Amanita phalloides


Amanita phalloides, commonly known as the death cap, is a deadly poisonous basidiomycete fungus and mushroom, one of many in the genus Amanita. Originating in Europe but later introduced to other parts of the world since the late twentieth century, A. phalloides forms ectomycorrhizas with various broadleaved trees. In some cases, the death cap has been introduced to new regions with the cultivation of non-native species of oak, chestnut, and pine. The large fruiting bodies appear in summer and autumn; the caps are generally greenish in colour with a white stipe and gills. The cap colour is variable, including white forms, and is thus not a reliable identifier.
The death cap resembles several edible species commonly consumed by humans, increasing the risk of accidental poisoning. Amatoxins, the class of toxins found in these mushrooms, are thermostable: they resist changes due to heat and cold, so their toxic effects are not reduced by cooking nor freezing.
Amanita phalloides is the most poisonous of all known mushrooms. It is estimated that as little as half a mushroom contains enough toxin to kill an adult human. It is also the deadliest mushroom worldwide, responsible for 90% of mushroom-related fatalities every year. It has been involved in the majority of human deaths from mushroom poisoning, possibly including Roman Emperor Claudius in AD 54 and Holy Roman Emperor Charles VI in 1740. It has also been the subject of much research and many of its biologically active agents have been isolated. The principal toxic constituent is α-Amanitin, which causes liver and kidney failure.

Taxonomy

The death cap is named in Latin as such in the correspondence between the English physician Thomas Browne and Christopher Merrett. It was described by French botanist Sébastien Vaillant in 1727, who gave a succinct phrase name "Fungus phalloides, annulatus, sordide virescens, et patulus" .
In 1821, Elias Magnus Fries described it as Agaricus phalloides, but included all white amanitas within its description. Finally, in 1833, Johann Heinrich Friedrich Link settled on the name Amanita phalloides, after Persoon had named it Amanita viridis 30 years earlier. Although Louis Secretan's use of the name A. phalloides predates Link's, it has been rejected for nomenclatural purposes because Secretan's works did not use binomial nomenclature consistently; some taxonomists have, however, disagreed with this opinion.
Amanita phalloides is the type species of Amanita section Phalloideae, a group that contains all of the deadly poisonous Amanita species thus far identified. Most notable of these are the species known as destroying angels, including A. virosa, A. bisporigera, A. ocreata, A. verna, and more than a dozen others. The term "destroying angel" has been applied to A. phalloides at times, but "death cap" is by far the most common vernacular name used in English. Other common names also listed include "stinking amanita" and "deadly amanita".
A rarely appearing, all-white form was initially described A. phalloides f. alba by Max Britzelmayr, though its status has been unclear. It is often found growing amid normally colored death caps. It has been described, in 2004, as a distinct variety and includes what was termed A. verna var. tarda. The true A. verna fruits in spring and turns yellow with KOH solution, whereas A. phalloides never does.

Description

The death cap has a large and imposing epigeous fruiting body, usually with a pileus from 5 to 15 cm across across, initially rounded and hemispherical, but flattening with age. The color of the cap can be pale-green, yellowish-green, olive-green, bronze, or white; it is often paler toward the margins, which can have darker streaks; it is also often paler after rain. The cap surface is sticky when wet and easily peeled—a troublesome feature, as that is allegedly a feature of edible fungi. The remains of the partial veil are seen as a skirtlike, floppy annulus usually about below the cap. The crowded white lamellae are free. The stipe is white with a scattering of grayish-olive scales and is long and thick, with a swollen, ragged, sac-like white volva. As the volva, which may be hidden by leaf litter, is a distinctive and diagnostic feature, it is important to remove some debris to check for it. Spores: 7-12 x 6-9 μm. Smooth, ellipsoid, amyloid.
The smell has been described as initially faint and honey-sweet, but strengthening over time to become overpowering, sickly-sweet and objectionable. Young specimens first emerge from the ground resembling a white egg covered by a universal veil, which then breaks, leaving the volva as a remnant. The spore print is white, a common feature of Amanita. The transparent spores are globular to egg-shaped, measure 8–10 μm long, and stain blue with iodine. The gills, in contrast, stain pallid lilac or pink with concentrated sulfuric acid.

Biochemistry

The species is now known to contain two main groups of toxins, both multicyclic peptides spread throughout the mushroom, tissue: the amatoxins and the phallotoxins. Another toxin is phallolysin, which has shown some hemolytic activity in vitro. An unrelated compound, antamanide, has also been isolated.
Amatoxins consist of at least eight compounds with a similar structure, that of eight amino-acid rings; they were isolated in 1941 by Heinrich O. Wieland and Rudolf Hallermayer of the University of Munich. Of the amatoxins, α-Amanitin is the chief component and along with β-amanitin is likely responsible for the toxic effects. Their major toxic mechanism is the inhibition of RNA polymerase II, a vital enzyme in the synthesis of messenger RNA, microRNA, and small nuclear RNA. Without mRNA, essential protein synthesis and hence cell metabolism grind to a halt and the cell dies. The liver is the principal organ affected, as it is the organ which is first encountered after absorption in the gastrointestinal tract, though other organs, especially the kidneys, are susceptible. The RNA polymerase of Amanita phalloides is insensitive to the effects of amatoxins, so the mushroom does not poison itself.
The phallotoxins consist of at least seven compounds, all of which have seven similar peptide rings. Phalloidin was isolated in 1937 by Feodor Lynen, Heinrich Wieland's student and son-in-law, and Ulrich Wieland of the University of Munich. Though phallotoxins are highly toxic to liver cells, they have since been found to add little to the death cap's toxicity, as they are not absorbed through the gut. Furthermore, phalloidin is also found in the edible blusher. Another group of minor active peptides are the virotoxins, which consist of six similar monocyclic heptapeptides. Like the phallotoxins, they do not induce any acute toxicity after ingestion in humans.
The genome of the death cap has been sequenced.

Similarity to edible species

A. phalloides is similar to the edible paddy straw mushroom and A. princeps, commonly known as "white Caesar".
Some may mistake juvenile death caps for edible puffballs or mature specimens for other edible Amanita species, such as A. lanei, so some authorities recommend avoiding the collecting of Amanita species for the table altogether. The white form of A. phalloides may be mistaken for edible species of Agaricus, especially the young fruitbodies whose unexpanded caps conceal the telltale white gills; all mature species of Agaricus have dark-colored gills.
In Europe, other similarly green-capped species collected by mushroom hunters include various green-hued brittlegills of the genus Russula and the formerly popular Tricholoma equestre, now regarded as hazardous owing to a series of restaurant poisonings in France. Brittlegills, such as Russula heterophylla, R. aeruginea, and R. virescens, can be distinguished by their brittle flesh and the lack of both volva and ring. Other similar species include A. subjunquillea in eastern Asia and A. arocheae, which ranges from Andean Colombia north at least as far as central Mexico, both of which are also poisonous.

Distribution and habitat

The death cap is native to Europe, where it is widespread. It is found from the southern coastal regions of Scandinavia in the north, to Ireland in the west, east to Poland and western Russia, and south throughout the Balkans, in Greece, Italy, Spain, and Portugal in the Mediterranean basin, and in Morocco and Algeria in north Africa. In west Asia, it has been reported from forests of northern Iran. There are records from further east in Asia but these have yet to be confirmed as A. phalloides.
By the end of the 19th century, Charles Horton Peck had reported A. phalloides in North America. In 1918, samples from the eastern United States were identified as being a distinct though similar species, A. brunnescens, by George Francis Atkinson of Cornell University. By the 1970s, it had become clear that A. phalloides does occur in the United States, apparently having been introduced from Europe alongside chestnuts, with populations on the West and East Coasts. A 2006 historical review concluded the East Coast populations were inadvertently introduced, likely on the roots of other purposely imported plants such as chestnuts. The origins of the West Coast populations remained unclear, due to scant historical records, but a 2009 genetic study provided strong evidence for the introduced status of the fungus on the west coast of North America. Observations of various collections of A. phalloides, from conifers rather than native forests, have led to the hypothesis that the species was introduced to North America multiple times. It is hypothesized that the various introductions led to multiple genotypes which are adapted to either oaks or conifers.
A. phalloides were conveyed to new countries across the Southern Hemisphere with the importation of hardwoods and conifers in the late twentieth century. Introduced oaks appear to have been the vector to Australia and South America; populations under oaks have been recorded from Melbourne, Canberra, Adelaide, and further observed by citizen scientists in Beechworth, Sydney and Albury.
It has been recorded under other introduced trees in Argentina. Pine plantations are associated with the fungus in Tanzania and South Africa, found under oaks and poplars in Chile, as well as Uruguay.
A number of deaths in India have been attributed to it.