| MeSH term | MeSH ID | Detail |
|---|---|---|
| Hemolysis | D006461 | 131 associated lipids |
| Inflammation | D007249 | 119 associated lipids |
| Body Weight | D001835 | 333 associated lipids |
| Edema | D004487 | 152 associated lipids |
| Esophageal Neoplasms | D004938 | 20 associated lipids |
| Precancerous Conditions | D011230 | 48 associated lipids |
| Stomach Neoplasms | D013274 | 24 associated lipids |
| Hematuria | D006417 | 13 associated lipids |
| Weight Gain | D015430 | 101 associated lipids |
| Obesity | D009765 | 29 associated lipids |
| Hyperplasia | D006965 | 34 associated lipids |
| Carcinoma, Hepatocellular | D006528 | 140 associated lipids |
| Fetal Weight | D020567 | 12 associated lipids |
| Immune Complex Diseases | D007105 | 9 associated lipids |
| Glomerulonephritis, IGA | D005922 | 7 associated lipids |
| Swine Diseases | D013553 | 16 associated lipids |
| Poultry Diseases | D011201 | 21 associated lipids |
| Thymus Neoplasms | D013953 | 15 associated lipids |
| Bronchopneumonia | D001996 | 7 associated lipids |
| Fetal Resorption | D005327 | 15 associated lipids |
Vomitoxin
Vomitoxin is a lipid of Prenol Lipids (PR) class. Vomitoxin is associated with abnormalities such as Infection and Gastroenteritis. The involved functions are known as mRNA Expression, Inflammation, Transcription, Genetic, Protein Biosynthesis and Adverse effects. Vomitoxin often locates in Lymphoid Tissue, Immune system, Bone Marrow and Plasma membrane. The associated genes with Vomitoxin are IMPACT gene, HIST1H1C gene and RBM39 gene. The related experimental models are Mouse Model.
Cross Reference
Introduction
To understand associated biological information of Vomitoxin, we collected biological information of abnormalities, associated pathways, cellular/molecular locations, biological functions, related genes/proteins, lipids and common seen animal/experimental models with organized paragraphs from literatures.
What diseases are associated with Vomitoxin?
Vomitoxin is suspected in Infection, Gastroenteritis and other diseases in descending order of the highest number of associated sentences.
Related references are mostly published in these journals:
| Disease | Cross reference | Weighted score | Related literature |
|---|
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Possible diseases from mapped MeSH terms on references
We collected disease MeSH terms mapped to the references associated with Vomitoxin
PubChem Associated disorders and diseases
What pathways are associated with Vomitoxin
There are no associated biomedical information in the current reference collection.
PubChem Biomolecular Interactions and Pathways
Link to PubChem Biomolecular Interactions and PathwaysWhat cellular locations are associated with Vomitoxin?
Visualization in cellular structure
Associated locations are in red color. Not associated locations are in black.
Related references are published most in these journals:
| Location | Cross reference | Weighted score | Related literatures |
|---|
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What functions are associated with Vomitoxin?
Related references are published most in these journals:
| Function | Cross reference | Weighted score | Related literatures |
|---|
What lipids are associated with Vomitoxin?
There are no associated biomedical information in the current reference collection.
What genes are associated with Vomitoxin?
Related references are published most in these journals:
| Gene | Cross reference | Weighted score | Related literatures |
|---|
What common seen animal models are associated with Vomitoxin?
Mouse Model
Mouse Model are used in the study 'Dietary fish oil suppresses experimental immunoglobulin a nephropathy in mice.' (Pestka JJ et al., 2002).
Related references are published most in these journals:
| Model | Cross reference | Weighted score | Related literatures |
|---|
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NCBI Entrez Crosslinks
All references with Vomitoxin
Download all related citations| Authors | Title | Published | Journal | PubMed Link |
|---|---|---|---|---|
| Savard C et al. | Prevention of deoxynivalenol- and zearalenone-associated oxidative stress does not restore MA-10 Leydig cell functions. | 2016 | Toxicology | pmid:26783879 |
| Antonissen G et al. | The Impact of Deoxynivalenol on Pigeon Health: Occurrence in Feed, Toxicokinetics and Interaction with Salmonellosis. | 2016 | PLoS ONE | pmid:27997572 |
| Zhou S et al. | Systematic analysis of the lysine acetylome in Fusarium graminearum. | 2016 | BMC Genomics | pmid:27964708 |
| Drakulic J et al. | Contrasting Roles of Deoxynivalenol and Nivalenol in Host-Mediated Interactions between Fusarium graminearum and Sitobion avenae. | 2016 | Toxins (Basel) | pmid:27916862 |
| Frobose HL et al. | The progression of deoxynivalenol-induced growth suppression in nursery pigs and the potential of an algae-modified montmorillonite clay to mitigate these effects. | 2016 | J. Anim. Sci. | pmid:27898884 |
| Alizadeh A et al. | Deoxynivalenol and Its Modified Forms: Are There Major Differences? | 2016 | Toxins (Basel) | pmid:27854268 |
| Tian Y et al. | Detoxification of Deoxynivalenol via Glycosylation Represents Novel Insights on Antagonistic Activities of Trichoderma when Confronted with Fusarium graminearum. | 2016 | Toxins (Basel) | pmid:27854265 |
| Uhlig S et al. | Glutathione-Conjugates of Deoxynivalenol in Naturally Contaminated Grain Are Primarily Linked via the Epoxide Group. | 2016 | Toxins (Basel) | pmid:27845722 |
| Gao T et al. | Fusarium graminearum pyruvate dehydrogenase kinase 1 (FgPDK1) Is Critical for Conidiation, Mycelium Growth, and Pathogenicity. | 2016 | PLoS ONE | pmid:27341107 |
| Fan Z et al. | Development and Validation of an Ultra-High Performance Liquid Chromatography-Tandem Mass Spectrometry Method for Simultaneous Determination of Four Type B Trichothecenes and Masked Deoxynivalenol in Various Feed Products. | 2016 | Molecules | pmid:27338321 |
| Gunter AB et al. | Protein engineering of Saccharomyces cerevisiae transporter Pdr5p identifies key residues that impact Fusarium mycotoxin export and resistance to inhibition. | 2016 | Microbiologyopen | pmid:27263049 |
| Kugler KG et al. | Ribosome quality control is a central protection mechanism for yeast exposed to deoxynivalenol and trichothecin. | 2016 | BMC Genomics | pmid:27245696 |
| Gonçalves C and Stroka J | Cross-reactivity features of deoxynivalenol (DON)-targeted immunoaffinity columns aiming to achieve simultaneous analysis of DON and major conjugates in cereal samples. | 2016 | Food Addit Contam Part A Chem Anal Control Expo Risk Assess | pmid:27243664 |
| Schweiger W et al. | Suppressed recombination and unique candidate genes in the divergent haplotype encoding Fhb1, a major Fusarium head blight resistance locus in wheat. | 2016 | Theor. Appl. Genet. | pmid:27174222 |
| Cowger C et al. | Profitability of Integrated Management of Fusarium Head Blight in North Carolina Winter Wheat. | 2016 | Phytopathology | pmid:27111803 |
| Wiwart M et al. | The Response of Selected Triticum spp. Genotypes with Different Ploidy Levels to Head Blight Caused by Fusarium culmorum (W.G.Smith) Sacc. | 2016 | Toxins (Basel) | pmid:27092526 |
| Sanders M et al. | Comparison of Enzyme-Linked Immunosorbent Assay, Surface Plasmon Resonance and Biolayer Interferometry for Screening of Deoxynivalenol in Wheat and Wheat Dust. | 2016 | Toxins (Basel) | pmid:27077883 |
| Sugiyama K et al. | NF-κB activation via MyD88-dependent Toll-like receptor signaling is inhibited by trichothecene mycotoxin deoxynivalenol. | 2016 | J Toxicol Sci | pmid:26961612 |
| Talas F et al. | Genome-Wide Association Study Identifies Novel Candidate Genes for Aggressiveness, Deoxynivalenol Production, and Azole Sensitivity in Natural Field Populations of Fusarium graminearum. | 2016 | Mol. Plant Microbe Interact. | pmid:26959837 |
| Cao S et al. | FgSsn3 kinase, a component of the mediator complex, is important for sexual reproduction and pathogenesis in Fusarium graminearum. | 2016 | Sci Rep | pmid:26931632 |
| Zuo DY et al. | A Deoxynivalenol-Activated Methionyl-tRNA Synthetase Gene from Wheat Encodes a Nuclear Localized Protein and Protects Plants Against Fusarium Pathogens and Mycotoxins. | 2016 | Phytopathology | pmid:26882849 |
| Suzuki T and Iwahashi Y | Acetylated Deoxynivalenol Generates Differences of Gene Expression that Discriminate Trichothecene Toxicity. | 2016 | Toxins (Basel) | pmid:26861396 |
| Skóra J et al. | Evaluation of Microbiological and Chemical Contaminants in Poultry Farms. | 2016 | Int J Environ Res Public Health | pmid:26861361 |
| Schumann B et al. | Effects of deoxynivalenol (DON), zearalenone (ZEN), and related metabolites on equine peripheral blood mononuclear cells (PBMC) in vitro and background occurrence of these toxins in horses. | 2016 | Mycotoxin Res | pmid:27255919 |
| Bryła M et al. | Occurrence of 26 Mycotoxins in the Grain of Cereals Cultivated in Poland. | 2016 | Toxins (Basel) | pmid:27231939 |
| Hellin P et al. | Relationship between Fusarium spp. diversity and mycotoxin contents of mature grains in southern Belgium. | 2016 | Food Addit Contam Part A Chem Anal Control Expo Risk Assess | pmid:27181458 |
| Yau AT et al. | Dietary exposure to mycotoxins of the Hong Kong adult population from a Total Diet Study. | 2016 | Food Addit Contam Part A Chem Anal Control Expo Risk Assess | pmid:27144988 |
| Winkler J et al. | Fusarium toxin-contaminated maize in diets of growing bulls: effects on performance, slaughtering characteristics, and transfer into physiological liquids. | 2016 | Mycotoxin Res | pmid:27083899 |
| Tima H et al. | Fusarium mycotoxins in cereals harvested from Hungarian fields. | 2016 | Food Addit Contam Part B Surveill | pmid:26892197 |
| Thanner S et al. | Urinary deoxynivalenol (DON) and zearalenone (ZEA) as biomarkers of DON and ZEA exposure of pigs. | 2016 | Mycotoxin Res | pmid:26888520 |
| Calori-Domingues MA et al. | Co-occurrence and distribution of deoxynivalenol, nivalenol and zearalenone in wheat from Brazil. | 2016 | Food Addit Contam Part B Surveill | pmid:26886061 |
| Qiu J et al. | Effect of preceding crop on Fusarium species and mycotoxin contamination of wheat grains. | 2016 | J. Sci. Food Agric. | pmid:26867679 |
| Liu J et al. | Aflatoxin B1, zearalenone and deoxynivalenol in feed ingredients and complete feed from central China. | 2016 | Food Addit Contam Part B Surveill | pmid:26771914 |
| Ren ZH et al. | The Fusarium toxin zearalenone and deoxynivalenol affect murine splenic antioxidant functions, interferon levels, and T-cell subsets. | 2016 | Environ. Toxicol. Pharmacol. | pmid:26722803 |
| Albonico M et al. | Toxicological effects of fumonisin B1 alone and in combination with other fusariotoxins on bovine granulosa cells. | 2016 | Toxicon | pmid:27108238 |
| Pizzo F et al. | In vitro effects of deoxynivalenol and zearalenone major metabolites alone and combined, on cell proliferation, steroid production and gene expression in bovine small-follicle granulosa cells. | 2016 | Toxicon | pmid:26657070 |
| Dänicke S et al. | Haematological and immunological adaptations of non-pregnant, non-lactating dairy cows to a high-energetic diet containing mycotoxins. | 2016 | Arch Anim Nutr | pmid:26654380 |
| Buhrow LM et al. | Exogenous Abscisic Acid and Gibberellic Acid Elicit Opposing Effects on Fusarium graminearum Infection in Wheat. | 2016 | Phytopathology | pmid:27135677 |
| DÄ…browski M et al. | Changes in the Subpopulations of Porcine Peripheral Blood Lymphocytes Induced by Exposure to Low Doses of Zearalenone (ZEN) and Deoxynivalenol (DON). | 2016 | Molecules | pmid:27128894 |
| Mayer S et al. | Occupational exposure to mould and microbial metabolites during onion sorting--insights into an overlooked workplace. | 2016 | Environ Monit Assess | pmid:26863887 |
| Quesada-Ocampo LM et al. | Susceptibility of Maize to Stalk Rot Caused by Fusarium graminearum Deoxynivalenol and Zearalenone Mutants. | 2016 | Phytopathology | pmid:27050573 |
| Li C et al. | A universal multi-wavelength fluorescence polarization immunoassay for multiplexed detection of mycotoxins in maize. | 2016 | Biosens Bioelectron | pmid:26720917 |
| Ling KH et al. | Protective Capacity of Resveratrol, a Natural Polyphenolic Compound, against Deoxynivalenol-Induced Intestinal Barrier Dysfunction and Bacterial Translocation. | 2016 | Chem. Res. Toxicol. | pmid:27058607 |
| Burt C et al. | Mapping a Type 1 FHB resistance on chromosome 4AS of Triticum macha and deployment in combination with two Type 2 resistances. | 2015 | Theor. Appl. Genet. | pmid:26040404 |
| Cheat S et al. | Nivalenol has a greater impact than deoxynivalenol on pig jejunum mucosa in vitro on explants and in vivo on intestinal loops. | 2015 | Toxins (Basel) | pmid:26035490 |
| Tola S et al. | Effects of Wheat Naturally Contaminated with Fusarium Mycotoxins on Growth Performance and Selected Health Indices of Red Tilapia (Oreochromis niloticus × O. mossambicus). | 2015 | Toxins (Basel) | pmid:26035489 |
| Gu Q et al. | The transmembrane protein FgSho1 regulates fungal development and pathogenicity via the MAPK module Ste50-Ste11-Ste7 in Fusarium graminearum. | 2015 | New Phytol. | pmid:25388878 |
| Wallin S et al. | Biomonitoring of concurrent mycotoxin exposure among adults in Sweden through urinary multi-biomarker analysis. | 2015 | Food Chem. Toxicol. | pmid:26070503 |
| Escrivá L et al. | In vivo toxicity studies of fusarium mycotoxins in the last decade: a review. | 2015 | Food Chem. Toxicol. | pmid:25680507 |
| Kuhnem PR et al. | Fusarium graminearum Isolates from Wheat and Maize in New York Show Similar Range of Aggressiveness and Toxigenicity in Cross-Species Pathogenicity Tests. | 2015 | Phytopathology | pmid:25338173 |