Biology:Thelodonti

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Short description: Extinct class of jawless fishes

Thelodonti
Temporal range: Sandbian[1]–Late Devonian,[2] 458–359 Ma
Thelodonti.gif
Among the flat-bodied forms are Lanarkia (top left), provided with long, spine-shaped scales, and Loganellia (top right and middle). Other thelodonts, such as Furcacauda from the Devonian of Canada (bottom) are deep-bodied, with lateral gill openings and a very large, forked tail.[3]
Scientific classification e
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Subphylum: Vertebrata
Infraphylum: Agnatha
Superclass: Thelodontomorphi
Jackel 1911
Class: Thelodonti
Jaekel, 1911
Orders

Thelodonti (from Greek: "nipple teeth")[4] is a class of extinct Palaeozoic jawless fishes with distinctive scales instead of large plates of armor.

There is much debate over whether the group represents a monophyletic grouping, or disparate stem groups to the major lines of jawless and jawed fish.

Shielia taiti

Thelodonts are united in possession of "thelodont scales". This defining character is not necessarily a result of shared ancestry, as it may have been evolved independently by different groups. Thus the thelodonts are generally thought to represent a polyphyletic group,[5] although there is no firm agreement on this point. On the basis that they are monophyletic, they are reconstructed as being ancestrally marine and invading freshwater on multiple occasions.[6]

"Thelodonts" were morphologically very similar, and probably closely related, to fish of the classes Heterostraci and Anaspida, differing mainly in their covering of distinctive, small, spiny scales. These scales were easily dispersed after death; their small size and resilience makes them the most common vertebrate fossil of their time.[7][8]

The fish lived in both freshwater and marine environments, first appearing during the Ordovician, and perishing during the Frasnian–Famennian extinction event of the Late Devonian. Traditionally they were considered predominantly deposit-feeding bottom dwellers, but more recent studies have showed they occupied various ecological roles in various parts of the water column, much like modern bony fishes and sharks. In particular, a large variety of species preferred reef ecosystems, and it has been suggested that this preference was the reason for the development of their unique scales, protecting against abrasion and allowing for the development of more flexible bodies than other jawless fish, which had inflexible armors and were restricted to open habitats.[9]

Description

Very few complete thelodont specimens are known; fewer still are preserved in three dimensions. This is due in part to the lack of an internal ossified (i.e. bony) skeleton; it does not help that the scales are poorly, if at all, attached to one another, and that they readily detach from their owners upon death.

The exoskeleton is composed of many tooth-like scales, usually around 0.5-1.5mm in size. These scales did not overlap,[10] and were aligned to point backwards along the fish, in the most streamlined direction, but beyond that, often appear haphazard in their orientation. The scales themselves approximate the form of a teardrop mounted on a small, bulky base, with the base often containing a small rootlet with which the scale was attached to the fish. The "teardrop" often contains lines, ridges, furrows and spikes running down its length in an array of sometimes complex patterns.[11] Scales found around the gill region were generally smaller than the larger, bulkier scales found on the dorsal/ventral sides of the fish; some genera display rows of longer spikes.[12]

The scaly covering contrasts them with most other jawless fishes, which were armor-plated with large, flat scales.

Aside from scattered scales, some specimens do appear to display imprints, giving an indication of the structure of the whole animal – which appeared to reach 15–30 cm in length.[13] Tentative studies appear to suggest that the fish possessed a more developed braincase than the lampreys, with an almost shark-like outline. Internal scales have also been recovered, some fused into plates resembling gnathostome tooth-whorls to such a degree that some researchers favour a close link between the families.[11]

Despite the rarity of complete fossils, these very rare intact specimens do allow us to gain an insight into the internal organ arrangement of the Thelodonts. Some specimens described in 1993 were the first to be found with a significant degree of three-dimensionality, ending speculations that the Thelodonts were flattened fish. Further, these fossils allowed the gut morphology to be interpreted, which generated much excitement: their guts were unlike those of any other agnathans, and a stomach was clearly visible: this was unexpected, as it was previously thought that stomachs evolved after jaws. Distinctive fork-shaped tails – usually characteristic of the jawed fish (gnathostomes) – were also found, linking the two groups to an unexpected degree.[14]

The fins of the thelodonts are useful in reconstructing their mode of life. Their paired pectoral fins were combined with a single, usually well-developed, dorsal and anal fins;[13] these and the hypercercal and much larger hypocercal lobes forming a heterocercal tail resemble features of modern fish that are associated with their deftness at predation and evasion.[12]

Taxonomy

Due to the small number of intact fossils, the taxonomy of thelodonts is based primarily on scale morphology. In fact, some thelodont families are only recognised based on their scale fossils.

A recent assessment of thelodont taxonomy by Wilson and Märss in 2009 merges the orders Loganelliiformes, Katoporiida and Shieliiformes into Thelodontiformes, places families Lanarkiidae and Nikoliviidae into Furcacaudiformes on the basis of scale morphology, and establishes Archipelepidiformes as the basal-most order.[15]

A newer taxonomy based on the work of Nelson, Grande and Wilson 2016[16] and van der Laan 2016.[17]

  • SuperclassThelodontomorphi Jaekel 1911
    • ClassThelodonti Kiaer 1932
      • FamilyOeseliidae Märss 2005
      • OrderArchipelepidiformes Wilson & Märss 2009
        • FamilyBoothialepididae Märss 1999
        • FamilyArchipelepididae Märss ex Soehn et al. 2001
      • OrderFurcacaudiformes Wilson & Caldwell 1998 (Fork-tailed thelodonts)
        • FamilyNikoliviidae Karatajūtė-Talimaa 1978
        • FamilyLanarkiidae Obručhev 1949
        • FamilyPezopallichthyidae Wilson & Caldwell 1998
        • FamilyDrepanolepididae Wilson & Marss 2009
        • FamilyBarlowodidae Märss, Wilson & Thorsteinsson 2002
        • FamilyApalolepididae Turner 1976
        • FamilyFurcacaudidae Wilson & Caldwell 1998
      • Clade Thelodontida Stensiö 1958 non Kiaer 1932 s.l.
        • FamilyTalivaliidae Marss, Wilson & Thorsteinsson 2002
        • FamilyLongodidae Märss 2006b
        • FamilyHelenolepididae Wilson & Märss 2009
        • OrderSandiviiformes Karatajūtė-Talimaa & Märss 2004
          • FamilyAngaralepididae Karatajūtė-Talimaa & Märss 2004
          • FamilyStroinolepididae Karatajūtė-Talimaa & Märss 2002
          • FamilySandiviidae Karatajūtė-Talimaa & Märss 2004
        • OrderTuriniida Stensiö 1958
          • FamilyTuriniidae Obručhev 1964
        • OrderThelodontiformes
          • FamilyThelodontidae Jordan 1905
        • OrderLoganelliiformes Turner 1991
          • FamilyNunavutiidae Marss, Wilson & Thorsteinsson 2002
          • FamilyLoganelliidae Märss, Wilson & Thorsteinsson 2002
        • OrderPhlebolepidiformes Berg 1937 s.s.
          • FamilyPhlebolepididae Berg 1937 corrig.
          • FamilyShieliidae Märss, Wilson & Thorsteinsson 2002
          • FamilyKatoporodidae Soehn et al. 2001 ex Märss, Wilson & Thorsteinsson 2002

Scales

Left to right: denticles of Paralogania (?), Shielia taiti, Lanarkia horrida

The bony scales of the thelodont group, as the most abundant form of fossil, are also the best understood – and thus most useful. The scales were formed and shed throughout the organisms' lifetimes, and quickly separated after their death.[18]

Bone – being one of the most resistant materials to the process of fossilisation – often preserves internal detail, which allows the histology and growth of the scales to be studied in detail. The scales consist of a non-growing "crown" composed of dentine, with a sometimes-ornamented enameloid upper surface and an aspidine (acellular bony tissue) base.[19] Its growing base is made of cell-free bone, which sometimes developed anchorage structures to fix it in the side of the fish.[11] Beyond that, there appear to be five types of bone-growth, which may represent five natural groupings within the thelodonts – or a spectrum ranging between the end members, meta- (or ortho-) dentine and mesodentine tissues.[20] Each of the five scale morphs appears to resemble the scales of more derived groupings of fish, suggesting that thelodont groups may have been stem groups to succeeding clades of fish.[11]

Scale morphology, alone, has limited value for distinguishing thelodont species. Within each organism, scale shape varies greatly according to body area,[21] with intermediate scale forms appearing between different areas; furthermore, scale morphology may not even be constant within a given body area. To confuse things further, scale morphologies are not unique to specific taxa, and may be indistinguishable on the same area of two different species.[13]

The morphology and histology of the thelodonts provides the main tool for quantifying their diversity and distinguishing between species – although ultimately using such convergent traits is prone to errors. Nonetheless, a framework of three groups has been proposed, based upon scale morphology and histology.[20]

Thelodonts displayed similar squamation patterns as modern sharks, so functionally they served a similar role. This allows for a clearer observation of their ecological niches. In particular, protection against abrasion seems to have been the original role for these scales.[9]

Ecology

Furcacauda heintzae

Most thelodonts were considered deposit feeders, but more recent studies have shown that several species were active swimmers and thus more pelagic. A large variety of species in particular preferred reef ecosystems.[9] They are mainly known from open shelf environments, but are also found nearer the shore and in some freshwater settings.[7] The appearance of the same species in fresh- and salt-water settings has led to suggestions that some thelodonts migrated into fresh water, perhaps to spawn. However, the transition from fresh- to salt- water should be observable, as the scales' composition would change to reflect the different environment. This compositional change has not yet been found.[22]

Utility as biostratigraphic markers

Thelodont scales are globally widespread during the Silurian and Early Devonian times, becoming restricted in range to Gondwana, until their extinction in the Late Devonian (Frasnian).[11] The morphology of some species diversified rapidly enough for the scales to rival the conodonts in utility as biostratigraphic markers, allowing precise correlation of widely spaced sediments.

Evolutionary patterns

The first major pattern or group of jawless fish with exoskeletons or plated armour, was the Laurentian group, which existed during the Cambrian-Ordovician time. However, the thelodonts (as well as the conodonts, placoderms, acanthodians, and chondrichthyans) are the second major group which are believed to have emerged in the middle Ordovician and lasted near the Late Devonian period. Due to their similar characteristics and chronological time frame of existence, many believe the thelodonts have Laurentian origins.[23]

See also

Further reading

References

  1. Sansom, Robert S.; Randle, Emma; Donoghue, Philip C. J. (February 7, 2015). "Discriminating signal from noise in the fossil record of early vertebrates reveals cryptic evolutionary history". Proceedings of the Royal Society B 282 (1800): 20142245. doi:10.1098/rspb.2014.2245. PMID 25520359. 
  2. Turner, S.; R. S. Dring (1981). "Late Devonian thelodonts (Agnatha) from the Gneudna Formation, Carnarvon Basin, Western Australia". Alcheringa 5: 39–48. doi:10.1080/03115518108565432. 
  3. Janvier, Philippe (1997) Thelodonti The Tree of Life Web Project.
  4. Maisey, John G., Craig Chesek, and David Miller. Discovering fossil fishes. New York: Holt, 1996.
  5. Sarjeant, William Antony S.; L. B. Halstead (1995). Vertebrate fossils and the evolution of scientific concepts: writings in tribute to Beverly Halstead. ISBN 978-2-88124-996-9. https://books.google.com/books?id=B3leE3TTeuIC&pg=PA146. Retrieved 2016-09-26. 
  6. Ferrón, Humberto G; Martínez-Pérez, Carlos; Turner, Susan; Manzanares, Esther; Botella, Héctor (2018). "Patterns of ecological diversification in thelodonts". Palaeontology 61 (2): 303–315. doi:10.1111/pala.12347. 
  7. 7.0 7.1 Turner, S. (1999). "Early Silurian to Early Devonian thelodont assemblages and their possible ecological significance". Palaeocommunities, International Geological Correlation Programme 53, Project Ecostratigraphy, Final Report. Cambridge University Press. pp. 42–78. 
  8. The early and mid Silurian. See Kazlev, M.A., White, T (March 6, 2001). "Thelodonti". Palaeos.com. http://www.palaeos.com/Vertebrates/Units/050Thelodonti/050.100.html#Thelodonti. Retrieved October 30, 2007. 
  9. 9.0 9.1 9.2 Ferrón Humberto G., Botella Héctor (2017). "Squamation and ecology of thelodonts". PLOS ONE 12 (2): e0172781. doi:10.1371/journal.pone.0172781. PMID 28241029. Bibcode2017PLoSO..1272781F. 
  10. Turner, S. (1973). "Siluro-Devonian thelodonts from the Welsh Borderland". Journal of the Geological Society 129 (6): 557–584. doi:10.1144/gsjgs.129.6.0557. Bibcode1973JGSoc.129..557T. 
  11. 11.0 11.1 11.2 11.3 11.4 Janvier, Philippe (1998). "Early vertebrates and their extant relatives". Early Vertebrates. Oxford University Press. pp. 123–127. ISBN 978-0-19-854047-2. 
  12. 12.0 12.1 Donoghue, P. C. J.; M. P. Smith (2001). "The anatomy of Turinia pagei (Powrie), and the phylogenetic status of the Thelodonti". Transactions of the Royal Society of Edinburgh: Earth Sciences 92 (1): 15–37. doi:10.1017/S0263593301000025. 
  13. 13.0 13.1 13.2 Botella, H.; J. I. Valenzuela-Rios; P. Carls (2006). "A New Early Devonian thelodont from Celtiberia (Spain), with a revision of Spanish thelodonts". Palaeontology 49 (1): 141–154. doi:10.1111/j.1475-4983.2005.00534.x. 
  14. Wilson, Mark V. H.; Michael W. Caldwell (1993). "New Silurian and Devonian fork-tailed 'thelodonts' are jawless vertebrates with stomach and deep bodies". Nature 361 (6441): 442–444. doi:10.1038/361442a0. Bibcode1993Natur.361..442W. 
  15. Wilson Mark VH, Märss Tiiu (2009). "Thelodont phylogeny revisited, with inclusion of key scale-based taxa". Estonian Journal of Earth Sciences 58 (4): 297–310. doi:10.3176/earth.2009.4.08. http://eap.ee/public/Estonian_Journal_of_Earth_Sciences/2009/issue_4/earth-2009-4-297-310.pdf. Retrieved 2014-09-18. 
  16. Nelson, Joseph S.; Grande, Terry C.; Wilson, Mark V. H. (2016). Fishes of the World (5th ed.). John Wiley & Sons. ISBN 978-1-118-34233-6. 
  17. van der Laan, Richard (2016). Family-group names of fossil fishes. https://www.researchgate.net/publication/303911230. 
  18. Turner, S.; Tarling, D. H. (1982). "Thelodont and other agnathan distributions as tests of Lower Paleozoic continental reconstructions". Palaeogeography, Palaeoclimatology, Palaeoecology 39 (3–4): 295–311. doi:10.1016/0031-0182(82)90027-X. Bibcode1982PPP....39..295T. 
  19. Märss, T. (2006). "Exoskeletal ultrasculpture of early vertebrates". Journal of Vertebrate Paleontology 26 (2): 235–252. doi:10.1671/0272-4634(2006)26[235:EUOEV2.0.CO;2]. 
  20. 20.0 20.1 Turner, S. (1991). "Monophyly and interrelationships of the Thelodonti". Early Vertebrates and Related Problems of Evolutionary Biology. Science Press, Beijing. pp. 87–119. 
  21. Märss, T. (1986). "Squamation of the thelodont agnathan Phlebolepis". Journal of Vertebrate Paleontology 6 (1): 1–11. doi:10.1080/02724634.1986.10011593. 
  22. Märss, T. (1992). "The structure of growth layers of Silurian fish scales as potential evidence of environmental changes". Academia 1: 41–48. 
  23. M. Paul Smith, Philip C. J. Donoghue & Ivan J. Sansom (2002). "The spatial and temporal diversification of Early Palaeozoic vertebrates". Special Publications 194 (1): 69–72. doi:10.1144/GSL.SP.2002.194.01.06. Bibcode2002GSLSP.194...69S. http://palaeo.gly.bris.ac.uk/donoghue/PDFs/2002/Smith_et_al_2002.pdf. Retrieved 2011-06-21. 

External links

Wikidata ☰ Q138088 entry