Biology:Prototaxites

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Short description: Extinct genus of fungi

Prototaxites
Temporal range: Late Silurian–Famennian
Possible record from Darriwilian
Prototaxites apex.jpg
Branching apex of P. loganii, "Schunnemunk tree"
Scientific classification e
Domain: Eukaryota
Kingdom: Fungi
Stem group: Ascomycota
Family: Prototaxitaceae
Hueber
Genus: Prototaxites
Dawson 1859
Type species
Prototaxites loganii
Dawson, 1859
Species
  • P. caledonicus (Lang 1926) Schmidt & Teichmüller 1954
  • P. clevelandensis Chitaley 1992b
  • P. forfarensis (Kidston 1897) Pia
  • P. hicksii (Etheridge 1881) Dawson 1881
  • P. honeggeri Retallack 2019
  • P. loganii Dawson, 1859
  • P. ortoni (Penhallow 1896)
  • P. psygmophylloides Kräusel & Weyland 1930 ex Kräusel & Weyland 1931
  • P. saharianum (Chiarugi 1934)
  • P. southworthii Arnold, 1952
  • P. storriei (Barber 1892)
  • P. taiti (Kidston & Lang 1921)
Synonyms
  • Celluloxylon Dawson 1881
  • Germanophyton Høeg 1942
  • Nematophycus Carruthers 1872
  • Nematophyton Dawson 1888
  • Nematoxylon Dawson 1863

Prototaxites /ˌprtˈtæksɪtz/ is an extinct genus of terrestrial fossil fungi dating from the Late Silurian until the Late Devonian periods.[1][2] Prototaxites formed large trunk-like structures up to 1 metre (3 ft) wide, reaching 8 metres (26 ft) in length,[3] made up of interwoven tubes around 50 micrometres (0.0020 in) in diameter, making it by far the largest land-dwelling organism of its time.

The taxonomy of Prototaxites has long been the subject of debate. Currently, it is widely considered a fungus, but the debate is ongoing. [3] Its exact relationship with extant fungus lineages is uncertain. It was almost certainly a perennial organism that grew over multiple years. Several ecologies have been proposed, including that it was saprotrophic like many modern fungi, or that it was a lichenised autotroph.[1]

Morphology

thumb|left|upright|Dawson's 1888 reconstruction of a conifer-like Prototaxites

The microstructure of Prototaxites under a light microscope
P. milwaukeensis from Wisconsin

File:Prototaxites phycobiont.tif With a diameter of up to 1 metre (3 ft 3 in), and a height reaching 8.8 metres (29 ft), Prototaxites fossils are remnants of by far the largest organism discovered from the period of its existence. Viewed from afar, the fossils take the form of tree-trunks, spreading slightly near their base in a fashion that suggests a connection to unpreserved root-like structures.[4] Infilled casts which may represent the spaces formerly occupied by "roots" of Prototaxites are common in early Devonian strata.[5] Concentric growth rings, sometimes containing embedded plant material,[6] suggest that the organism grew sporadically by the addition of external layers. It is probable that the preserved "trunks" represent the fruiting body, or "sporophore", of a fungus, which would have been fuelled by a mycelium, a net of dispersed filaments ("hyphae"). On a microscopic scale, the fossils consist of narrow tube-like structures, which weave around one another. These come in two types: skeletal "tubes", 20–50 μm across, have thick (2–6 μm) walls and are undivided for their length, and generative "filaments", which are thinner (5–10 μm diameter) and branch frequently; these mesh together to form the organism's matrix. These thinner filaments are septate—that is to say, they bear internal walls. These septa are perforate—i.e. they contain a pore, a trait only present in the modern red algae and fungi.[7]

The similarity of these tubes to structures in the early plant Nematothallus has led to suggestions that the latter may represent leaves of Prototaxites. Unfortunately for this hypothesis, the two have never been found in connection, although this may be a consequence of their detachment after the organisms' death.[8]

History of research

First collected in 1843,[9] it was not until 14 years later that John William Dawson, a Canadian scientist, studied Prototaxites fossils, which he described as partially rotten giant conifers, containing the remains of the fungi which had been decomposing them.[10][11][6] This concept was not disputed until 1872, when the rival scientist William Carruthers poured ridicule on the idea.[12] Such was his fervour that he rebuked the name Prototaxites (loosely translated as "first yew"[13]) and insisted that the name Nematophycus ("stringy alga[14]") be adopted,[6] a move strongly against scientific convention.[15] Dawson fought adamantly to defend his original interpretation until studies of the microstructure made it clear that his position was untenable, whence he promptly attempted to rename the genus himself (to Nematophyton, "stringy plant"), denying with great vehemence that he'd ever considered it to be a tree.[6] Despite these political attempts to rename the genus, the rules of botanical nomenclature mean that the name "Prototaxites", however inappropriate in meaning, remains in use today.

Despite the overwhelming evidence that the organism grew on land,[16][17] Carruthers's interpretation that it was a giant marine alga was challenged just the once, in 1919, when Church suggested that Carruthers had been too quick to rule out the possibility of the fungi.[18] The lack of any characters diagnostic of any extant group made the presentation of a firm hypothesis difficult;[6] the fossil remained an enigmatic mystery and subject of debate. It was not until 2001, after 20 years of research, that Francis Hueber, of Washington's National Museum of Natural History, published a long-awaited paper which attempted to put Prototaxites in its place. The paper deduced, based on its morphology, that Prototaxites was a fungus.[6]

This idea was received with disbelief, denial and strong scepticism, but further evidence is emerging to support it.[19] In 2007, isotopic analyses by a team including Hueber and Kevin Boyce of the University of Chicago[3] concluded that Prototaxites was a giant fungus. They detected a highly variable range of values of carbon isotope ratios in a range of Prototaxites specimens; autotrophs (organisms such as plants and algae, that make a living via photosynthesis) living at the same time draw on the same (atmospheric) source of carbon; as organisms of the same type share the same chemical machinery, they reflect this atmospheric composition with a constant carbon isotope trace. The inconsistent ratio observed in Prototaxites appears to show that the organism did not survive by photosynthesis, and Boyce's team deduced that the organism fed on a range of substrates, such as the remains of whichever other organisms were nearby.[3] Nevertheless, the large size of the organism would necessitate an extensive network of subterranean mycelia in order to obtain enough organic carbon to accumulate the necessary biomass. Root-like structures have circumstantially been interpreted as Prototaxites's rhizomorphs, and could support the possibility of the organism transporting nutrients large distances to support its above-ground body.[20]

Other recent research has suggested that Prototaxites represents a rolled-up bundle of liverworts,[21] but this interpretation has substantial difficulties.[22]

A similar genus, Nematasketum, also consists of banded and branching tubes in axial bundles; this seems to be a fungus.[23]

In 2021, Gregory Retallack described new species Prototaxites honeggeri from the Darriwilian (Middle Ordovician) age Douglas Lake Member of the Lenoir Limestone, at Douglas Dam, Tennessee, which makes the earliest appearance of this genus.[24] While Ordovician origin of this genus is mentioned by some study,[2] paleobotanist Dianne Edwards referred this study and commented "When diagnostic features are absent, such fragmentary organic materials can be misinterpreted, leading to implausible attributions".[25] Nelson and Boyce (2022) referred this study by Retallack, but considered appearance of genus is Late Silurian.[1]

A 2022 paper suggested that Prototaxites was a fungal rhizomorph that grew on its side and likely at least partially underground, as opposed to the traditional view that it grew upright.[2]

Ecological context

Prototaxites would have been the tallest living organism in its day by far. In comparison, the plant Cooksonia only reached 6 centimetres (2.4 in) and itself towered over the "moss forests". Invertebrates were the only other land-dwelling multi-cellular life. Prototaxites became extinct as vascular plants rose to prominence.[4] The organism could have used its tall columnar structure for spore dispersal. Alternatively, if Prototaxites contained photosynthetic structures, the height would have increased light capture.[4] The University of Chicago research team has it reconstructed as a branchless, columnar structure.[26] The presence of bio-molecules often associated with algae may suggest that the organism was covered by symbiotic (or parasitic) algae (making it in essence a huge lichen), or even that it was an alga itself.[4][27][28] However, the variability in the ratios of δ13C between specimens of Prototaxites suggest that it was heterotrophic.[1]

Prototaxites mycelia (strands) have been fossilised invading the tissue of vascular plants;[6] in turn, there is evidence of animals inhabiting Prototaxites: mazes of tubes have been found within some specimens, with the fungus re-growing into the voids, leading to speculation that the organisms' extinction may have been caused by such activity;[6] however, evidence of arthropod borings in Prototaxites has been found from the early and late Devonian, suggesting the organism survived the duress of boring for many millions of years.[29] Intriguingly, Prototaxites was bored long before plants developed a structurally equivalent woody stem, and it is possible that the borers transferred to plants when these evolved.[29]

References

  1. 1.0 1.1 1.2 1.3 Nelsen, Matthew P.; Boyce, C. Kevin (2022-07-01). "What to Do with Prototaxites ?" (in en). International Journal of Plant Sciences 183 (6): 556–565. doi:10.1086/720688. ISSN 1058-5893. https://www.journals.uchicago.edu/doi/10.1086/720688. 
  2. 2.0 2.1 2.2 Vajda, Vivi; Cavalcante, Larissa; Palmgren, Kristoffer; Krüger, Ashley; Ivarsson, Magnus (2022-12-13). "Prototaxites reinterpreted as mega-rhizomorphs, facilitating nutrient transport in early terrestrial ecosystems" (in en). Canadian Journal of Microbiology 69 (1): cjm–2021–0358. doi:10.1139/cjm-2021-0358. ISSN 0008-4166. PMID 36511419. 
  3. 3.0 3.1 3.2 3.3 Boyce, K.C.; Hotton, C.L.; Fogel, M.L.; Cody, G.D.; Hazen, R.M.; Knoll, A.H.; Hueber, F.M. (May 2007). "Devonian landscape heterogeneity recorded by a giant fungus". Geology 35 (5): 399–402. doi:10.1130/G23384A.1. Bibcode2007Geo....35..399B. http://geology.geoscienceworld.org/cgi/reprint/35/5/399.pdf. 
  4. 4.0 4.1 4.2 4.3 Selosse, M.A. (2002). "Prototaxites: A 400 Myr Old Giant Fossil, A Saprophytic Holobasidiomycete, Or A Lichen?". Mycological Research 106 (6): 641–644. doi:10.1017/S0953756202226313. 
  5. Hillier, R; Edwards, D; Morrissey, L. B. (2008). "Sedimentological evidence for rooting structures in the Early Devonian Anglo–Welsh Basin (UK), with speculation on their producers". Palaeogeography, Palaeoclimatology, Palaeoecology 270 (3–4): 366. doi:10.1016/j.palaeo.2008.01.038. 
  6. 6.0 6.1 6.2 6.3 6.4 6.5 6.6 6.7 Hueber, F.M. (2001). "Rotted wood-alga-fungus: the history and life of Prototaxites Dawson 1859". Review of Palaeobotany and Palynology 116 (1): 123–158. doi:10.1016/S0034-6667(01)00058-6. 
  7. Schmid, Rudolf (1976). "Septal pores in Prototaxites, an enigmatic Devonian plant". Science 191 (4224): 287–288. doi:10.1126/science.191.4224.287. PMID 17832148. Bibcode1976Sci...191..287S. 
  8. Jonker, F.P. (1979). "Prototaxites in the Lower Devonian". Palaeontographica B: 39–56. 
  9. A fossil specimen collected by Charles Darwin's friend Joseph Dalton Hooker, was mislaid for 163 years at the British Geological Survey offices in London ("Scientists find lost Darwin fossils in gloomy corner of British Geological Survey", Christian Science Monitor, 17 January 2012; identifying Hooker as "John Hooker").
  10. Dawson, J.W. (1856). "Remarks on a specimen of fossil wood from the Devonian rocks, (Gaspé Sandstones) of Gaspé, Canada East". Proceedings of the American Association for the Advancement of Science 10, Part II: 174-176. https://babel.hathitrust.org/cgi/pt?id=ucm.532928735x&seq=488. 
  11. Dawson, J.W. (1859). "On the fossil plants from the Devonian rocks of Canada". The Quarterly Journal of the Geological Society of London 15: 477 - 488. https://www.biodiversitylibrary.org/item/111474#page/575/mode/1up.  On p. 485, Dawson gave this "plant" its taxonomic name Prototaxites Logani.
  12. Carruthers, Wm. (October 1872). "On the History, Histological Structure, and Affinities of Nematophycus Logani, Carr. (Prototaxites Logani, Dawson), an Alga of Devonian Age". The Monthly Microscopical Journal 8 (4): 160-172. https://www.biodiversitylibrary.org/item/49844#page/188/mode/1up. 
  13. The "Taxinaea" (Taxaceae) are the grouping of conifers to which Dawson drew analogy
  14. Almond Miller, Samuel (1877). The American Palaeozoic Fossils: A Catalogue of the Genera and Species, with Names of Authors, Dates, Places of Publication, Groups of Rocks in which Found, and the Etymology and Signification of the Words, and an Introduction Devoted to the Stratigraphical Geology of the Palaeozoic Rocks. author. pp. 35. https://archive.org/details/cu31924004249235. 
  15. Seward, A. C. (Albert Charles) (1898), Fossil plants : a text-book for students of botany and geology, University Press ; New York : Macmillan, p. 192, http://trove.nla.gov.au/work/3568018, retrieved 13 February 2016 
  16. Seward, A. C. (2010). Plant Life Through the Ages: A Geological and Botanical Retrospect Cambridge Library Collection - Earth Science. Cambridge University Press. pp. 119. ISBN 9781108016001. 
  17. William Dawson, Sir John (2016). The Geological History of Plants. Library of Alexandria. ISBN 9781465606853. 
  18. Church, A.H. (1919). Botanical Memoirs No. 3: Thallassiophyta and the Subaerial Transmigrant. London, England: Oxford University Press. p. 49. https://books.google.com/books?id=ovtGAQAAMAAJ&pg=PA49. 
  19. Debra Lindsay (2005) Prototaxites Dawson, 1859 or Nematophycus Carruthers, 1872: Geologists V. Botanists in the Formative Period of the Science of Paleobotany. Earth Sciences History: 2005, Vol. 24, No. 1, pp. 35-61.
  20. "Sedimentological evidence for rooting structures in the Early Devonian Anglo-Welsh Basin (UK), with speculation on their producers". Palaeogeography, Palaeoclimatology, Palaeoecology 270 (3–4): 366–380. 2008. doi:10.1016/j.palaeo.2008.01.038. 
  21. Graham, LE, Cook, ME, Hanson, DT, Pigg, KB and Graham, JM (2010). "Structural, physiological, and stable carbon isotopic evidence that the enigmatic Paleozoic fossil Prototaxites formed from rolled liverwort mats". American Journal of Botany 97 (2): 268–275. doi:10.3732/ajb.0900322. PMID 21622387. 
  22. Taylor, T. N.; Taylor, E. L.; Decombeix, A. -L.; Schwendemann, A.; Serbet, R.; Escapa, I.; Krings, M. (2010). "The enigmatic Devonian fossil Prototaxites is not a rolled-up liverwort mat: Comment on the paper by Graham et al. (AJB 97: 268-275)". American Journal of Botany 97 (7): 1074–1078. doi:10.3732/ajb.1000047. PMID 21616859. 
  23. Edwards, D.; Axe, L. (2012). "Evidence for a fungal affinity for Nematasketum, a close ally of Prototaxites". Botanical Journal of the Linnean Society 168 (1): 1–18. doi:10.1111/j.1095-8339.2011.01195.x. 
  24. Retallack, G.J. (2019). "Ordovician land plants and fungi from Douglas Dam, Tennessee". The Palaeobotanist 68: 1–33. 
  25. Edwards, Dianne; Morris, Jennifer L.; Axe, Lindsey; Duckett, Jeffrey G.; Pressel, Silvia; Kenrick, Paul (2022). "Piecing together the eophytes – a new group of ancient plants containing cryptospores" (in en). New Phytologist 233 (3): 1440–1455. doi:10.1111/nph.17703. ISSN 0028-646X. https://nph.onlinelibrary.wiley.com/doi/10.1111/nph.17703. 
  26. Prehistoric mystery organism verified as giant fungus Press release from University of Chicago, April 23, 2007.
  27. Niklas, K.J. (1976). "Chemical Examinations of Some Non-Vascular Paleozoic Plants". Brittonia 28 (1): 113–137. doi:10.2307/2805564. 
  28. Niklas, K.J.; Pratt, L.M. (1980). "Evidence for Lignin-Like Constituents in Early Silurian (Llandoverian) Plant Fossils". Science 209 (4454): 396–7. doi:10.1126/science.209.4454.396. PMID 17747811. Bibcode1980Sci...209..396N. 
  29. 29.0 29.1 Labandeira, C. (2007). "The origin of herbivory on land: Initial patterns of plant tissue consumption by arthropods". Insect Science 14 (4): 259–275. doi:10.1111/j.1744-7917.2007.00152.x. 

External links

updated: https://www.ted.com/talks/paul_stamets_6_ways_mushrooms_can_save_the_world

Wikidata ☰ Q2061593 entry