Vomitoxin

Vomitoxin, also known as deoxynivalenol (DON), is a type B trichothecene, an epoxy-sesquiterpenoid. This mycotoxin occurs predominantly in grains such as wheat, barley, oats, rye, and corn, and less often in rice, sorghum, and triticale. The occurrence of deoxynivalenol is associated primarily with Fusarium graminearum (Gibberella zeae) and F. culmorum, both of which are important plant pathogens which cause fusarium head blight in wheat and gibberella or fusarium ear blight in corn. A direct relationship between the incidence of fusarium head blight and contamination of wheat with deoxynivalenol has been established.[1] The incidence of fusarium head blight is strongly associated with moisture at the time of flowering (anthesis), and the timing of rainfall, rather than the amount, is the most critical factor. However, increased amount of moisture towards harvest time has been associated with lower amount of vomitoxin in wheat grain due to leaching of toxins.[2] Furthermore, deoxynivalenol contents are significantly affected by the susceptibility of cultivars towards Fusarium species, previous crop, tillage practices, and fungicide use.[3] It occurs abundantly in grains in Norway due to heavy rainfall.[4]

Vomitoxin
Names
IUPAC name
(3α,7α)-3,7,15-trihydroxy-12,13-epoxytrichothec-9-en-8-one
Other names

Deoxynivalenol (DON)
Vomitoxin
Identifiers
CAS Number
3D model (JSmol)
ChEMBL
ChemSpider
ECHA InfoCard 100.129.971
KEGG
PubChem CID
UNII
Properties
Chemical formula
C15H20O6
Molar mass 296.319 g·mol−1
Hazards
Safety data sheet External MSDS
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Infobox references

F. graminearum grows optimally at a temperature of 25 °C and at a water activity above 0.88. F. culmorum grows optimally at 21 °C and at a water activity above 0.87. The geographical distribution of the two species appears to be related to temperature, F. graminearum being the more common species occurring in warmer climates. Deoxynivalenol has been implicated in incidents of mycotoxicoses in both humans and farm animals.

Mechanism of action

Vomitoxin belongs to a class of mycotoxins (trichothecenes) which are strong inhibitors of protein synthesis[5]; exposure to vomitoxin causes the brain to decrease its uptake of the amino acid tryptophan and, in turn, its synthesis of serotonin. Reduced levels of serotonin are believed to be responsible for the anorexic effects of DON and other trichothecenes. Irritation of the gastrointestinal tract may also play a role in reducing feed intake, and may also partially explain the high incidence of paraesophageal stomach ulcers observed in sows during feed refusal. In humans DON is extensively glucuronidated and excreted via urine[6].

In food

When compared to other trichothecene mycotoxins which can form in grains and forages, vomitoxin is relatively mild. Reduced feed intake, with its accompanying decrease in performance, is the only symptom of vomitoxin toxicity livestock producers will likely encounter. This response to vomitoxin appears to occur through the central nervous system.

  • Human foods: Vomitoxin is not a known carcinogen as with aflatoxin. Large amounts of grain with vomitoxin would have to be consumed to pose acute toxicity in humans. Currently, the effects chronic of low-dose exposure are unknown. The U.S. Food and Drug Administration has established a level of 1 ppm (parts per million) restriction of vomitoxin.
  • Companion animals: Dogs and cats are restricted to 5 ppm and of grains and grain byproducts and the grains are not to exceed 40% percent of the diet.
  • Livestock and farm animals: In animals and livestock, vomitoxin causes a refusal to feed and lack of weight gain when fed above advised levels. Restrictions are set at 10 ppm for poultry and ruminating beef and feedlot cattle older than four months. Ingredients may not exceed 50% of the animal's diet. Dairy cow feed limits are set at 2 ppm.

Biosynthesis

Biosynthesis of vomitoxin

References

  1. Gautam, P. and Dill-Macky, R. 2011. Type I host resistance and Trichothecene Accumulation in Fusarium-infected Wheat Heads. American Journal of Agricultural and Animal Sciences 6(2):231-241.
  2. Gautam, P. and Dill-Macky, R. 2012. Impact of moisture, host genetics and Fusarium graminearum isolates on Fusarium head blight development and trichothecene accumulation in spring wheat. Mycotoxin Research 28 (1) doi:10.1007/s12550-011-0115-6
  3. Beyer M, Klix MB, Klink H, Verreet J-A (2006): Quantifying the effects of previous crop, tillage, cultivar and triazole fungicides on the deoxynivalenol content of wheat grain – a review. Journal of Plant Diseases and Protection 113: 241–246.
  4. http://www.vkm.no/dav/eee04d10c4.pdf
  5. Pestka, James J. (27 August 2010). "Deoxynivalenol: mechanisms of action, human exposure, and toxicological relevance". Archives of Toxicology. 84 (9): 663–679. doi:10.1007/s00204-010-0579-8.
  6. Warth, Benedikt; Sulyok, Michael; Berthiller, Franz; Schuhmacher, Rainer; Krska, Rudolf (June 2013). "New insights into the human metabolism of the Fusarium mycotoxins deoxynivalenol and zearalenone". Toxicology Letters. 220 (1): 88–94. doi:10.1016/j.toxlet.2013.04.012.
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