Project description:Morphology together with the capability to respond to surrounding stimuli are the key elements governing the spatial interaction of a living cell with the environment. In this respect, biomechanical stimulation can trigger significant physiological cascades that can potentially modulate or interact with toxicity. Deoxynivalenol (DON, vomitoxin) is one of the most prevalent mycotoxins produced by Fusarium spp. and it was used to explore the delicate interaction between biomechanical stimulation and cytotoxic processes in A431 cells. In fact, in addition of being a well-known food contaminant, DON is becoming a relevant toxin also for other organ systems. The combination between biomechanical stimulation and the mycotoxin revealed how DON can impair crucial functions like cellular morphology and lysosome trafficking at concentrations far below those known to be cytotoxic in routine toxicity studies. Moreover, sub-toxic concentrations of DON (0.1-1 μM) impaired the capability of A431 cells to respond to a biomechanical stimulation that normally sustains trophic effects in this cell line. Ultimately, the effects of DON (0.1-10 μM) were partially modulated by the application of uniaxial stretching (0.5Hz, 24h, 15% deformation) suggesting a deep cross-talk between the cytotoxic potential of the mycotoxin and the biomechanical stimulation.

Project description:The possibility to combine untargeted proteomic workflows to more classical experimental approaches is continuously opening new insights in all branches of biological sciences. Deoxynivalenol (vomitoxin, DON) is a secondary metabolite produced by Fusarium spp. fungi and it is one of the most recurrent mycotoxins worldwide. DON is known to inhibit protein synthesis and as such to interact with the different cell types in multiple and complex ways. For the purpose of this study epidermoid squamous cell carcinoma cells A431 and primary human HEKn cells were incubated with DON for 24h and toxin dependent alteration of the proteome profile was observed in the nuclear and cytoplasmic fraction. In A431 cells, DON significantly down-regulated ribosomal proteins, as well as mitochondrial respiratory chain elements (OXPHOS regulation) and transport proteins (TOMM22; TOMM40; TOMM70A). In line with the impairment of the mitochondrial function, altered metabolic capability was observed, with particular target of the lipid synthesis machinery. Effect of the mycotoxin on cell membrane was verified by confocal microscopy (morphology) and by membrane fluidity measures (biophysical properties). The toxicological relevance of these findings was independently confirmed with the primary human keratinocytes HEKn.

Project description:Here we analysed different mechanisms of apical and basolateral deoxynivalenol (DON) toxicity reflected in the gene expression. We used the jejunum derived, polarized intestinal porcine epithelial cell line IPECM-bM-^@M-^QJ2 as an in vitro cell culture model. Luminal and blood stream DON intoxication was mimicked by a DON application from the apical or basolateral compartment of ThinCertM-BM-. membrane inserts for 72M-BM- h. We compared the genome wide gene expression of untreated and DON-treated IPEC-J2 cells by the GeneChipM-BM-. Porcine Genome Array of Affymetrix.

Project description:Proteomic changes associated with the individual and combined exposures of deoxynivalenol (DON) and zearalenone (ZEA) were investigated in human hepatocytes (HepaRG cell line) after 24 hour expousre and at low cytotoxicity levels using liquid chromatography coupled to tandem mass spectrometry.

Project description:Proteomic changes associated with the individual and combined exposures of deoxynivalenol (DON) and zearalenone (ZEA) were investigated in human hepatocytes (HepaRG cell line) after only 1h exposure and at low cytotoxicity levels using liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS)

Project description:The mycotoxin deoxynivalenol (DON) is a secondary metabolite from Fusarium species and is frequently present on wheat and other cereals. The main effects of DON are a reduction of the feed intake and reduced weight gain of broilers. At the molecular level DON binds to the 60S ribosomal subunit and inhibits subsequently protein synthesis at the translational level. It has been suggested that cells and tissues with high protein turnover rate, like the liver and small intestine, are most affected by DON. However, little is known about other effects of DON e.g. at the transcriptional level. Therefore we decided to perform a microarray analysis, which allows us the investigation of thousands of transcripts in one experiment. The one-day old broiler chicks were separated into four groups. The diets consisted of a control diet and of three diets with moderate concentrations of 1.0, 2.5 and 5.0 mg DON/kg feed, which was attained by exchanging uncontaminated wheat with naturally DON-contaminated wheat up to the intended concentration. The chicken were held at standard conditions for 23 days and received their diet ad libitum. After slaughter the gene expression was determined in the liver of three samples per group.

Project description:Deoxynivalenol (DON) is a frequent mycotoxin in grains, produced by Fusarium fungi, which demonstre multiple side effects such as modulation of immune responses, reduced feed intake and weight gain or impairment of the intestinal barrier function. Among animal species, pigs are the best model for humans and are very sensitive to DON. In wheat, DON can be conjugated to glucose to form DON-3-β-D-glucoside (D3G). Some bacteria isolated from digestive tracts or soil, are also able to de-epoxydize or epimerize DON to metabolites such as deepoxy-deoxynivalenol (DOM-1) or 3-epi-deoxynivalenol (epi-DON). The toxicity of these DON metabolites is poorly documented. By the way of ingestion, the intestine is the first organ exposed to these molecules and so constitute a relevant model. The aim of this study was to compare the intestinal toxicity of three DON metabolites (D3G, DOM-1 and epi-DON) with the one of DON. Intestinal explants from 6 pigs were treated with 10mM DON, D3G, DOM-1 or epi-DON for 4 hours and transcriptomic analysis was performed using an “Agilent Porcinet 60K”. Jejunal explants from 4 piglets aged of 5 weeks were sampled and exposed in vitro to differents molecules (DON, D3G, DOM-1 & 3-epi-DON) at 10µM during 4h. Then RNA was extracted.

Project description:Inflammation is a physiological process involved in many diseases. Monitoring proteins involved in regulatory effects may help to improve our understanding of inflammation. We have analyzed proteome alterations induced in peripheral blood mononuclear cells (PBMCs) upon inflammatory activation in great detail using high resolution mass spectrometry. Moreover, the activated cells were treated with dexamethasone to investigate their response to this antiphlogistic drug. From a total of 6886 identified proteins, 469 proteins were significantly regulated upon inflammatory activation. Most of these proteins were counter-regulated by dexamethasone, with some exceptions concerning members of the interferon-induced protein family. To confirm some of these results, we performed targeted MRM analyses of selected peptides. The inflammation-induced up-regulation of proteins such as IL-1beta, IL-6, CXCL2 and GROα was confirmed, however with strong quantitative inter-individual differences. Furthermore, the inability of dexamethasone to down-regulate inflammation-induced proteins such as PTX3 and TSG6 was clearly demonstrated. In conclusion, the relation of cell function as well as drug-induced modulation thereof was successfully mapped to proteomes, suggesting targeted analysis as a novel and powerful drug evaluation method. While most consequences of dexamethasone were found compatible with the expected way of action, some unexpected but significant observations may relate with adverse effects.

Project description:Inflammation is a physiological process involved in many diseases. Monitoring proteins involved in regulatory effects may help to improve our understanding of inflammation. We have analyzed proteome alterations induced in peripheral blood mononuclear cells (PBMCs) upon inflammatory activation in great detail using high resolution mass spectrometry. Moreover, the activated cells were treated with dexamethasone to investigate their response to this antiphlogistic drug. From a total of 6886 identified proteins, 469 proteins were significantly regulated upon inflammatory activation. Most of these proteins were counter-regulated by dexamethasone, with some exceptions concerning members of the interferon-induced protein family. To confirm some of these results, we performed targeted MRM analyses of selected peptides. The inflammation-induced up-regulation of proteins such as IL-1beta, IL-6, CXCL2 and GROα was confirmed, however with strong quantitative inter-individual differences. Furthermore, the inability of dexamethasone to down-regulate inflammation-induced proteins such as PTX3 and TSG6 was clearly demonstrated. In conclusion, the relation of cell function as well as drug-induced modulation thereof was successfully mapped to proteomes, suggesting targeted analysis as a novel and powerful drug evaluation method. While most consequences of dexamethasone were found compatible with the expected way of action, some unexpected but significant observations may relate with adverse effects.

Project description:Inflammation is a physiological process involved in many diseases. Monitoring proteins involved in regulatory effects may help to improve our understanding of inflammation. We have analyzed proteome alterations induced in peripheral blood mononuclear cells (PBMCs) upon inflammatory activation in great detail using high resolution mass spectrometry. Moreover, the activated cells were treated with dexamethasone to investigate their response to this antiphlogistic drug. From a total of 6886 identified proteins, 469 proteins were significantly regulated upon inflammatory activation. Most of these proteins were counter-regulated by dexamethasone, with some exceptions concerning members of the interferon-induced protein family. To confirm some of these results, we performed targeted MRM analyses of selected peptides. The inflammation-induced up-regulation of proteins such as IL-1beta, IL-6, CXCL2 and GROα was confirmed, however with strong quantitative inter-individual differences. Furthermore, the inability of dexamethasone to down-regulate inflammation-induced proteins such as PTX3 and TSG6 was clearly demonstrated. In conclusion, the relation of cell function as well as drug-induced modulation thereof was successfully mapped to proteomes, suggesting targeted analysis as a novel and powerful drug evaluation method. While most consequences of dexamethasone were found compatible with the expected way of action, some unexpected but significant observations may relate with adverse effects.