Structure
The compounds have a similar structure, that of eight amino-acid residues arranged in a conserved macrobicyclic motif (an overall pentacyclic structure when counting the rings inherent in the proline and tryptophan-derived residues); they were isolated in 1941 by Heinrich O. Wieland and Rudolf Hallermayer. All amatoxins are cyclic peptides that are synthesized as 35-amino-acid proproteins, from which the final eight amino acids are cleaved by a prolyl oligopeptidase. The schematic amino acid sequence of amatoxins is Ile-Trp-Gly-Ile-Gly-Cys-Asn-Pro with cross-linking between Trp and Cys via the sulfoxide (S=O) moiety and hydroxylation in variants of the molecule; enzymes for these processings steps remain unknown. There are currently ten named amatoxins: δ-Amanitin has been reported, but its chemical structure has not been determined.Family relations
Amanitin is very closely related to phalloidins, which are bicyclic 7-residue toxins. They both are part of the MSDINMechanism
Amatoxins are potent and selective inhibitors ofSymptoms of exposure
Upon exposure to amatoxins, theTreatment
There are many anecdotal and partially-studied treatments in use worldwide. One study in mice showed null results for all studied treatments. Treatments showing no discernable value included N-acetylcysteine, benzylpenicillin, cimetidine, thioctic acid, and silybin. Treatment involves high-doseDetection
Presence of amatoxins in mushroom samples may be detected by the Meixner test (also known as the Wieland test). The amatoxins may be quantitated in plasma or urine using chromatographic techniques to confirm a diagnosis of poisoning in hospitalized patients and in postmortem tissues to aid in a medicolegal investigation of a suspected fatal overdosage. In 2020, a monoclonal antibody-based lateral flow immunoassay has been developed that can quickly and selectively detect amatoxins. This test sensitively detects alpha-amanitin and gamma-amanitin (clearly detects 10 ng/mL), and exhibits slightly less detection for beta-amanitin (0.5% cross-reactivity; 2000 ng/mL). Although this test cross-reacts with phallotoxins at 0.005% (200,000 ng/mL), the phallotoxins would not interfere in urine sampling and there are very rare instances where a mushroom produces phallotoxins without producing amatoxins.Studies
In a 2013 study on the toxin concentration in '' Amanita phalloides'' all parts of the mushroom were found to contain amatoxins and it was determined that the highest concentrations were found in the gills and cap with the lowest levels in the spores and mycelium. An additional study published in 2013 by many of the same authors found no difference in the ITS sequence of ''Amanita phalloides var. alba'' but did find different concentrations of toxins. The gills and cap of ''Amanita phalloides var. alba'' also contained the highest level with very low levels noted in the spores, volva and stipe however in this variant the spores had a higher concentration of all toxins besides gamma amanitin than was found in ''Amanita phalloides.'' The spores of ''Amanita phalloides var. alba'' contained 0.89 mg/g of alpha-amanitin, 0.48 mg/g of beta-amanitin and 0.001 mg/g gamma-amanitin in contrast to the 2.46, 1.94 and 0.36 mg/g found in the gills and the 2.40, 1.75 and 0.27 mg/g found in the cap. The concentration found in the gills, cap, stipe and volva of ''Amanita phalloides var. alba'' is lower than in ''Amanita phalloides'' however the spores were shown to contain a higher concentration. In both studies six mushrooms were spore printed, dried and tested with the toxin level in the whole mushroom being derived from testing one half of the whole mushroom cut down the middle, the other half was divided into cap, gill, stipe and volva sections to test individually with the parts ground into a powder and tested as 1gram samples. In 2010 a study on '' Amanita bisporigera'', the destroying angel, determined that the concentrations of toxins in the spores were also lower than the levels found in the cap or stipe. Amatoxins are extremely toxic to humans with ''Amanita phalloides'' and its variants making up many of the cases of fatal toxicity after consumption.These toxins have high heat stability and this property combined with their solubility in water make them exceptionally toxic as they are not destroyed by cooking or drying. In addition, amatoxins are resistant to enzyme and acid degradation, and therefore when ingested they are not inactivated in the gastrointestinal tract. A fatal case was reported after consuming ''A. phalloides'' that had been frozen for 7–8 months, thus demonstrating that these compounds are also resistant to the freeze/thawing processes. Additionally, amatoxins decompose very slowly when stored in open, aqueous solutions or following prolonged exposure to sun or neon light. In 2015 a case study was conducted on a patient who cooked and consumed just the caps from two ''Amanita phalloides'' mushrooms and was subsequently admitted to hospital a day later. The subject was a 61-year-old man with a body weight of 67 kg who was presenting with fatigue, abdominal pain, nausea, vomiting and diarrhea. Mushrooms were collected from the same region and shown to the patient in order to confirm that these were what he had eaten and two mushrooms of approximately the same size and level of maturity were selected for study. Previous studies have demonstrated that younger mushrooms can contain a higher concentration of toxins than is found in mature specimens. The combined weight of the caps of these two mushrooms was 43.4g fresh or 4.3g when dry and when tested were found to contain a total of 21.3 mg of amatoxin distributed as 11.9 mg alpha-amanitin, 8.4 mg beta-amanitin and 1 mg gamma-amanitin. Analysis of the patient's urine after 4 days of treatment in hospital showed a concentration of 2.7 ng/ml alpha-amanitin and 1.25 ng/ml beta-amanitin with no gamma-amanitin detected. The patient survived and was discharged after 9 days of treatment with follow up tests showing no signs of liver damage but based on this case it was estimated that an oral dose of 0.32 mg amatoxin per kg of body mass could be lethal with an approximate lethal dose of alpha-amanitin being 0.2 mg/kg when taken orally. It was estimated that consuming more than 50g of fresh ''Amanita phalloides'', roughly 2 medium-sized mushrooms could be deadly. Clinical tests showed that the amount consumed by the patient remained below the hypothetical lethal dose, which the study notes probably varies depending on patient health, predisposition to liver damage and regional variation in toxin concentrations. Anecdotes have been repeated in field guides that claim foragers have fallen ill from spores alone after collecting toxic ''Amanita'' species in the same basket, unwittingly leaving their spores to collect on the harvest before the toxic ones were discarded. This subject however has not been researched and studies make no claims one way or the other as to the possibility of poisoning from spores alone. Given that the concentration of toxins found in the spores is lower than that of the cap it would require the consumption of a substantial mass of spores in excess of the weight of the mushroom caps themselves, in order to reach a fatal dose.Mushroom species
Amatoxin-containing mushroom species from the genera ''Amanita'', ''Galerina'' and ''Lepiota''.See also
* Phallotoxins, a closely related class of mycotoxinsReferences
{{Toxins Hepatotoxins RNA polymerase inhibitors