Fuligo septica

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Dog vomit slime mold (Jasmine)
Fuligo septica - Gelbe Lohblute - Hexenbutter - 02.jpg
Fuligo septica as white/yellow plasmodium
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Phylum: Amoebozoa
Class: Myxogastria
Order: Physarales
Family: Physaraceae
Genus: Fuligo
Species:
F. septica
Binomial name
Fuligo septica
(L.) F.H.Wigg (1780)
Synonyms [1]
  • Mucor septicusL. (1763)
  • Reticularia septica(L.) With. (1792)
  • Aethalium septicum(L.) Fr. (1829)

Fuligo septica is a species of slime mold in the class Myxomycetes. It is commonly known as scrambled egg slime or flowers of tan [2] because of its peculiar yellowish appearance. It is also known as dog vomit slime mold or Jasmine mold and is relatively common with a worldwide distribution, often being found on bark mulch in urban areas after heavy rain or excessive watering. Their spores are produced on or in aerial sporangia and are spread by wind.

History and taxonomy

The first description of the species was provided by French botanist Jean Marchant in 1727, who referred to it as "fleur de tan" (bark flower); Marchant also classified it as "des éponges" (one of the sponges). [3] Carl Linnaeus called it Mucor septicus in his 1763 Species Plantarum . [4] The species was transferred to the genus Fuligo by German botanist Friedrich Heinrich Wiggers in 1780. [5]

Description and habitat

Like many slime molds, the cells of this species typically aggregate to form a plasmodium, a multinucleate mass of undifferentiated cells that may move in an ameboid-like fashion during the search for nutrients. F. septica's plasmodium may be anywhere from white to yellow-gray, [6] typically 2.5–20 cm (1.0–7.9 in) in diameter, and 1–3 cm (0.4–1.2 in) thick. [7] The plasmodium eventually transforms into a sponge-like aethalium, analogous to the spore-bearing fruiting body of a mushroom; which then degrades, darkening in color, and releases its dark-colored spores. F. septica produces the largest aethalium of any slime mold. [8] This species is known to have its spores dispersed by beetles (family Latridiidae). [9]

The spores have a two-layered wall, with a dense outer layer with spines, and a fibrous inner layer. During germination, the outer layer splits to create an opening, and more elastic inner layer ruptures later as protoplasm emerges. A remnant of the inner layer may be persistent and adhere to the protoplast after it has emerged from the spore. A peroxidase enzyme present in the inner cell wall plays a role in germination. [10]

Fuligo septica grows on rotten wood and plant debris, but can also grow on the leaves and stems of living plants. [11]

Resistance to metal toxicity

Slime molds have a high resistance to toxic levels of metals; one author was prompted to write "The levels of zinc in Fuligo septica were so high (4,000–20,000 ppm) that it is difficult to understand how a living organism can tolerate them." [12] The resistance to extreme levels of zinc appears to be unique to F. septica. [13] The mechanism of this metal resistance is now understood: F. septica produces a yellow pigment called fuligorubin A, which has been shown to chelate metals and convert them to inactive forms. [14]

Bioactive compounds

Extracts from F. septica show antibiotic activity against Bacillus subtilis and Candida albicans , and cytotoxic activity on KB cells (a cell line derived from a human carcinoma of the nasopharynx). [15]

Fuligo septica contains a yellow pigment called fuligorubin A that is thought to be involved in photoreception and in the process of energy conversion during its life cycle. [16] In 2011 a Japanese research group reported isolating and characterizing a new chlorine-containing yellow pigment from a specific strain of the organism that they called dehydrofuligoic acid. [17]

Relationship to humans

Folklore

In Scandinavian folklore, Fuligo septica is identified as the vomit of troll cats. [18]

In Finland, F. septica was believed to be used by witches to spoil their neighbors' milk. This gives it the name paranvoi, meaning "butter of the familiar spirit". [8] [19] In Dutch, "heksenboter" refers to "witches' butter". In Latvian, the slime mold (amongst other slime molds) is called "ragansviests" as "witches' butter" or "raganu spļāviens" as "witches' spit" but it is unclear about the origins of these names.

Human pathogenicity

The species is known to trigger episodes of asthma and allergic rhinitis in susceptible people. [20] [21]

Model of RNA processing

Introns are sections of DNA that must be properly cleaved, digested and processed prior to rendering functional mRNAs for protein synthesis. Because it has a large number of group I introns, F. septica is used as a model to understand the processing and evolution of RNA. [22] [23]

Related Research Articles

<span class="mw-page-title-main">Slime mold</span> Spore-forming organisms

Slime mold or slime mould is an informal name given to a polyphyletic assemblage of unrelated eukaryotic organisms in the Stramenopiles, Rhizaria, Discoba, Amoebozoa and Holomycota clades. Most are microscopic; those in the Myxogastria form larger plasmodial slime molds visible to the naked eye. The slime mold life cycle includes a free-living single-celled stage and the formation of spores. Spores are often produced in macroscopic multicellular or multinucleate fruiting bodies that may be formed through aggregation or fusion; aggregation is driven by chemical signals called acrasins. Slime molds contribute to the decomposition of dead vegetation; some are parasitic.

<span class="mw-page-title-main">Mold</span> Wooly, dust-like fungal structure or substance

A mold or mould is one of the structures that certain fungi can form. The dust-like, colored appearance of molds is due to the formation of spores containing fungal secondary metabolites. The spores are the dispersal units of the fungi. Not all fungi form molds. Some fungi form mushrooms; others grow as single cells and are called microfungi.

<span class="mw-page-title-main">Spore</span> Unit of reproduction adapted for dispersal and survival in unfavorable conditions

In biology, a spore is a unit of sexual or asexual reproduction that may be adapted for dispersal and for survival, often for extended periods of time, in unfavourable conditions. Spores form part of the life cycles of many plants, algae, fungi and protozoa. They were thought to have appeared as early as the mid-late Ordovician period as an adaptation of early land plants.

<span class="mw-page-title-main">Mycetozoa</span> Infraphylum of protists

Mycetozoa is a polyphyletic grouping of slime molds. It was originally thought to be a monophyletic clade, but recently it was discovered that protostelia are a polyphyletic group within Conosa.

<span class="mw-page-title-main">Amoebozoa</span> Phylum of protozoans

Amoebozoa is a major taxonomic group containing about 2,400 described species of amoeboid protists, often possessing blunt, fingerlike, lobose pseudopods and tubular mitochondrial cristae. In traditional classification schemes, Amoebozoa is usually ranked as a phylum within either the kingdom Protista or the kingdom Protozoa. In the classification favored by the International Society of Protistologists, it is retained as an unranked "supergroup" within Eukaryota. Molecular genetic analysis supports Amoebozoa as a monophyletic clade. Modern studies of eukaryotic phylogenetic trees identify it as the sister group to Opisthokonta, another major clade which contains both fungi and animals as well as several other clades comprising some 300 species of unicellular eukaryotes. Amoebozoa and Opisthokonta are sometimes grouped together in a high-level taxon, variously named Unikonta, Amorphea or Opimoda.

<i>Fuligo</i> Genus of slime moulds

Fuligo is a widespread genus of plasmodial slime mold in the family Physaraceae. These organisms are protozoans rather than fungi, but for historical reasons are sometimes treated as part of mycology.

<i>Physarum polycephalum</i> Species of slime mold, model organism

Physarum polycephalum, an acellular slime mold or myxomycete popularly known as "the blob", is a protist with diverse cellular forms and broad geographic distribution. The “acellular” moniker derives from the plasmodial stage of the life cycle: the plasmodium is a bright yellow macroscopic multinucleate coenocyte shaped in a network of interlaced tubes. This stage of the life cycle, along with its preference for damp shady habitats, likely contributed to the original mischaracterization of the organism as a fungus. P. polycephalum is used as a model organism for research into motility, cellular differentiation, chemotaxis, cellular compatibility, and the cell cycle.

<i>Lycogala epidendrum</i> Species of slime mould

Lycogala epidendrum, commonly known as wolf's milk or groening's slime, is a cosmopolitan species of myxogastrid amoeba which is often mistaken for a fungus. The aethalia, or fruiting bodies, occur either scattered or in groups on damp rotten wood, especially on large logs, from June to November. These aethalia are small, pink to brown cushion-like blobs. They may ooze a pink "paste" if the outer wall is broken before maturity. When mature, the colour tends to become more brownish. When not fruiting, single celled individuals move about as very small, red amoeba-like organisms called plasmodia, masses of protoplasm that engulf bacteria, as well as fungal and plant spores, protozoa, and particles of non-living organic matter through phagocytosis.

Multinucleate cells are eukaryotic cells that have more than one nucleus per cell, i.e., multiple nuclei share one common cytoplasm. Mitosis in multinucleate cells can occur either in a coordinated, synchronous manner where all nuclei divide simultaneously or asynchronously where individual nuclei divide independently in time and space. Certain organisms may have a multinuclear stage of their life cycle. For example, slime molds have a vegetative, multinucleate life stage called a plasmodium.

<span class="mw-page-title-main">Myxogastria</span> Group of slime molds

Myxogastria/Myxogastrea or Myxomycetes (ICN) is a class of slime molds that contains 5 orders, 14 families, 62 genera, and 888 species. They are colloquially known as the plasmodial or acellular slime moulds.

<span class="mw-page-title-main">Trichiales</span> Order of slime moulds

Trichiales is an order of slime moulds in the phylum Amoebozoa. Trichiales is one of five orders in the group Myxomycetes, or the true plasmodial slime molds. It is also currently categorized under the superorder Lucisporidia with its sister group, Liceales. The order was first described by Thomas MacBride in 1922, and has retained the same name and status as a defined order in present phylogeny. In the plasmodium form, members of Trichiales lack a columella but have a well-developed capillitium for spore dispersal. The shape and details of the capillitium are used to define families within the order. Spores are brightly coloured, ranging from clear, white and yellow to pink and red-brown tones. The order currently has 4 families, 14 genera and 174 species. Recent molecular research has shown that while Trichiales probably represents a true taxonomic group, its sister group Liceales is likely paraphyletic, and it has been suggested that several genera from the Liceales should be reclassified under Trichiales instead.

<i>Ceratiomyxa</i> Genus of slime mould

Ceratiomyxa is a genus of plasmodial slime mould within the Eumycetozoa, first described by Pier Antonio Micheli. They are widely distributed and commonly found on decaying wood.

Fonticula is a genus of cellular slime mold which forms a fruiting body in a volcano shape. As long ago as 1979 it has been known to not have a close relationship with either the Dictyosteliida or the Acrasidae, the two well-established groups of cellular slime molds. In 1979, Fonticula was made a new genus of its own due to the unique characteristics of its fruiting body, with only one species: Fonticula alba.

<i>Enteridium lycoperdon</i> Slime mold

Enteridium lycoperdon, the false puffball, is one of the more obvious species of slime mould or Myxogastria, typically seen in its reproductive phase as a white 'swelling' on standing dead trees in the spring, or on large pieces of fallen wood. Alder is a common host.

<i>Brefeldia maxima</i> Species of slime mould

Brefeldia maxima is a species of non-parasitic plasmodial slime mold, and a member of the class Myxomycetes. It is commonly known as the tapioca slime mold because of its peculiar pure white, tapioca pudding-like appearance. A common species with a worldwide distribution, particularly in North America and Europe. It is often found on bark after heavy rain or excessive watering. Their spores are produced on or in aerial sporangia and are spread by wind, however beetles of the family Latridiidae are also reported to disperse the spores. Bonner states that soil invertebrates and rain mainly disperse spores as they are sticky and unlikely to be carried by air currents.

<span class="mw-page-title-main">Hypothallus</span>

In true slime molds (myxogastria), lichens, and in species of the family Clavicipitaceae, the hypothallus is the layer on which the fruit body sits, lying in contact with the substrate. The word is derived from the Ancient Greek root hypó ("under") and thallós.

<i>Hemitrichia</i> Genus of slime moulds

Hemitrichia is a genus of slime molds, of the family Trichiidae, found within the order Trichiida. It was first described by Josef Rostafinski in 1873 and remains a well-defined genus of the slime molds. Hemitrichia species exhibit either plasmodiocarp or sporangium fruiting bodies, both of which are well-known and recognizable slime molds seen on multiple continents. The genus includes Hemtrichia serpula, known as the pretzel slime mold, an iconic and widespread species that has been used to examine speciation in slime molds.

<i>Elaeomyxa</i> Genus of slime moulds

Elaeomyxa is a genus of slime molds in the family Lamprodermataceae. As of May 2022, there are four known species in the genus. Species in this genus have been documented in North America, Eurasia, Africa, and Australasia.

<span class="mw-page-title-main">Glossary of mycology</span>

This glossary of mycology is a list of definitions of terms and concepts relevant to mycology, the study of fungi. Terms in common with other fields, if repeated here, generally focus on their mycology-specific meaning. Related terms can be found in glossary of biology and glossary of botany, among others. List of Latin and Greek words commonly used in systematic names and Botanical Latin may also be relevant, although some prefixes and suffixes very common in mycology are repeated here for clarity.

References

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  2. Young, A.M. (2005). A Field Guide to the Fungi of Australia. University of New South Wales Press Ltd. ISBN   9780868407425.
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  4. Linnaeus C. (1763). Species Plantarum. Vol. v.2 (2nd ed.). Stockholm: Impensis Direct. Laurentii Salvii. p. 1656.
  5. Wiggers FH, Weber GH (1780). Primitiae Florae Holsaticae (in Latin). Litteris Mich. Frider. Bartschii Acad. Typogr. p. 112.
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  10. Stempen H, Evans RC (1982). "Behavior of the inner wall layer of the germinating Fuligo septica spore: evidence of peroxidase activity". Mycologia. 74 (1): 26–35. doi:10.2307/3792625. JSTOR   3792625.
  11. Healy RA; Huffman DR; Tiffany LH; Knaphaus G (2008). Mushrooms and Other Fungi of the Midcontinental United States (Bur Oak Guide). Iowa City, Iowa: University of Iowa Press. p. 340. ISBN   978-1-58729-627-7.
  12. Setala A, Nuorteva P (1989). "High metal contents found in Fuligo septica L. Wiggers and some other slime molds (Myxomycetes)". Karstenia. 29 (1): 37–44. doi: 10.29203/ka.1989.273 .
  13. Zhulidov DA, Robarts RD, Zhulidov AV, Zhulidova OV, Markelov DA, Rusanov VA, Headley JV (2002). "Zinc accumulation by the slime mold Fuligo septica (L.) Wiggers in the former Soviet Union and North Korea". Journal of Environmental Quality. 31 (3): 1038–42. Bibcode:2002JEnvQ..31.1038Z. doi:10.2134/jeq2002.1038. PMID   12026071.[ permanent dead link ]
  14. Latowski D, Lesiak A, Jarosz-Krzeminska E, Strzalka K (2008). "Fuligo septica, as a new model organism in studies on interaction between metal ions and living cells". Metal Ions in Biology and Medicine and Medicine. 10: 204–9.
  15. Pereira EC; Cavalcanti LDH; Campos-Takaki GMD; Nascimento; Silene CD (1992). "Antibiotic and cytotoxic activities of crude extracts from Fuligo septica (L.) Wigg. and Tubifera microsperma (Berk. and Curt.) Martin (Myxomycetes)". Revista de Ciencias Biomedicas (13): 23–32.
  16. Rahman A. (1988). Studies in Natural Products Chemistry. Amsterdam: Elsevier. pp. 237–8. ISBN   0-444-51510-0.
  17. Shintani A, Toume K, Yamamoto Y, Ishibashi M (2010). "Dehydrofuligoic acid, a new yellow pigment isolated from the myxomycete Fuligo septica f. flava". Heterocycles. 82 (1): 839–42. doi:10.3987/com-10-s(e)18 (inactive 2024-02-17). ISSN   0385-5414.{{cite journal}}: CS1 maint: DOI inactive as of February 2024 (link)
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  20. Santili J, Rockwell WJ, Collins RP (1895). "The significance of the spore of the Basidiomycetes (mushrooms and their allies) in bronchial asthma and allergenic rhinitis". Annals of Allergy. 55 (3): 469–71. PMID   4037433.
  21. Gianini EH, Northy WT, Leathers CR (1975). "The allergenic significance of certain fungi rarely reported as allergens". Annals of Allergy. 35 (6): 372–6. PMID   1239229.
  22. Lundblad EW, Einvik C, Rønning S, Haugli K, Johansen S (2004). "Twelve Group I introns in the same pre-rRNA transcript of the myxomycete Fuligo septica: RNA processing and evolution". Molecular Biology and Evolution. 21 (7): 1283–93. doi: 10.1093/molbev/msh126 . PMID   15034133.
  23. Haugen P, Coucheron DH, Rønning SB, Haugli K, Johansen S (2003). "The molecular evolution and structural organization of self-splicing group I introns at position 516 in nuclear SSU rDNA of myxomycetes". Journal of Eukaryotic Microbiology. 50 (4): 283–92. doi:10.1111/j.1550-7408.2003.tb00135.x. PMID   15132172. S2CID   19835141.
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