Amanita bisporigera

Amanita bisporigera is a deadly poisonous species of fungus in the family Amanitaceae. It is commonly known as the eastern North American destroying angel or just as the destroying angel, although the fungus shares this latter name with three other lethal white Amanita species, A. ocreata, A. verna and A. virosa. The fruit bodies are found on the ground in mixed coniferous and deciduous forests of eastern North America south to Mexico, but are rare in western North America; the fungus has also been found in pine plantations in Colombia. The mushroom has a smooth white cap that can reach up to 10 cm (4 in) across, and a stipe, up to 14 cm (5.5 in) long by 1.8 cm (0.7 in) thick, that has a delicate white skirt-like ring near the top. The bulbous stipe base is covered with a membranous sac-like volva. The white gills are free from attachment to the stalk and crowded closely together. As the species name suggests, A. bisporigera typically bears two spores on the basidia, although this characteristic is not as immutable as was once thought. Amanita bisporigera was described as a new species in 1906. It is classified in the section Phalloideae of the genus Amanita together with other amatoxin-containing species. Amatoxins are cyclic peptides which inhibit the enzyme RNA polymerase II and interfere with various cellular functions. The first symptoms of poisoning appear 6 to 24 hours after consumption, followed by a period of apparent improvement, then by symptoms of liver and kidney failure, and death after four days or more. Amanita bisporigera closely resembles a few other white amanitas, including the equally deadly A. virosa and A. verna. These species, difficult to distinguish from A. bisporigera based on visible field characteristics, do not have two-spored basidia, and do not stain yellow when a dilute solution of potassium hydroxide is applied. The DNA of A. bisporigera has been partially sequenced, and the genes responsible for the production of amatoxins have been determined. Amanita bisporigera was first described scientifically in 1906 by American botanist George Francis Atkinson in a publication by Cornell University colleague Charles E. Lewis. The type locality was Ithaca, New York, where several collections were made. In his 1941 monograph of world Amanita species, Édouard-Jean Gilbert transferred the species to his new genus Amanitina, but this genus is now considered synonymous with Amanita. In 1944, William Murrill described the species Amanita vernella, collected from Gainesville, Florida; that species is now thought to be synonymous with A. bisporigera after a 1979 examination of its type material revealed basidia that were mostly 2-spored. Amanita phalloides var. striatula, a poorly known taxon originally described from the United States in 1902 by Charles Horton Peck, is considered by Amanita authority Rodham Tulloss to be synonymous with A. bisporigera. Vernacular names for the mushroom include 'destroying angel', 'deadly amanita', 'white death cap', 'angel of death' and 'eastern North American destroying angel'. Amanita bisporigera belongs to section Phalloideae of the genus Amanita, which contains some of the deadliest Amanita species, including A. phalloides and A. virosa. This classification has been upheld with phylogenetic analyses, which demonstrate that the toxin-producing members of section Phalloideae form a clade—that is, they derive from a common ancestor. In 2005, Zhang and colleagues performed a phylogenetic analysis based on the internal transcribed spacer (ITS) sequences of several white-bodied toxic Amanita species, most of which are found in Asia. Their results support a clade containing A. bisporigera, A. subjunquillea var. alba, A. exitialis, and A. virosa. The Guangzhou destroying angel (Amanita exitialis) has two-spored basidia, like A. bisporigera. The cap is 3–10 cm (1.2–3.9 in) in diameter and, depending on its age, ranges in shape from egg-shaped to convex to somewhat flattened. The cap surface is smooth and white, sometimes with a pale tan- or cream-colored tint in the center. The surface is either dry or, when the environment is moist, slightly sticky. The flesh is thin and white, and does not change color when bruised. The margin of the cap, which is rolled inwards in young specimens, does not have striations (grooves), and lacks volval remnants. The gills, also white, are crowded closely together. They are either free from attachment to the stipe or just barely reach it. The lamellulae (short gills that do not extend all the way to the stipe) are numerous, and gradually narrow. The white stipe is 6–14 cm (2.4–5.5 in) by 0.7–1.8 cm (0.3–0.7 in) thick, solid (i.e., not hollow), and tapers slightly upward. The surface, in young specimens especially, is frequently floccose (covered with tufts of soft hair), fibrillose (covered with small slender fibers), or squamulose (covered with small scales); there may be fine grooves along its length. The bulb at the base of the stipe is spherical or nearly so. The delicate ring on the upper part of the stipe is a remnant of the partial veil that extends from the cap margin to the stalk and covers the gills during development. It is white, thin, membranous, and hangs like a skirt. When young, the mushrooms are enveloped in a membrane called the universal veil, which stretches from the top of the cap to the bottom of the stipe, imparting an oval, egg-like appearance. In mature fruit bodies, the veil's remnants form a membrane around the base, the volva, like an eggshell-shaped cup. On occasion, however, the volva remains underground or gets torn up during development. It is white, sometimes lobed, and may become pressed closely to the stipe. The volva is up to 3.8 cm (1.5 in) in height (measured from the base of the bulb), and is about 2 mm thick midway between the top and the base attachment. The mushroom's odor has been described as 'pleasant to somewhat nauseous', becoming more cloying as the fruit body ages. The cap flesh turns yellow when a solution of potassium hydroxide (KOH, 5–10%) is applied (a common chemical test used in mushroom identification). This characteristic chemical reaction is shared with A. ocreata and A. virosa, although some authors have expressed doubt about the identity of North American A. virosa, suggesting those collections may represent four-spored A. bisporigera. Tulloss suggests that reports of A. bisporigera that do not turn yellow with KOH were actually based on white forms of A. phalloides. Findings from the Chiricahua Mountains of Arizona and in central Mexico, although 'nearly identical' to A. bisporigera, do not stain yellow with KOH; their taxonomic status has not been investigated in detail. The spore print of A. bisporigera, like most Amanita, is white. The spores are roughly spherical, thin-walled, hyaline (translucent), amyloid, and measure 7.8–9.6 by 7.0–9.0 μm. The cap cuticle is made of partially gelatinized, filamentous interwoven hyphae, 2–6 μm in diameter. The tissue of the gill is bilateral, meaning it diverges from the center of the gill to its outer edge. The subhymenium is ramose—composed of relatively thin branching, unclamped hyphae. The spore-bearing cells, the basidia, are club-shaped, thin-walled, without clamps, with dimensions of 34–45 by 4–11 μm. They are typically two-spored, although rarely three- or four-spored forms have been found. Although the two-spored basidia are a defining characteristic of the species, there is evidence of a tendency to shift towards producing four-spored basidia as the fruiting season progresses. The volva is composed almost exclusively of densely interwoven filamentous hyphae, 2–10 μm in diameter, that are sparsely to moderately branched. There are few small inflated cells, which are mostly spherical to broadly elliptic. The tissue of the stipe is made of abundant, sparsely branched, filamentous hyphae, without clamps, measuring 2–5 μm in diameter. The inflated cells are club-shaped, longitudinally oriented, and up to 2–3 by 15.7 μm. The annulus is made of abundant moderately branched filamentous hyphae, measuring 2–6 μm in diameter. The inflated cells are sparse, broadly elliptic to pear-shaped, and are rarely larger than 31 by 22 μm. Pleurocystidia and cheilocystidia (cystidia found on the gill faces and edges, respectively) are absent, but there may be cylindrical to sac-like cells of the partial veil on the gill edges; these cells are hyaline and measure 24–34 by 7–16 μm. In 1906 Charles E. Lewis studied and illustrated the development of the basidia in order to compare the nuclear behavior of the two-spored with that of the four-spored forms. Initially (1), the young basidium, appearing as a club-shaped branch from the subhymenium, is filled with cytoplasm and contains two primary nuclei, which have distinct nucleoli. As the basidium grows larger, the membranes of the two nuclei contact (2), and then the membrane disappears at the point of contact (3). The two primary nuclei remain distinct for a short time, but eventually the two nuclei fuse completely to form a larger secondary nucleus with a single secondary nucleolus (4, 5). The basidium increases in size after the primary nuclei fuse, and the nucleus migrates towards the end of the basidia (6, 7). During this time, the nucleus develops vacuoles 'filled by the nuclear sap in the living cell'. Chromosomes are produced from the nucleolar threads, and align transversely near the apex of the basidium, connected by spindles (8–10). The chromosomes then move to the poles, forming the daughter nuclei that occupy different positions in the basidium; the daughters now have a structure similar to that of the parent nuclei (11). The two nuclei then divide to form four nuclei, similar to fungi with four-spored basidia (12, 13). The four nuclei crowd together at some distance from the end of the basidium to form an irregular mass (14). Shortly thereafter, the sterigmata (slender projections of the basidia that attach the spores) begin to form (15), and cytoplasm begins to pass through the sterigmata to form the spores (16). Although Lewis was not able to clearly determine from observation alone whether the contents of two or four nuclei passed through the sterigmata, he deduced, by examining older basidia with mature spores, that only two nuclei enter the spores (16, 17).