Orellanine

Orellanine or orellanin is a mycotoxin found in a group of mushrooms known as the Orellani of the Cortinariaceae family. Structurally, it is a bipyridine N-oxide compound somewhat related to diquat. Orellanine or orellanin is a mycotoxin found in a group of mushrooms known as the Orellani of the Cortinariaceae family. Structurally, it is a bipyridine N-oxide compound somewhat related to diquat. Orellanine first came to people's attention in 1957 when there was a mass poisoning of 135 people in Bydgoszcz, Poland, which resulted in 19 deaths. Orellanine comes from a class of mushrooms that fall under the genus Cortinarius. Although not all the species in this genus are poisonous/contain orellanine, it was found that Cortinarius orellanus, rubellus, henrici, rainerensis and bruneofulvus contain orellanine. Poisonings pertaining to these mushrooms were predominately in Europe where foraging was a major source of nourishment, although there are cases of orellanine poisoning in North America as well. Orellanine has been found to cause acute renal failure and there are many cases where people have taken this mushroom mistaking it for causing hallucinogenic effects. It wasn't until 1962 until the first isolation of orellanine was done. The first methanolic extraction and isolation of orellanine was done by Stanisław Grzymala and isolated from the mushroom Cortinarius orellanus. Along with the isolation of orellanine, Grzymala was also able to demonstrate the nephrotoxicity of Cortinarius orellanus and determine various physical and chemical properties of orellanine. He found that the toxicity of the mushrooms was linked to delayed and acute renal failure, as well as when the isolated white crystalline substance was heated above 150 ̊C it began to slowly decompose. After this first isolation of orellanine, the structure of orellanine was first discovered by Antkowiak and Gessner in 1979. Orellanine’s structure was found to be 3,3',4,4'-tetrahydroxy- 2,2'-bipyridine-l,l'-dioxide. Antkowiak and Gessner were also able to determine that orellanine was the mono-N-oxide of orelline, which was the decomposition product of orellanine. It was also found that orelline was non-toxic. The first successful synthesis of orellanine was done in 1985. Tiecco, M. et. Al. completed a total synthesis of orellanine using commercially available 3-hydroxypyridine. After the first successful synthesis, the structure was confirmed in 1987 by Cohen-Addad et al. in 1987 by X-ray crystallography. The chemical constitution of orellanine remained unknown until the Polish chemists Antkowiak and Gessner in the last half of the 1970s discovered that it was a bipyridine dioxide. Orellanine undergoes tautomerization, and the more stable tautomer is the amine oxide form. An interesting feature of orellanine is its ability to bind aluminium ions to form chelation complexes. The first synthesis of orellanine was done in 1985 and Tiecco, M. et. Al. were able to synthesize orellaine from 3-hydroxy pyridine. This synthesis was completed in 8 steps with a 79-87% yield. When synthesized the two pyridyl rings are nearly perpendicular and the molecule is chiral. When it is isolated from the mushroom, it is an optically inactive racemic mixture. Other synthetic strategies have also been attempted. For example, orellanine was also synthesized in 9 steps by Dehmlow and Schulz in 1985 using 3-aminopyridine and the desired product was synthesized with 30% yield. In the synthesis done by Tiecco, M. et al. can be seen in the scheme below. In the first step, 3-hydroxy pyridine was first treated with bromine in an alkaline solution to obtain 2. The product of that step was then subjected to O-alkylation using DMF as a solvent to obtain 3. 3 was the oxidized with m-chloroperbenzoic acid in chloroform to give 4. That product was then nitrated with nitric acid and sulfuric acid to obtain a mixture of 5 and 6. These two molecules were separated by combining the mixture of products with water. 5 is insoluble in water, whereas 6 is soluble in water. 6 was then subjected to sodium methoxide in methanol to obtain the other methoxy group seen in product 7 and 7 was deoxygenated using phosphorus tribromide to obtain 8. To obtain tetramethyl orelline, structure 9, triphenylphosphine, NiCl2·6H2O, and zinc powder were used to conduct the homocoupling of halopyridines through the use of nickel-phosphine complexes. Once 8 with the bipyridyl structure had been obtained, the synthesis of orellanine could be conducted. The bipyridyl product from number 8 is then dealkylated with hydrobromic acid to give orelline, which was found to be a yellow crystalline solid (10). Orelline is then oxidized with hydrogen peroxide using heat to obtain the desired product, orellanine (11).