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.

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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 Pathways

What cellular locations are associated with Vomitoxin?

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

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Authors Title Published Journal PubMed Link
Liu X et al. Acetohydroxyacid synthase FgIlv2 and FgIlv6 are involved in BCAA biosynthesis, mycelial and conidial morphogenesis, and full virulence in Fusarium graminearum. 2015 Sci Rep pmid:26552344
Perochon A et al. TaFROG Encodes a Pooideae Orphan Protein That Interacts with SnRK1 and Enhances Resistance to the Mycotoxigenic Fungus Fusarium graminearum. 2015 Plant Physiol. pmid:26508775
Clark ES et al. High Sensitivity of Aged Mice to Deoxynivalenol (Vomitoxin)-Induced Anorexia Corresponds to Elevated Proinflammatory Cytokine and Satiety Hormone Responses. 2015 Toxins (Basel) pmid:26492270
Gauthier L et al. Metabolomics to Decipher the Chemical Defense of Cereals against Fusarium graminearum and Deoxynivalenol Accumulation. 2015 Int J Mol Sci pmid:26492237
Nussbaumer T et al. Joint Transcriptomic and Metabolomic Analyses Reveal Changes in the Primary Metabolism and Imbalances in the Subgenome Orchestration in the Bread Wheat Molecular Response to Fusarium graminearum. 2015 G3 (Bethesda) pmid:26438291
Ali N et al. Deoxynivalenol Exposure Assessment for Pregnant Women in Bangladesh. 2015 Toxins (Basel) pmid:26404372
Bönnighausen J et al. Disruption of the GABA shunt affects mitochondrial respiration and virulence in the cereal pathogen Fusarium graminearum. 2015 Mol. Microbiol. pmid:26305050
Zhou HR and Pestka JJ Deoxynivalenol (Vomitoxin)-Induced Cholecystokinin and Glucagon-Like Peptide-1 Release in the STC-1 Enteroendocrine Cell Model Is Mediated by Calcium-Sensing Receptor and Transient Receptor Potential Ankyrin-1 Channel. 2015 Toxicol. Sci. pmid:25787141
Kazemi Darsanaki R et al. Occurrence of deoxynivalenol (DON) in wheat flours in Guilan province, northern Iran. 2015 Ann Agric Environ Med pmid:25780825
Kluger B et al. Biotransformation of the mycotoxin deoxynivalenol in fusarium resistant and susceptible near isogenic wheat lines. 2015 PLoS ONE pmid:25775425
Paulick M et al. Effects of increasing concentrations of sodium sulfite on deoxynivalenol and deoxynivalenol sulfonate concentrations of maize kernels and maize meal preserved at various moisture content. 2015 Toxins (Basel) pmid:25760079
Yun Y et al. Functional analysis of the Fusarium graminearum phosphatome. 2015 New Phytol. pmid:25758923
Ji F et al. Relationship of deoxynivalenol content in grain, chaff, and straw with Fusarium head blight severity in wheat varieties with various levels of resistance. 2015 Toxins (Basel) pmid:25751146
Walter S et al. A wheat ABC transporter contributes to both grain formation and mycotoxin tolerance. 2015 J. Exp. Bot. pmid:25732534
Guerrero-Netro HM et al. Effects of the mycotoxin deoxynivalenol on steroidogenesis and apoptosis in granulosa cells. 2015 Reproduction pmid:25731188
McElhinney C et al. Development and validation of an UHPLC-MS/MS method for the determination of mycotoxins in grass silages. 2015 Food Addit Contam Part A Chem Anal Control Expo Risk Assess pmid:26374621
Liang Z et al. Individual and combined effects of deoxynivalenol and zearalenone on mouse kidney. 2015 Environ. Toxicol. Pharmacol. pmid:26407231
Kharbikar LL et al. Impact of post-anthesis rainfall, fungicide and harvesting time on the concentration of deoxynivalenol and zearalenone in wheat. 2015 Food Addit Contam Part A Chem Anal Control Expo Risk Assess pmid:26361223
Gu W et al. A novel and simple cell-based electrochemical impedance biosensor for evaluating the combined toxicity of DON and ZEN. 2015 Biosens Bioelectron pmid:25863342
Winkler J et al. Development of a multi-toxin method for investigating the carryover of zearalenone, deoxynivalenol and their metabolites into milk of dairy cows. 2015 Food Addit Contam Part A Chem Anal Control Expo Risk Assess pmid:25849036
Gerez JR et al. Deoxynivalenol alone or in combination with nivalenol and zearalenone induce systemic histological changes in pigs. 2015 Exp. Toxicol. Pathol. pmid:25467749
Martinez M et al. [Fusarium graminearum presence in wheat samples for human consumption]. 2014 Jan-Mar Rev. Argent. Microbiol. pmid:24721273
van der Fels-Klerx HJ Evaluation of performance of predictive models for deoxynivalenol in wheat. 2014 Risk Anal. pmid:23901939
Devreese M et al. The effects of feed-borne Fusarium mycotoxins and glucomannan in turkey poults based on specific and non-specific parameters. 2014 Food Chem. Toxicol. pmid:24200858
Dzuman Z et al. Enzyme-linked immunosorbent assay in analysis of deoxynivalenol: investigation of the impact of sample matrix on results accuracy. 2014 Anal Bioanal Chem pmid:24292429
Mishra S et al. Influence of temperature and pH on the degradation of deoxynivalenol (DON) in aqueous medium: comparative cytotoxicity of DON and degraded product. 2014 Food Addit Contam Part A Chem Anal Control Expo Risk Assess pmid:24261986
Cirlini M et al. Durum wheat (Triticum Durum Desf.) lines show different abilities to form masked mycotoxins under greenhouse conditions. 2014 Toxins (Basel) pmid:24368326
Yang W et al. Deoxynivalenol induced oxidative stress and genotoxicity in human peripheral blood lymphocytes. 2014 Food Chem. Toxicol. pmid:24355168
Mohamed MS et al. Type 1 ribotoxin-curcin conjugated biogenic gold nanoparticles for a multimodal therapeutic approach towards brain cancer. 2014 Biochim. Biophys. Acta pmid:24361614
Ghareeb K et al. Insights on the host stress, fear and growth responses to the deoxynivalenol feed contaminant in broiler chickens. 2014 PLoS ONE pmid:24498179
Denschlag C et al. Real-time loop-mediated isothermal amplification (LAMP) assay for group specific detection of important trichothecene producing Fusarium species in wheat. 2014 Int. J. Food Microbiol. pmid:24631635
Audenaert K et al. Deoxynivalenol: a major player in the multifaceted response of Fusarium to its environment. 2014 Toxins (Basel) pmid:24451843
Giménez I et al. Effects of bread making and wheat germ addition on the natural deoxynivalenol content in bread. 2014 Toxins (Basel) pmid:24451845
Jajić I et al. Incidence of deoxynivalenol in Serbian wheat and barley. 2014 J. Food Prot. pmid:24780345
Zhou HR et al. Direct activation of ribosome-associated double-stranded RNA-dependent protein kinase (PKR) by deoxynivalenol, anisomycin and ricin: a new model for ribotoxic stress response induction. 2014 Toxins (Basel) pmid:25521494
Wu M et al. An NMR-based metabolomic approach to investigate the effects of supplementation with glutamic acid in piglets challenged with deoxynivalenol. 2014 PLoS ONE pmid:25502722
van der Fels-Klerx HJ et al. A framework to determine the effectiveness of dietary exposure mitigation to chemical contaminants. 2014 Food Chem. Toxicol. pmid:25445762
Yu F et al. The TOR signaling pathway regulates vegetative development and virulence in Fusarium graminearum. 2014 New Phytol. pmid:24684168
Bormann J et al. The adenylyl cyclase plays a regulatory role in the morphogenetic switch from vegetative to pathogenic lifestyle of Fusarium graminearum on wheat. 2014 PLoS ONE pmid:24603887
Aristimuño Ficoseco ME et al. Antifungal and antimycotoxigenic metabolites in Anacardiaceae species from northwest Argentina: isolation, identification and potential for control of Fusarium species. 2014 J. Appl. Microbiol. pmid:24428333
Patience JF et al. Evaluation of two mycotoxin mitigation strategies in grow-finish swine diets containing corn dried distillers grains with solubles naturally contaminated with deoxynivalenol. 2014 J. Anim. Sci. pmid:24398837
Weaver AC et al. Protective effect of two yeast based feed additives on pigs chronically exposed to deoxynivalenol and zearalenone. 2014 Toxins (Basel) pmid:25533517
Kim DH et al. Incidence and levels of deoxynivalenol, fumonisins and zearalenone contaminants in animal feeds used in Korea in 2012. 2014 Toxins (Basel) pmid:24366207
Waśkiewicz A et al. Deoxynivalenol and oxidative stress indicators in winter wheat inoculated with Fusarium graminearum. 2014 Toxins (Basel) pmid:24514944
Kosawang C et al. Transcriptomic profiling to identify genes involved in Fusarium mycotoxin Deoxynivalenol and Zearalenone tolerance in the mycoparasitic fungus Clonostachys rosea. 2014 BMC Genomics pmid:24450745
Gerding J et al. Determination of mycotoxin exposure in Germany using an LC-MS/MS multibiomarker approach. 2014 Mol Nutr Food Res pmid:25243722
Kim KY et al. Development of a simultaneous lateral flow strip test for the rapid and simple detection of deoxynivalenol and zearalenone. 2014 J. Food Sci. pmid:25224778
Brezina U et al. Development of a liquid chromatography tandem mass spectrometry method for the simultaneous determination of zearalenone, deoxynivalenol and their metabolites in pig serum. 2014 Mycotoxin Res pmid:24925826
Bertuzzi T et al. Co-occurrence of type A and B trichothecenes and zearalenone in wheat grown in northern Italy over the years 2009-2011. 2014 Food Addit Contam Part B Surveill pmid:24848161
Song S et al. Multiplex lateral flow immunoassay for mycotoxin determination. 2014 Anal. Chem. pmid:24745689