Gasteroid fungi

The puffball Lycoperdon perlatum - Germany

The gasteroid fungi are a group of fungi in the Basidiomycota. Species were formerly placed in the obsolete class Gasteromycetes Fr. (literally "stomach fungi"), or the equally obsolete order Gasteromycetales Rea, because they produce their spores inside their basidiocarps (fruit bodies) rather than on an outer surface.[1] The class is artificial, however, since specieswhich include puffballs, earthstars, stinkhorns, and false trufflesare not closely related to each other. Because they are often studied as a group, it has been convenient to retain the informal (non-taxonomic) name of "gasteroid fungi".

History

Devil's fingers, Clathrus archeri, emerging from its gasteroid 'eggs'

Several gasteroid fungisuch as the stinkhorn, Phallus impudicus L.were formally described by Linnaeus in his original Species Plantarum of 1753, but the first critical treatment of the group was by Christiaan Hendrik Persoon in his Synopsis methodica fungorum of 1801.[2] Until 1981, this book was the starting point for the naming of Gasteromycetes under the International Code of Nomenclature for algae, fungi, and plants. Although the starting point was subsequently put back to 1753, names of gasteroid fungi used in Persoon's book are still sanctioned and cannot be replaced by earlier names.[3] Elias Magnus Fries introduced the name Gasteromycetes for a class of fungi in his Systema Mycologicum of 1821, although (not using a microscope) he included many species of the Ascomycota (such as truffles) within the class. Fries contrasted the Gasteromycetes with the Hymenomycetes, where spores are produced externally on gills, pores, and other surfaces.[4]

This convenient division continued to be used for the next 150 years or so, although by the middle of the twentieth century it had become evident that Gasteromycetes was an artificial class (bringing together a miscellany of unrelated species) and not a natural one. In a 1995 study of British species, Pegler, et al. noted that "these fungi represent an heterogeneous assemblage, a mixture of forms which are derived from various lineages...[they] can be collectively referred to as gasteroid fungi, but they cannot be classified as a single group."[5] DNA-based systematic research has, not unexpectedly, confirmed the diversity of the gasteroid fungi.[6][7][8] According to a 2011 estimate, gasteroid fungi comprise about 8.4% of the known Agaricomycetes.[9]

Description and genera

The berry-like red-pouch fungus, Leratiomyces erythrocephalus, New Zealand

The gasteroid fungi form visibly diverse fruit bodies, but in all cases the spores are formed and reach maturity internally. They are not discharged forcibly, as in agarics and most other members of the Basidiomycota, but are released passively in a variety of different ways.[5]

In the puffballs, which include the genera Lycoperdon, Bovista, and Calvatia, spores are formed within spherical to pestle-shaped fruit bodies and are released either by wind (as the fruit body wears away, exposing the spore mass inside) or by raindrops. In the latter case, the fruit bodies develop an ostiole (apical hole) through which spores are puffed out by the pressure of raindrops falling on the fruit body surface. The same ingenious mechanism has evolved separately in the earthstars (Geastrum species), which have a hard outer layer to the fruitbody that splits open in a star-like manner to reveal the puffball-like spore sack.[10]

The stinkhorns and their allies, including the genera Phallus, Mutinus, Clathrus, and Lysurus, form spores within internally gelatinous, puffball-like 'eggs'. At maturity the eggs split and various strange spore-receptacles emerge. The spores are coated with an evil-smelling slime that attracts fliesthese being the agents of dispersal.[11]

The bird's nest fungi, which include the genera Cyathus and Crucibulum, form miniature, egg-like packets of spores within cup-shaped fruit bodies. These packets of spores are ejected by rain-splash and may land some distance away, the packets gradually wearing away to release the spores themselves.[12]

False truffles in such genera as Rhizopogon, Hymenogaster, and Melanogaster develop underground or at the soil surface. As with the true truffles, some of them have distinctive smells and are actively hunted out by small mammals which may consume them and spread their spores.[5] Some New Zealand secotioid fungi in the genus Leratiomyces are shaped and coloured like berries and their spores may be dispersed by ground-dwelling birds.[13]

Habitat and distribution

Podaxis pistillaris, a gasteroid fungus adapted to arid conditions

Most gasteroid fungi are saprotrophic, living on dead plant material, including very rotten, fallen wood.

The earthballs (Scleroderma species), dyeballs (Pisolithus species), and many false truffles are ectomycorrhizal, forming a mutually beneficial relationship with the roots of living trees.[14]

These species are cosmopolitan, but the stinkhorns and their allies are most diverse in the wet tropics.[15]

Producing spores in an enclosed fruit body is a suitable adaptation for growing in arid conditions. Several genera, including Podaxis, Battarrea, Phellorinia, and Tulostoma, are typical of steppes and deserts, some also occurring in sand dunes in temperate zones.[16]

References

  1. Kirk PM. et al. (2008). Dictionary of the fungi 10th edition. Wallingford: CABI ISBN 978-0-85199-826-8
  2. Persoon CH. (1801) Synopsis methodica fungorum
  3. McNeill J. et al. (2006). International Code of Botanical Nomenclature (Vienna Code): Article13.1.d Archived October 6, 2012, at the Wayback Machine.
  4. Fries EM. (1821). Systema Mycologicum.
  5. 1 2 3 Pegler DN et al. (1995). British puffballs, earthstars and stinkhorns: an account of the British gasteroid fungi. Kew: Royal Botanic Gardens ISBN 0-947643-81-8
  6. Hibbett DS, et al. (1997). "Evolution of gilled mushrooms and puffballs inferred from ribosomal DNA sequences". Proceedings of the National Academy of Sciences. 94: 12002–12006. PMC 23683Freely accessible. PMID 9342352. doi:10.1073/pnas.94.22.12002.
  7. Kruger D, et al. (2001). "The Lycoperdales. A molecular approach to the systematics of some gasteroid mushrooms". Mycologia. 93: 947–957. doi:10.2307/3761759.
  8. Binder M, Bresinsky A (2002). "Derivation of a polymorphic lineage of gasteromycetes from boletoid ancestors". Mycologia. 94: 85–98. PMID 21156480. doi:10.2307/3761848.
  9. Wilson AW, Binder M, Hibbett DS (2011). "eEffects of gasteroid fruiting body morphology on diversification rates in three independent clades of fungi estimated using binary state speciation and extinction analysis". Evolution. 65 (5): 1305–1322. PMID 21166793. doi:10.1111/j.1558-5646.2010.01214.x.
  10. Miller, 1988, pp. 36–47.
  11. Miller, 1988, p. 75.
  12. Miller, 1988, p. 69.
  13. Beever RE. (1993). Dispersal of truffle-like fungi in New Zealand, in Hill RS. (ed.) Southern Temperate Ecosystems: Origin and Diversification 22. Hobart, Australia.
  14. Miller, 1988, p. 61.
  15. Dring DM. (1980). Contributions towards a rational arrangement of the Clathraceae. Kew: Royal Botanic Gardens.
  16. Miller, 1988, p. 48.

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