNFα in both plasma and brain tissue post-exposure. Notably, glyphosate measures correlated positively with TNFα levels. Glyphosate exposure in APP/PS1 primary cortical neurons increases levels of soluble Aβ40-42 and cytotoxicity. RNAseq revealed over 200 differentially expressed genes in a dose-dependent manner and cell-type-specific deconvolution analysis showed enrichment of key biological processes in oligodendrocytes including myelination, axon ensheathment, glial cell development, and oligodendrocyte development. Conclusions: Collectively, these results show for the first time that glyphosate infiltrates the brain, elevates both the expression of TNFα and soluble Aβ, and disrupts the transcriptome in a dose-dependent manner, suggesting that exposure to this herbicide may have detrimental outcomes regarding the health of the general population.

Project description:Glyphosate is one of the most widely used herbicides globally. It acts by inhibiting an enzyme in an aromatic amino synthesis pathway specific to plants and microbes, leading to view that glyphosate poses no risk to other organisms. However, there is growing concern that glyphosate is associated with detrimental health effects in humans, and an ever-increasing body of evidence suggests that glyphosate affects other animals including pollinating insects such as bees. Although pesticides have long been considered a contributing factor in the decline of wild bee populations most research on bees has focussed on demonstrating and understanding the effects (particularly sublethal ones) of insecticides. To assess whether glyphosate poses a potential risk to bees we characterised the changes in survival, behaviour, digestive tract proteome and microbiome in the bumblebee Bombus terrestris after chronic exposure to field relevant doses of glyphosate alone and as part of the commercially available product RoundUp Optima+®. Regardless of source, changes in response to herbicide exposure in important cellular and physiological processes in the digestive tract of B. terrestris were observed, with the abundances of proteins associated with oxidative stress regulation, metabolism, cellular adhesion, the extracellular matrix, and various signalling pathways being altered. Interestingly, endocytosis, oxidative phosphorylation, the TCA cycle, and carbohydrate, lipid, and amino acid metabolism were differentially altered depending on whether the exposure source was glyphosate AI or RoundUp Optima+®. In addition, RoundUp Optima+®, but not the active ingredient glyphosate, impacted fungal diversity in the digestive tract microbiota. Our research provides new insights into the potential mode of action and consequences of glyphosate exposure at the molecular and cellular levels in bumblebees and highlights issues with current regulatory measures involving commercial formulations of pesticides where the impact of the co-formulants on non-target organisms are generally overlooked.

Project description:Transcription profiling by array of Arabidopsis treated with glyphosate herbicide

Project description:Background: The auxin herbicides 2,4-D and dicamba are commonly used for management of horseweed (Erigeron canadensis L, (syn: Conyza canadensis L)). Halauxifen-methyl is a new auxin herbicide and recently commercialized to control several broadleaf weed species under a range of sites and environmental conditions. While synthetic auxin herbicides have been used for over 70 years, the precise mode of action that leads to plant death has yet to be clearly characterized. As new chemical families are discovered and the use of these herbicides continues to increase, it is imperative to understand how synthetic auxin active ingredients work within the plant to cause an herbicidal effect. Results: At 1 hour after treatment (HAT), 48 genes were consistently upregulated across the three herbicides, many of which are involved in the auxin-activated signaling pathway and response to auxin. At 6 HAT, 735 genes were upregulated by all herbicide treatments including genes associated with hormone signaling, metabolism, transport, senescence, and gene expression. The GO terms representing the 501 genes downregulated in all herbicide treatments were broadly categorized under two major groups: ATP and photosynthesis. At 6 HAT, over 50% of the genes differential expressed among the three herbicide treatments were unique to a single active ingredient. Conclusion: This research presents a first look into the differential gene expression profiles in horseweed following a foliar application of synthetic auxin compounds that represent three unique chemical families. While there are an abundance of transcriptome similarities induced by each herbicide that accounts for the general auxin herbicide response, distinct gene expression changes exclusive to each compound cannot be ignored as a contributor to the mode of action.

Project description:Despite all debates about its safe use, glyphosate still is the most widely applied active ingredient in herbicide products with renewed approval in the European Union until 2033. Non-target organisms are commonly exposed to glyphosate as a matter of its mode of application, with its broader environmental and biological impacts remaining under investigation. Glyphosate displays structural similarity to phosphoenolpyruvate (PEP), thereby competitively inhibiting the 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS), crucial for the synthesis of aromatic amino acids in plants, fungi, bacteria, and archaea. The majority of microbes, including the gut bacterium Escherichia coli (E. coli), possess a glyphosate-sensitive class I EPSPS, making them vulnerable to glyphosate's effects. Yet, little is known about glyphosate’s interactions with other bacterial proteins or its broader modes of action at the proteome level. Here, we employed a quantitative proteomics and thermal proteome profiling (TPP) approach, to identify novel protein binding partners of glyphosate in the E. coli proteome. Glyphosate exposure significantly altered amino acid synthesizing pathways, including increased abundance in shikimate pathway proteins, suggesting a compensatory mechanism. Extracellular riboflavin concentrations were elevated upon glyphosate exposure, while intracellular levels remained stable. Thermal proteome profiling indicated an effect of glyphosate on the thermal stability of certain proteins beyond the target enzyme EPSPS, including AroH and ProA. An elevated structural similarity between the substrates of the interaction candidates and glyphosate, similar to the competitive binding between PEP and glyphosate at the EPSPS, could be a reason for their interaction with the herbicide. Overall, glyphosate induced metabolic disturbances in E. coli, extending beyond its primary target, thereby providing new insights into glyphosate's broader impact on microbial systems.

Project description:The number and type of synthetic chemicals that are being produced worldwide continues to increase significantly. While these industrial chemicals provide numerous benefits, there is no doubt that some have potential to damage the environment and health. Toxicity must be evaluated and use must be carefully controlled and monitored in order to minimize potential damage. DNA microarray technology has become an important new technique in toxicology. We are using the yeast Saccharomyces cerevisiae as a model organism for toxicological study because it is a simple, fast-growing eukaryote that has been thoroughly characterized. In order to evaluate toxicity by newly synthesized or mixture chemicals, toxicity-induced gene expression alteration profiles by known chemicals should be collected. In our study, cells need to be exposed with same experimental cellular condition, semi lethal (IC50), respectively. In the case of round up (CAS; 40465-66-5), the exposure dose was decided as 1500 times dilution by growth curve with continuously diluted exposure. Roundup is the brand name of a systemic, broad-spectrum herbicide contains the active ingredient glyphosate. Glyphosate is classed as a moderately toxic herbicide and in EPA toxicity class III. // Genomic profile of roundup treatment of yeast using DNA microarray analysis: The herbicide Roundup, which contains glyphosate as the active ingredient, was first introduced in 1974 and has enjoyed widespread use in Japan and elsewhere in the world. Roundup-induced reactions occurring in the yeast Saccharomyces cerevisiae may have a predictive value for understanding responses in higher eukaryotes, and we applied yeast DNA microarray analysis for this purpose. Functional characterization of up-regulated open reading frames (ORFs) following Roundup treatment suggests that Roundup affects membrane structures and cellular organelles. Expression profiles induced by treatments with detergents, oils and hydrostatic pressure were similar to those following Roundup treatment based on cluster analysis. Glyphosate alone was not found to inhibit yeast growth at the concentration contained in the Roundup treatment used for microarray analysis. The toxicity of Roundup appeared to be due to detergent in the product. Keywords: stress response

Project description:Resistance to herbicides in weeds can be due to alteration(s) in the gene encoding the herbicide target site, or to herbicide degradation via a deviation in plant general metabolism. If target-site-based resistance is easy to study, the multigenic control of metabolism-based resistance renders it much more complex to study. Metabolism-based resistance to herbicides represents the major part of herbicide resistance in black-grass. Its most likely basis is an overexpression of genes encoding enzymes degrading herbicides. We thus seek to identify such overexpressed genes by comparing the transcriptomes of resistant and sensitive black-grass individuals belonging to an F2 line segregating for two resistance genes. Given there are no genomic tools developed for black-grass, this approach will use heterologous hybridisation onto a wheat Affymetrix microarray. Comparison using heterologous hybridisation onto a wheat whole-genome microarray of transcriptome of three pools of black-grass plants obtained 2h30 after herbicide spraying at field rate. The three pools correspond to: · Sensitive plants (killed by herbicide). · Moderately resistant plants (growth impaired by herbicide but plants still alive) · Resistant plants (growth unimpaired by herbicide) 6 arrays - wheat

Project description:Resistance to herbicides in weeds can be due to alteration(s) in the gene encoding the herbicide target site, or to herbicide degradation via a deviation in plant general metabolism. If target-site-based resistance is easy to study, the multigenic control of metabolism-based resistance renders it much more complex to study. Metabolism-based resistance to herbicides represents the major part of herbicide resistance in black-grass. Its most likely basis is an overexpression of genes encoding enzymes degrading herbicides. We thus seek to identify such overexpressed genes by comparing the transcriptomes of resistant and sensitive black-grass individuals belonging to an F2 line segregating for two resistance genes. Given there are no genomic tools developed for black-grass, this approach will use heterologous hybridisation onto a wheat Affymetrix microarray. Comparison using heterologous hybridisation onto a wheat whole-genome microarray of transcriptome of three pools of black-grass plants obtained 2h30 after herbicide spraying at field rate. The three pools correspond to: · Sensitive plants (killed by herbicide). · Moderately resistant plants (growth impaired by herbicide but plants still alive) · Resistant plants (growth unimpaired by herbicide)

Project description:This experiment was annotated by TAIR (http://www.arabidopsis.org). In this experiment we examined whole genome response to herbicidal levels of 2,4-D application. Arabidopsis plants (14 days) grown in vitro on MS medium in petri dishes were flooded with 1 mL stock of 2,4-D to enable root uptake. Plants were treated with 1.0 mM 2,4-D for a period of 1 hour immediately after which RNA was extracted and used for the microarray based experiments. the goal of this study was to explore the herbicidal mode of action of auxinic herbicide 2,4-D. Experimenter name = Chitra Raghavan Experimenter department = Trevor Stevenson Laboratory Experimenter institute = IRRI Experimenter address = Entomology and Plant Pathology Division IRRI Experimenter zip/postal_code = Manila 4031 Experimenter country = Philippines Keywords: compound_treatment_design

Project description:Transcriptomic implications of low herbicide concentrations in hepatic cells: Insights into the individual and combined effects of 2,4-D, glyphosate, and AMPA