Project description:Deoxynivalenol (DON) is a fungal toxin mainly produced by Fusarium graminearum and Fusarium graminearum, and is present in cereal crops such as wheat, barley, oats, rye, and corn. It is widely polluted worldwide. DON and its related derivatives have a wide range of toxic effects on humans and animals. This study used zebrafish models and different cell models to verify the toxic effects of DON, and explored the mechanism of DON mediated Jurkat apoptosis and inhibition of M2 macrophage differentiation. The results indicate that the toxic effects of these fungal toxins differ significantly among various cell types. For Jurkat T cells, the IC50 values of DON, NIV, 15 Ac DON, and 3-Ac DON were 488.6 nM, 318.2 nM, 544 nM, and 6516 nM, respectively. There are significant differences in the effects on M2 polarization of macrophages, and DON, NIV, and 15 Ac DON can inhibit M2 differentiation and function of macrophages at lower dose levels. Indicating that immune toxicity is an important toxic effect of DON and its related substances. Research on its mechanism has shown that DON can target protein processing processes, interfere with the normal synthesis and folding of proteins in cells, and trigger cellular stress responses. These findings reveal the toxic effects and potential mechanisms of DON on human immune cells, providing a scientific basis for preventing and controlling DON pollution and its harm to human health.

Project description:Deoxynivalenol (DON) is a fungal toxin mainly produced by Fusarium graminearum and Fusarium graminearum, and is present in cereal crops such as wheat, barley, oats, rye, and corn. It is widely polluted worldwide. DON and its related derivatives have a wide range of toxic effects on humans and animals. This study used zebrafish models and different cell models to verify the toxic effects of DON, and explored the mechanism of DON mediated Jurkat apoptosis and inhibition of M2 macrophage differentiation. The results indicate that the toxic effects of these fungal toxins differ significantly among various cell types. For Jurkat T cells, the IC50 values of DON, NIV, 15 Ac DON, and 3-Ac DON were 488.6 nM, 318.2 nM, 544 nM, and 6516 nM, respectively. There are significant differences in the effects on M2 polarization of macrophages, and DON, NIV, and 15 Ac DON can inhibit M2 differentiation and function of macrophages at lower dose levels. Indicating that immune toxicity is an important toxic effect of DON and its related substances. Research on its mechanism has shown that DON can target protein processing processes, interfere with the normal synthesis and folding of proteins in cells, and trigger cellular stress responses. These findings reveal the toxic effects and potential mechanisms of DON on human immune cells, providing a scientific basis for preventing and controlling DON pollution and its harm to human health.

Project description:In this study, we used dual RNA-sequencing to profile FHB-resistant AC Emerson, FHB-moderately AC Morley, and FHB-susceptible CDC Falcon winter wheat cultivars prior to and in response to Fusarium graminearum at 7 days post inoculation. Differential expression analyses revealed distinct defense responses between resistant and susceptible wheat cultivars including increased mechanical defense through lignin biosynthesis and increased deoxynivalenol (DON) detoxification through UDP-glycosyltransferase activity in resistant cultivars. Further, differential expression analysis in F. graminearum challenging these distinct cultivars revealed changes genes involved in trichothecene mycotoxin biosynthesis.

Project description:We constructed E. coli transcriptome under deoxynivalenol (DON) and nivalenol (NIV) condition from Fusarium spp. To identify differentially expressed genes in mycotoxin condition, we compared mycotoxin (DON and NIV) transcriptome to acetonitrile (ACN) transcriptome as the solvent of myxotoxin. As a result, 435-929 transcripts were identified from all conditions, respectively.

Project description:Fusarium graminearum is the major causal agent of Fusarium head blight (FHB) in North America and other regions of the world. The pathogen causes direct yield losses and produces various types of trichothecenes mycotoxins [Deoxynivalenol (DON) and its acetylated forms (3-acetyl-4-deoxynivalenol=3ADON and 15-acetyl-4-deoxvevalenol=15ADON), nivalenol (NIV). Recent studies indicated that 3ADON-type isolates were significantly increased in North America and China in recent years and appears to be more aggressive based on growth rate, disease severity on different cultivars, and DON production in vitro. Thus the overall objective of this this study was to understand the molecular mechanisms that make 3ADON- and 15ADON-type populations different during infection using a susceptible cultivar, and to compare the transcriptomes of the 3ADON- and 15ADON-type populations in vitro and in planta using the RNA-seq approach as well as to identify the expression differences of candidate genes related to aggressiveness and DON production.

Project description:Fusarium head blight (FHB) is a major disease of cereal crops caused by the fungus Fusarium graminearum (Fg). FHB affects the flowering heads (or spikes). This study compare the gene expression profile in wheat spikelets from the very susceptible spring wheat cultivar Roblin inoculated with either water (H2O), a Fg strain (GZ3639) producing the mycotoxin deoxynivalenol (+DON), or a GZ3639-derived Fg strain which has been inactivated at the Tri5 locus (-DON).

Project description:affy_brachy_2011_11 - affy_brachy_2011_11 - Fusarium graminearum is the causal agent of Fusarium head blight (FHB) of small-grain cereals, including wheat. Besides direct grain losses, this disease is of major concern because of the production by the pathogen of mycotoxins which are hazardous to animals, thus making the grain unfit for food or feed. Major mycotoxins produced by the fungus are trichothecens, including deoxynivalenol (DON). In our laboratory, we use Brachypodium distachyon as a model plant for cereals because of its amenability (short life cycle, numerous genomic and genetic resources, ...). We have recently shown that F. graminearum does induce head blight symptoms on this species and that DON is produced on infected spikes. We have also evidenced that a F. graminearum strain unable to produce DON exhibits reduced virulence on B. distachyon spikes, as previously shown on wheat. The aim of this project is to analyse and compare the plant response to DON producing and non-producing strains of F. graminearum. This analysis will allow to decipher the mechanisms of detoxification set up by the plant and also more specific responses due to the impact of the mycotoxin on plant metabolism and physiology. -Three conditions on B. distachyon spikes: 1-Mock inoculation (Tween 20 0,01%) 2-Inoculation by a F. graminearum wild-type strain 3-Inoculation by a F. graminearum mutant strain, unable to produce DON Spikes were point inoculated with 3ul of either Tween 20 0.01%, wild-type strain or mutant strain (300 spores) and incubated for 96 hours. Six inoculated spikes were collected and pooled for each condition and biological replicate. Three independent biological replicates were conducted. 9 arrays - Brachypodium; normal vs disease comparison,time course

Project description:affy_brachy_2011_11 - affy_brachy_2011_11 - Fusarium graminearum is the causal agent of Fusarium head blight (FHB) of small-grain cereals, including wheat. Besides direct grain losses, this disease is of major concern because of the production by the pathogen of mycotoxins which are hazardous to animals, thus making the grain unfit for food or feed. Major mycotoxins produced by the fungus are trichothecens, including deoxynivalenol (DON). In our laboratory, we use Brachypodium distachyon as a model plant for cereals because of its amenability (short life cycle, numerous genomic and genetic resources, ...). We have recently shown that F. graminearum does induce head blight symptoms on this species and that DON is produced on infected spikes. We have also evidenced that a F. graminearum strain unable to produce DON exhibits reduced virulence on B. distachyon spikes, as previously shown on wheat. The aim of this project is to analyse and compare the plant response to DON producing and non-producing strains of F. graminearum. This analysis will allow to decipher the mechanisms of detoxification set up by the plant and also more specific responses due to the impact of the mycotoxin on plant metabolism and physiology. -Three conditions on B. distachyon spikes: 1-Mock inoculation (Tween 20 0,01%) 2-Inoculation by a F. graminearum wild-type strain 3-Inoculation by a F. graminearum mutant strain, unable to produce DON Spikes were point inoculated with 3ul of either Tween 20 0.01%, wild-type strain or mutant strain (300 spores) and incubated for 96 hours. Six inoculated spikes were collected and pooled for each condition and biological replicate. Three independent biological replicates were conducted.

Project description:Fusarium graminearum (F.g) is responsible for Fusarium head blight (FHB), which is a destructive disease of wheat that accumulates mycotoxin such as deoxynivalenol (DON) and makes its quality unsuitable for end use. Several FHB resistant varieties development is going on world-wide. However the complete understanding of wheat defence response, pathogen (Fusarium graminearum) disease development mechanism and the gene crosstalk between organisms is still unclear. In our study focused to analyse pathogen (F. graminearum) molecular action in different Fusarium head blight resistance cultivars during the disease development. To understand the Fusarium graminearum pathogen molecular reaction, microarray gene expression analysis was carried out by using Fusarium graminearum (8 x 15k) Agilent arrays at two time points (3 & 7 days after infection) on three wheat genotypes (Japanese landrace cv. Nobeokabouzu-komugi - highly resistant, Chinese cv. Sumai 3 - resistant and Australian cv. Gamenya - susceptible), which spikes infected by Fusarium graminearum ‘H-3’strain. During the disease development the pathogen biomass as well as the expression of Trichothecene biosynthesis involved genes (Tri genes) in three wheat cultivars was determined. In our material no relation between fungus biomass and the disease symptoms were observed, however, it showed relation with fungus virulence factors expression (Tri genes). For the first time, we report the nature of Fusarium graminearum gene expression in the FHB-highly resistant cv. Nobeokabouzu-komugi during the disease development stage and the possible underlying molecular response.

Project description:Fusarium graminearum (F. graminearum) and its derivative mycotoxin deoxynivalenol (DON) are highly concerned with food security, safety and sustainability worldwide. The molecular mechanism regulates DON biosynthesis in F. graminearum remains enigmatic, despite several transcription factors (TFs) have been revealed containing regulatory functions. Here, we first characterized a zinc finger-contained TF, FgSfp1. Interestingly, contrast to the previous knowledge, all TRI-cluster genes were abnormally upregulated in ∆FgSfp1 while Tri proteins abundance rationally decreased, resulting in a 95.4% reduction of DON yield simultaneously. Further evidence determined FgSfp1 acted as a nutrient-sensing factor coordinates genetic expression efficiency through interference of ribosomal biogenesis process. Specifically, FgSfp1-depletion leads to ribosome biogenesis assembly factor (RiBi) expression attenuation along with DON precursor acetyl-CoA synthase reduction since FgSfp1 actively interacts with RNA 2’-O-methylation enzyme FgNop1 revealed by Bi-FC and subsequently influences mRNA translation capacity. In conclusion, we elucidated that the FgSfp1 orchestrates DON biosynthesis via participating RNA posttranscriptional modification for ribosomal RNA maturation, offering new insights into the DON biosynthesis regulation. Ultimately, this novel TF might be a key regulator for DON contamination control in the whole food chain.