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Leedsichthys

January 01, 1970

Leedsichthys is an extinct genus of pachycormid fish that lived in the oceans of the Middle to Late Jurassic.[1] It is the largest ray-finned fish, and amongst the largest fish known to have ever existed.[2]

Leedsichthys
Temporal range: Callovian-Tithonian
~165–152 Ma
Fossil tail fin from the Natural History Museum, London
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Order: Pachycormiformes
Family: Pachycormidae
Genus: Leedsichthys
Woodward, 1889
Type species
Leedsichthys problematicus
Woodward, 1889
Species
  • ?L. notocetes
    Martill et al., 1999

The first remains of Leedsichthys were identified in the nineteenth century. Especially important were the finds by the British collector Alfred Nicholson Leeds, after whom the genus was named "Leeds' fish" in 1889. The type species is Leedsichthys problematicus. Leedsichthys fossils have been found in England, France, Germany and Chile. In 1999, based on the Chilean discoveries, a second species was named Leedsichthys notocetes, but this was later shown to be indistinguishable from L. problematicus.

Leedsichthys fossils have been difficult to interpret because the skeletons were not completely made of bone. Large parts consisted of cartilage that did not fossilize. On several occasions the enigmatic large partial remains have been mistaken for stegosaurian dinosaur bones. As the vertebrae are among the parts that have not been preserved, it is hard to determine the total body length. Estimates have varied significantly. At the beginning of the twentieth century, a length of 9 m (30 ft) was seen as plausible, but by its end Leedsichthys was sometimes claimed to have been over 30 m (98 ft) long. Recent research has lowered this to about 16.5 m (54 ft) for the largest individuals. Skull bones have been found indicating that Leedsichthys had a large head with bosses on the skull roof. Fossilised bony fin rays show large elongated pectoral fins and a tall vertical tail fin. The gill arches were lined by gill rakers, equipped by a unique system of delicate bone plates, that filtered plankton from the sea water, the main food source.

Along with its close pachycormid relatives Bonnerichthys and Rhinconichthys, Leedsichthys is part of a lineage of large-sized filter-feeders that swam the Mesozoic seas for over 100 million years, from the middle Jurassic until the end of the Cretaceous period. Pachycormids might represent an early branch of Teleostei, the group most modern bony fishes belong to; in that case Leedsichthys is the largest known teleost fish.

Discovery and naming edit

During the 1880s, the gentleman farmer Alfred Nicholson Leeds collected large fish fossils from loam pits near Peterborough, England. In May 1886 these were inspected by John Whitaker Hulke, who in 1887 partially reported them as the back plates of the stegosaurian Omosaurus.[3] On 22 August 1888, the American dinosaur expert Professor Othniel Charles Marsh visited Leeds' farm at Eyebury and quickly concluded that the presumed dinosaurian armour in fact represented the skull bones of a giant fish. Within two weeks British fish expert Arthur Smith Woodward examined the specimens and began to prepare a formal description published in 1889.[4] In it he named the species Leedsichthys problematicus. The generic name Leedsichthys means "Leeds' fish", from Greek ἰχθύς, ichthys, "fish".[1] The fossils found by Leeds gave the fish the specific epithet problematicus because the remains were so fragmented that they were extremely hard to recognize and interpret.[1] After a second publication in 1889,[5] objections were raised against the perceived "barbaric" nature of the generic name, which simply attached a non-Latinised British family name to a Classical Greek word. Woodward therefore in 1890 changed the genus name to Leedsia, resulting in a Leedsia problematica.[6] However, by modern standards this is a non-valid junior synonym.[1]

 
Photo of Arthur Smith Woodward, the describer of Leedsichthys.

The holotype specimen, BMNH P.6921, had been found in a layer of the Oxford Clay Formation dating from the Callovian, about 165 million years old. It consists of 1133 disarticulated elements of the skeleton, mostly fin ray fragments, probably of a single individual. Another specimen, BMNH P.6922, contains additional probable fragmentary remains of Leedsichthys. Woodward also identified a specimen previously acquired from the French collector Tesson, who had in 1857 found them in the Falaises des Vaches Noires of Normandy, BMNH 32581, as the gill rakers of Leedsichthys. Another specimen bought in 1875 from the collection of William Cunnington, BMNH 46355, he failed to recognise.[7]

Leeds continued to collect Leedsichthys fossils that subsequently were acquired by British musea. In March 1898, Leeds reported to have discovered a tail which he on 17 March 1899 sold for £25 to the British Museum of Natural History, which exhibited it as specimen BMNH P.10000; a new inventory number range was begun for the occasion.[8] Already in July 1898, the front of probably the same animal had been bought, BMNH P.11823. On 22 July 1905 specimen BMNH P.10156 was acquired, a gill basket. In January 1915 Leeds sold specimens GLAHM V3362, a pectoral fin, and GLAHM V3363, the remainder of the same skeleton with 904 elements, to the Hunterian Museum of Glasgow.[1]

Leeds had a rival, the collector Henry Keeping [citation needed], who in 1899 tricked pit workers into selling dorsal fin rays by misinforming them that Leeds had lost interest in such finds. Keeping again sold these to the University of Cambridge where they were catalogued as specimen CAMSM J.46873. In September 1901, they were examined by the German palaeontologist Friedrich von Huene, who identified them as tail spikes, Schwanzstacheln, of Omosaurus,[9] the second time Leedsichthys remains were mistaken for stegosaurian bones; Leeds himself was able to disabuse von Huene the same year.[1]

In 2001, students at the Dogsthorpe Star Pit discovered a major new British specimen that they nicknamed "Ariston" after a 1991 commercial for the Indesit Ariston washing machine that claimed it went "on and on and on" — likewise the bones of Leedsichthys seemed to endlessly continue into the face of the loam pit.[10] From 2002 until 2004 "Ariston" or specimen PETMG F174 was excavated by a team headed by Jeff Liston; to uncover the remains it was necessary to remove ten thousand tonnes of loam forming an overburden of 15 metres (49 feet) thickness.[11][12] The find generated considerable media attention, inspiring an episode of the BBC Sea Monsters series, "The Second Most Deadly Sea", and a Channel Four documentary titled The Big Monster Dig, both containing computer-generated animated reconstructions of Leedsichthys. Liston subsequently dedicated a dissertation and a series of articles to Leedsichthys, providing the first extensive modern osteology of the animal.[13]

Apart from the British discoveries, finds of a more fragmentary nature continued to be made in Normandy, France. In July 1982, Germany became an important source of Leedsichthys fossils when two groups of amateur palaeontologists, unaware of each other's activities, began to dig up the same skeleton at Wallücke. Remarkably, parts of it were again incorrectly identified as stegosaurian material, of Lexovisaurus.[14] From 1973 onwards, fragmentary Leedsichthys fossils were uncovered in Chile. In March 1994, a more complete specimen was found, SMNK 2573 PAL. In 1999 the Chilean finds were named as a second species, Leedsichthys notocetes, the "Southern Sea Monster".[15] However, Liston later concluded that the presumed distinguishing traits of this species, depressions on the gill rakers, were artefacts caused by erosion;[13] Leedsichthys notocetes would be a junior synonym of Leedsichthys problematicus.[16]

Fossil range edit

The fossil remains of Leedsichthys have been found in the Callovian of England and northern Germany, the Oxfordian of Chile, and the Callovian and upper Kimmeridgian of France.[17] These occurrences span a temporal range of at least five million years.[7] A complete and isolated gill raker from the Vaca Muerta formation of Argentina (MOZ-Pv 1788), has been assigned to the genus and dates to the early Tithonian.[18]

Description edit

 
Restoration based on modern interpretation of the fossils

Although the remains of over seventy individuals have been found, most of them are partial and fragmentary. The skeleton of Leedsichthys is thus only imperfectly known. This is largely caused by the fact that many skeletal elements, including the front of the skull and the vertebral centra, did not ossify but remained cartilage. Furthermore, those that did ossify were gradually hollowed out during the lifetime of the animal by resorption of the inner bone tissue. In the fossil phase, compression flattened and cracked these hollow structures, making it extraordinarily difficult to identify them or determine their original form.[1]

The head was probably relatively large and wide but still elongated. The snout is completely unknown. Frontal bones are absent. The skull roof is rather robust with bosses on the parietals, continuing sideways over the dermopterotica, and the postparietals. The parietals have a notch on the front midline. A dermosphenoticum is present above the eye socket. The jaws are toothless. Behind the jaw joint a robust hyomandibula is present. The gill basket rests on paired hypohyalia. At least the first two gill arches have ossified hypobranchialia, the lower parts of the gill arch; a third hypobranchiale was likely present. The hypobranchials are attached at their lower ends at an angle of 21,5° via a functional joint that possibly served to increase the gape of the mouth, to about two feet.[7] All five gill arches have ossified ceratobranchialia with a triangular cross-section, the middle sections of the arches. The hypobranchials are fused with their ceratobranchials. The fifth gill arch is fused with the front parts of the basket. Higher epibranchialia and pharyngobranchialia are present but poorly known. The fourth arches are supported by a midline fourth basibranchiale. An ossified operculum is present.[19]

The gill arches are equipped with rows of parallel 3-to-12-centimetre-long (1.2-to-4.7-inch-long) gill rakers, in life probably attached to the ceratobranchials via soft tissue. On the top of each raker one or two rows of dozens of low "teeth" are present. When there are two rows, they are placed on the edges of the upper surface and separated by a deep trough, itself separated from an internal hollow space by a transverse septum. The teeth or "fimbriations" are obliquely directed towards the front and the top. They are grooved at their sides, the striations continuing over the sides of the raker. Detailed study of exquisitely preserved French specimens revealed to Liston that these teeth were, again via soft tissue, each attached to delicate 2-millimetre-long (0.08-inch-long) bony plates, structures that had never before been observed among living or extinct fishes. An earlier hypothesis that the striations would function as sockets for sharp "needle teeth", as with the basking shark, was hereby refuted. The rakers served to filter plankton, the main food supply of Leedsichthys, from the sea water.[17][2]

Large parts of the Leedsichthys fossils consist of bony finrays. Leedsichthys has two pectoral fins that probably were located rather low on the body. They are large, very elongated — about five times longer than wide — and scythe-like, with a sudden kink at the lower end, curving 10° to the rear. Also a dorsal fin is present, although its position is unknown. Pelvic fins at the belly are lacking; also a pelvic plate is absent. However, there are indications for a small triangular anal fin. The vertical tail fin is very large and symmetrical with paired upper and lower lobes; there is a smaller lobe in the middle protruding between them. The rays are unsegmented lepidotrichia, resulting in a rather stiff structure. They are bifurcated at up to three splitting points along their length, so a proximally single ray may have eight distal ends. A row of bony supraneuralia is present behind the head, at each side of the vertebral column. Uroneuralia at the tail are unknown. No bony scales are present.[19]

Size edit

 
Largest specimen of Leedsichthys compared to other Pachycormid fish

Leedsichthys is the largest known member of the Osteichthyes or bony fishes.[20] The largest extant non-tetrapodomorph bony fish is the ocean sunfish, Mola mola, being with a weight of up to two tonnes an order of magnitude smaller than Leedsichthys. The extant giant oarfish might rival Leedsichthys in length but is much thinner. The lack of a preserved vertebral column has made it difficult to estimate the exact length of Leedsichthys.[1] Arthur Smith Woodward, who described the type specimen in 1889,[4] estimated specimen BMNH P.10000 to be of an around nine metre long individual,[21][22] by comparing this tail of Leedsichthys, having a preserved height of 274 centimetres (8.99 feet), with another pachycormid, Hypsocormus. The length of Leedsichthys was not historically the subject of much attention, the only reference to it being made by Woodward himself when he in 1937 indicated it again as 9 metres (30 feet) on the museum label of BMNH P.10000. However, in 1986, David Martill compared the bones of Leedsichthys to a pachycormid that he had recently discovered, Asthenocormus.[20] The unusual proportions of that specimen gave a wide range of possible sizes.[17] Some were as low as 13.5 metres (44 feet), but extrapolating from the gill basket resulted in an estimated length of 27.6 metres (91 feet) for Leedsichthys specimen NHM P.10156 (the earlier BMNH P.10156). Martill considered the higher estimate as a plausible size of the largest individuals.[23] Subsequently, a length of thirty metres (hundred feet) was often mentioned in popular science publications, sometimes one as high as thirty-five metres (115 feet).[24]

Liston in his studies concluded to much lower estimates. Documentation of historical finds[25] and the excavation of "Ariston", the most complete specimen ever from the Star Pit near Whittlesey, Peterborough,[26] support Woodward's figures of between 9 and 10 metres (30 and 33 ft). With "Ariston" the pectoral fins are 100.5 centimetres (3.30 feet) apart, indicating a narrow body of no excessive size, even though it was initially thought to have been 22 metres (72 feet) long.[27] In 2007 Liston stated that most specimens indicated lengths between 7 and 12 metres (23 and 39 ft). A linear extrapolation from the gill basket would be flawed because the gills grow disproportionally in size, having to increase their surface allometrically to ensure the oxygen supply of a body increasing in volume to the third power. The growth ring structures within the remains of Leedsichthys have indicated that it would have taken 21 to 25 years to reach these lengths,[28] and isolated elements from other specimens showed that a maximum size of just over 16 m (52 ft)[29] is not unreasonable.

In 2013, Liston and colleagues estimated that the age of the five specimens (PETMG F174, NHMUK PV P10000, GLAHM V3363, NHMUK PV P6921 and NHMUK PV P10156) would have ranged between 19 and 40 years old. The largest specimen, NHMUK PV P10156, on the basis of its gill basket with a preserved width of 114 centimetres (3.74 ft) and height of 154.5 centimetres (5.07 ft), would have been 38 years old (2 years younger than the holotype NHMUK PV P6921) and measured 16.5 metres (54 ft) long.[2] In 2018, Ferron and colleagues estimated that this specimen would have weighed 44.9 metric tons (49.5 short tons).[30]

Phylogeny edit

Woodward initially assigned Leedsichthys to the Acipenseroidea, considering it related to the sturgeon, having the large gill rakers and branching finrays in common. In 1905, he changed this to the Pachycormidae. The Pachycormidae have a somewhat uncertain position. Often they are considered very basal Teleostei[31][32] — if so, Leedsichthys would be the largest known teleost — others see them as members of a Pachycormiformes forming the sister group of the Teleostei, and sometimes they are seen as even more basal Amiiformes.[33] In the latter case the extant bowfin, Amia calva, would be the closest living relative of Leedsichthys.

Within the Pachycormidae, a cladistic analysis found Leedsichthys to be the sister species of Asthenocormus, their clade being the sister group of Martillichthys.[19]

This cladogram after Friedman et al. shows a possible position of Leedsichtys in the evolutionary tree.[34]

Paleobiology edit

 
Leedsichthys being attacked by Pliosaurus rossicus. The reconstruction of Leedsichthys follows that of Martill (1986) and the BBC, which has been criticised as showing an incorrectly sloping head and visible dermal head bosses

Like the largest fish today, the whale sharks and basking sharks, Leedsichthys problematicus derived its nutrition as a suspension feeder, using an array of specialised gill rakers lining its gill basket to extract zooplankton, small animals, from the water passing through its mouth and across its gills. It is less clear whether also phytoplankton, algae, were part of the diet. Leedsichthys could have been a ram feeder, making the water pass through its gills by swimming, but could also have actively pumped the water through the gill basket. In 2010, Liston suggested that fossilised furrows discovered in ancient sea floors in Switzerland and attributed to the activity of plesiosaurs, had in fact been made by Leedsichthys spouting water through its mouth to disturb and eat the benthos, the animals dwelling in the sea floor mud.[7]

Much is still uncertain about the life cycle of Leedsichthys. Liston's 2013 study suggested a slow, nearly linear, growth.[2] A French study in 1993 of its bone structure concluded however, that the metabolism was rather high.[35] Also problematic is how Leedsichthys could increase its size quickly during the first year of its life. Teleostei typically lay relatively small eggs and this has been seen as an obstacle for them attaining giant sizes.[36]

In 1986, Martill reported the presence of a tooth of the marine crocodile Metriorhynchus in a bone of Leedsichthys. The bone would have healed, a sign that the about 3-metre-long (10-foot-long) Metriorhynchus was actively hunting the much larger fish.[37] However, in 2007 Liston concluded the bone tissue had not in fact healed and that this was probably a case of scavenging. A 2.5 m-long specimen FBS 2012.4.67.80, assigned to Metriorhynchus cf. superciliosus, was found with the gill apparatus of Leedsichthys and remains of invertebrates inside its stomach. Such content indicates that the diet of metriorhynchids was varied, and this individual most likely ate already dead fish.[38] An apex predator of the Oxford Clay seas large enough to attack Leedsichthys was the pliosaurid Liopleurodon.

In 1999 Martill suggested that a climate change at the end of the Callovian led to the extinction of Leedsichthys in the northern seas, the southern Ocean offering a last refuge during the Oxfordian.[15] However, in 2010 Liston pointed out that Leedsichthys during the later Kimmeridgian was still present in the north, as testified by Normandian finds.[7] Liston did nevertheless consider in 2007 that the lack of any vertebrate suspension feeders as large as 0.5 metres (1.6 feet) prior to the Callovian stage of the Mesozoicum might indicate that the Callovian had seen a marked change in productivity as regarded zooplankton populations. Indeed, further studies supported this, viewing Leedsichthys as the beginning of a long line of large (>2 metres (6.6 feet) in length) pachycormid suspension feeders that continued to flourish well into the Late Cretaceous, such as Bonnerichthys and Rhinconichthys,[39] and emphasising the convergent evolutionary paths taken by pachycormids and baleen whales.[40]

Recent studies have uncovered some estimations regarding metabolic rate and speed for Leedsichthys. Using data from living teleost fish as a comparison, scientists discovered that Leedsichthys could have cruised along at potential speeds of 11 mph (17.8 km/h) while still maintaining oxygenation of its body tissues.[41][42]

Footnotes edit

  1. ^ a b c d e f g h Liston, JJ (2004). An overview of the pachycormiform Leedsichthys. In: Arratia G and Tintori A (eds) Mesozoic Fishes 3 - Systematics, Paleoenvironments and Biodiversity. Verlag Dr. Friedrich Pfeil, München, pp 379–390.
  2. ^ a b c d Liston, J., Newbrey, M., Challands, T., and Adams, C., 2013 (2013). "Growth, age and size of the Jurassic pachycormid Leedsichthys problematicus (Osteichthyes: Actinopterygii)" (PDF). In Arratia, G., Schultze, H. and Wilson, M. (ed.). Mesozoic Fishes 5 – Global Diversity and Evolution. München, Germany: Verlag Dr. Friedrich Pfeil. pp. 145–175. ISBN 9783899371598.{{cite book}}: CS1 maint: multiple names: authors list (link) CS1 maint: numeric names: authors list (link)
  3. ^ Hulke, J.W., 1887, "Note on some Dinosaurian remains in the collection of A. Leeds Esq., of Eyebury, Northamptonshire", Quarterly Journal of the Geological Society of London, 43: 695-702
  4. ^ a b Woodward, Smith, A (1889). Preliminary notes on some new and little-known British Jurassic fishes. Geological Magazine Decade 3 Volume 6: 448–455.
  5. ^ Woodward, A.S., 1889, "Notes on some new and little-known British Jurassic Fishes", Annals of the Magazine of natural History, series 6, 4: 405-407
  6. ^ Woodward, A.S., 1890, "Note on the gill-rakers of Leedsia problematica – a gigantic fish from the Oxford Clay", Geological Magazine December III(7): 292-293
  7. ^ a b c d e Liston, J.J., 2010, "The occurrence of the Middle Jurassic pachycormid fish Leedsichthys", Oryctos 9: 1-36
  8. ^ Gunter, M., 2005, Conservation of P.10000: Leedsichthys problematicus. 35 pp.; London (RCA/V&A Conservation)
  9. ^ Huene, F. von, 1901, "Notizen aus dem Woodwardian-Museum in Cambridge", Centralblatt für Mineralogie, Geologie und Palaeontologie 1901: 715-719
  10. ^ Douglas Palmer & Hermione Cockburn, 2012, The Fossil Detectives: Discovering Prehistoric Britain, Google eBook, p. 146
  11. ^ Dawn, A., 2004, "Leedsichthys problematicus", Geology Today 20: 53-55
  12. ^ Dawn, A., 2004, "Leedsichthys problematicus", The Mercian Geologist, 16(1): 43-45
  13. ^ a b Liston, J.J., 2007, A Fish Fit For Ozymandias?: The Ecology, Growth and Osteology of Leedsichthys (Pachycormidae, Actinopterygii), Unpublished PhD Thesis. 464 pp. Faculty of BioMedical & LifeSciences, University of Glasgow, Scotland
  14. ^ Michelis, I., Martin Sander, P., Metzdorf, R. & Breitkreuz, H., 1996, "Die Vertebratenfauna des Calloviums (Mittlerer Jura) aus dem Steinbruch Störmer (Wallücke, Wiehengebirge)", Geologie und Palaeontologie in Westfalen 44: 5-66
  15. ^ a b Martill, D.M., Frey, E., Caceras, R.P. & Diaz, G.C., 1999, "The giant pachycormid Leedsichthys (Actinopterygii) in the southern hemisphere: further evidence for a Jurassic Atlanto-Pacific marine faunal province", Neues Jahrbuch für Geologie und Paläontologie, Monatshefte 1999: 243-256
  16. ^ Liston, J.J., 2013, "The plasticity of gill raker characteristics in suspension feeders: Implications for Pachycormiformes", In: G. Arratia, H.-P. Schultze & M. V. H. Wilson (eds.) Mesozoic Fishes 5 – Global Diversity and Evolution pp 121-143, Verlag Dr. Friedrich Pfeil, München
  17. ^ a b c Liston, JJ (2008a). Leedsichthys des Vaches Noires ... au peigne fin (translation by M-C Buchy) L’Écho des Falaises (=Ech.des Fal.) No.12: 41–49, 2008 ISSN 1253-6946.
  18. ^ Gouiric-Cavalli, Soledad. "Large and Mainly Unnoticed: The First Lower Tithonian Record of a Suspension-Feeding Pachycormid from Southern Gondwana." Ameghiniana 54.3 (2017): 283-289.
  19. ^ a b c Liston, J.J., 2008, "A review of the characters of the edentulous pachycormiforms Leedsichthys, Asthenocormus and Martillichthys nov. gen.", In: Mesozoic Fishes 4 Homology and Phylogeny, G. Arratia, H.-P. Schultze & M. V. H. Wilson (eds.): pp. 181–198, 10 figs., 1 tab. © 2008 by Verlag Dr. Friedrich Pfeil, München, Germany – ISBN 978-3-89937-080-5
  20. ^ a b Martill, DM (1986). The world's largest fish. Geology Today March–April: 61–63.
  21. ^ Woodward, Smith, A (1905). A Guide to the Fossil Reptiles, Amphibians, and Fishes in the Department of Geology and Palaeontology of the British Museum (Natural History). Eighth edition. British Museum (Natural History), London. Pp xviii, 110 pages.
  22. ^ Woodward, A.S., 1917, "Alfred Nicholson Leeds, F.G.S.", Geological Magazine, 6(4): 478-480
  23. ^ Martill, D.M., 1988, "Leedsichthys problematicus, a giant filter-feeding teleost from the Jurassic of England and France", Neues Jahrbuch für Geologie und Paläontologie Monatshefte 1988 (11): 670-680
  24. ^ [Ed.] "Catch the 100ft fish", The Mirror, London, England, September 18, 2003
  25. ^ Liston, JJ & Noè, LF (2004). The tail of the Jurassic fish Leedsichthys problematicus (Osteichthyes: Actinopterygii) collected by Alfred Nicholson Leeds – an example of the importance of historical records in palaeontology. Archives of Natural History 31: 236–252.
  26. ^ Liston, JJ (2006). From Glasgow to the Star Pit and Stuttgart: A short journey around the world's longest fish. The Glasgow Naturalist 24: 59–71.
  27. ^ Sloan, C (2004). Big Fish Story. National Geographic Magazine, p. 42. 1/9/2004.
  28. ^ Liston, JJ, Steel, L & Challands, TJ (2005). Lured by the Rings: Growth structures in Leedsichthys. In: Poyato-Ariza FJ (ed) Fourth International Meeting on Mesozoic Fishes - Systematics, Homology and Nomenclature, Extended Abstracts. Servicio de Publicaciones de la Universidad Autónoma de Madrid/UAM Ediciones, Madrid, pp 147–149
  29. ^ Liston, JJ (2005). Homologies amongst the fragments: searching for synapomorphies in shattered skulls. In: Poyato-Ariza FJ (ed) Fourth International Meeting on Mesozoic Fishes - Systematics, Homology and Nomenclature, Extended Abstracts. Servicio de Publicaciones de la Universidad Autónoma de Madrid/UAM Ediciones, Madrid, pp 141–145.
  30. ^ Ferrón, H. G., Holgado, B., Liston, J. J., Martínez-Pérez, C., & Botella, H. (2018). "Assessing metabolic constraints on the maximum body size of actinopterygians: locomotion energetics of Leedsichthys problematicus (Actinopterygii, Pachycormiformes)". Palaeontology. 61 (5): 775–783. Bibcode:2018Palgy..61..775F. doi:10.1111/pala.12369. hdl:10550/85571. S2CID 134886017.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  31. ^ Arratia, G., 1999, "The monophyly of Teleostei and stem-group teleosts. Consensus and disagreements". –In: Arratia, G. & Schultze, H.-P. (eds.): Mesozoic Fishes 2 – Systematics and Fossil Record: 265-334, München, Dr. Friedrich Pfeil Verlag
  32. ^ M. Friedmann, 2012, "Parallel evolutionary trajectories underlie the origin of giant suspension-feeding whales and bony fish", Proceedings of the Royal Society B 279: 944-951
  33. ^ J.J. Sepkoski, 2002, "A compendium of fossil marine animal genera", Bulletins of American Paleontology 363: 1-560
  34. ^ Matt Friedman; Kenshu Shimada; Larry D. Martin; Michael J. Everhart; Jeff Liston; Anthony Maltese; Michael Triebold (2010). "100-million-year dynasty of giant planktivorous bony fishes in the Mesozoic seas" (PDF). Science. 327 (5968): 990–993. Bibcode:2010Sci...327..990F. doi:10.1126/science.1184743. PMID 20167784. S2CID 206524637.
  35. ^ Bardet, N., Pennettier, E., Pennetier, G., Charles, A. & Charles, J., 1993, "Des os énigmatiques à section triangulaire dans le Jurassique Moyen (Callovien) de Normandie", Bulletin trimestriel de la Société géologique de Normandie et des amis du Muséum du Havre 80: 7-10
  36. ^ Freedman, J.A. & Noakes, L.G., 2002, "Why are there no really big bony fishes? A point-of-view on maximum body size in teleosts and elasmobranchs", Reviews in Fish Biology and Fisheries 12: 403-416
  37. ^ Martill, D.M., 1986, "The diet of Metriorhynchus, a Mesozoic marine crocodile", Neues Jahrbuch fur Geologie und Paläontologie, Monatshefte 1986: 621-625
  38. ^ Stéphane Hua, Jeff Liston, Jérôme Tabouelle (February 2024). "The Diet of Metriorhynchus (Thalattosuchia, Metriorhynchidae): Additional Discoveries and Paleoecological Implications". Fossils. 2 (1): 66-76. doi:10.3390/fossils2010002.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  39. ^ Friedman, M., K. Shimada, L.D. Martin, M.J. Everhart, J. Liston, A. Maltese and M. Triebold, 2010, "100-million-year dynasty of giant planktivorous bony fishes in the Mesozoic seas", Science 327: 990–993
  40. ^ Friedman, M., 2011, "Parallel evolutionary trajectories underlie the origin of giant suspension-feeding whales and bony fishes", Proceedings of the Royal Society B, 279: 944-951
  41. ^ "This ancient fish was bigger than a whale shark—and faster than scientists ever imagined". 2018-05-29.
  42. ^ Humberto G. Ferrón, Borja Holgado, Jeffrey J. Liston, Carlos Martínez‐Pérez & Héctor Botella, 2018, "Assessing metabolic constraints on the maximum body size of actinopterygians: locomotion energetics of Leedsichthys problematicus (Actinopterygii, Pachycormiformes)", Palaeontology 61(5): 775-783

External links edit

  • For more on the Star Pit dig of 2002-2003 look here and also here where the dig was featured in the BBC-Open University series Fossil Detectives. 2011-06-11 at the Wayback Machine
  • For a more accurate reconstruction of Leedsichthys visit Paleocreations. The artist went on to produce the most accurate reconstruction of Leedsichthys to date, which was used on 'Fossil Detectives' (see above).
  • Article on Leedsichthys by Darren Naish.
  • Profile of Leedsichthys problematicus from the BBC series Sea Monsters
  • National Geographic News. Published October 1, 2003.
  • , estimated 22 meters = 72 feet (22 m) long.
  • Picture of Leedsichthys problematicus
  • Article on Leedsichthys from BBC news

January 01, 1970
leedsichthys, extinct, genus, pachycormid, fish, that, lived, oceans, middle, late, jurassic, largest, finned, fish, amongst, largest, fish, known, have, ever, existed, temporal, range, callovian, tithonian, preꞒ, fossil, tail, from, natural, history, museum, . Leedsichthys is an extinct genus of pachycormid fish that lived in the oceans of the Middle to Late Jurassic 1 It is the largest ray finned fish and amongst the largest fish known to have ever existed 2 LeedsichthysTemporal range Callovian Tithonian 165 152 Ma PreꞒ Ꞓ O S D C P T J K Pg N Fossil tail fin from the Natural History Museum London Scientific classification Domain Eukaryota Kingdom Animalia Phylum Chordata Class Actinopterygii Order Pachycormiformes Family Pachycormidae Genus LeedsichthysWoodward 1889 Type species Leedsichthys problematicusWoodward 1889 Species L notocetes Martill et al 1999 The first remains of Leedsichthys were identified in the nineteenth century Especially important were the finds by the British collector Alfred Nicholson Leeds after whom the genus was named Leeds fish in 1889 The type species is Leedsichthys problematicus Leedsichthys fossils have been found in England France Germany and Chile In 1999 based on the Chilean discoveries a second species was named Leedsichthys notocetes but this was later shown to be indistinguishable from L problematicus Leedsichthys fossils have been difficult to interpret because the skeletons were not completely made of bone Large parts consisted of cartilage that did not fossilize On several occasions the enigmatic large partial remains have been mistaken for stegosaurian dinosaur bones As the vertebrae are among the parts that have not been preserved it is hard to determine the total body length Estimates have varied significantly At the beginning of the twentieth century a length of 9 m 30 ft was seen as plausible but by its end Leedsichthys was sometimes claimed to have been over 30 m 98 ft long Recent research has lowered this to about 16 5 m 54 ft for the largest individuals Skull bones have been found indicating that Leedsichthys had a large head with bosses on the skull roof Fossilised bony fin rays show large elongated pectoral fins and a tall vertical tail fin The gill arches were lined by gill rakers equipped by a unique system of delicate bone plates that filtered plankton from the sea water the main food source Along with its close pachycormid relatives Bonnerichthys and Rhinconichthys Leedsichthys is part of a lineage of large sized filter feeders that swam the Mesozoic seas for over 100 million years from the middle Jurassic until the end of the Cretaceous period Pachycormids might represent an early branch of Teleostei the group most modern bony fishes belong to in that case Leedsichthys is the largest known teleost fish Contents 1 Discovery and naming 1 1 Fossil range 2 Description 2 1 Size 3 Phylogeny 4 Paleobiology 5 Footnotes 6 External linksDiscovery and naming editDuring the 1880s the gentleman farmer Alfred Nicholson Leeds collected large fish fossils from loam pits near Peterborough England In May 1886 these were inspected by John Whitaker Hulke who in 1887 partially reported them as the back plates of the stegosaurian Omosaurus 3 On 22 August 1888 the American dinosaur expert Professor Othniel Charles Marsh visited Leeds farm at Eyebury and quickly concluded that the presumed dinosaurian armour in fact represented the skull bones of a giant fish Within two weeks British fish expert Arthur Smith Woodward examined the specimens and began to prepare a formal description published in 1889 4 In it he named the species Leedsichthys problematicus The generic name Leedsichthys means Leeds fish from Greek ἰx8ys ichthys fish 1 The fossils found by Leeds gave the fish the specific epithet problematicus because the remains were so fragmented that they were extremely hard to recognize and interpret 1 After a second publication in 1889 5 objections were raised against the perceived barbaric nature of the generic name which simply attached a non Latinised British family name to a Classical Greek word Woodward therefore in 1890 changed the genus name to Leedsia resulting in a Leedsia problematica 6 However by modern standards this is a non valid junior synonym 1 nbsp Photo of Arthur Smith Woodward the describer of Leedsichthys The holotype specimen BMNH P 6921 had been found in a layer of the Oxford Clay Formation dating from the Callovian about 165 million years old It consists of 1133 disarticulated elements of the skeleton mostly fin ray fragments probably of a single individual Another specimen BMNH P 6922 contains additional probable fragmentary remains of Leedsichthys Woodward also identified a specimen previously acquired from the French collector Tesson who had in 1857 found them in the Falaises des Vaches Noires of Normandy BMNH 32581 as the gill rakers of Leedsichthys Another specimen bought in 1875 from the collection of William Cunnington BMNH 46355 he failed to recognise 7 Leeds continued to collect Leedsichthys fossils that subsequently were acquired by British musea In March 1898 Leeds reported to have discovered a tail which he on 17 March 1899 sold for 25 to the British Museum of Natural History which exhibited it as specimen BMNH P 10000 a new inventory number range was begun for the occasion 8 Already in July 1898 the front of probably the same animal had been bought BMNH P 11823 On 22 July 1905 specimen BMNH P 10156 was acquired a gill basket In January 1915 Leeds sold specimens GLAHM V3362 a pectoral fin and GLAHM V3363 the remainder of the same skeleton with 904 elements to the Hunterian Museum of Glasgow 1 Leeds had a rival the collector Henry Keeping citation needed who in 1899 tricked pit workers into selling dorsal fin rays by misinforming them that Leeds had lost interest in such finds Keeping again sold these to the University of Cambridge where they were catalogued as specimen CAMSM J 46873 In September 1901 they were examined by the German palaeontologist Friedrich von Huene who identified them as tail spikes Schwanzstacheln of Omosaurus 9 the second time Leedsichthys remains were mistaken for stegosaurian bones Leeds himself was able to disabuse von Huene the same year 1 In 2001 students at the Dogsthorpe Star Pit discovered a major new British specimen that they nicknamed Ariston after a 1991 commercial for the Indesit Ariston washing machine that claimed it went on and on and on likewise the bones of Leedsichthys seemed to endlessly continue into the face of the loam pit 10 From 2002 until 2004 Ariston or specimen PETMG F174 was excavated by a team headed by Jeff Liston to uncover the remains it was necessary to remove ten thousand tonnes of loam forming an overburden of 15 metres 49 feet thickness 11 12 The find generated considerable media attention inspiring an episode of the BBC Sea Monsters series The Second Most Deadly Sea and a Channel Four documentary titled The Big Monster Dig both containing computer generated animated reconstructions of Leedsichthys Liston subsequently dedicated a dissertation and a series of articles to Leedsichthys providing the first extensive modern osteology of the animal 13 Apart from the British discoveries finds of a more fragmentary nature continued to be made in Normandy France In July 1982 Germany became an important source of Leedsichthys fossils when two groups of amateur palaeontologists unaware of each other s activities began to dig up the same skeleton at Wallucke Remarkably parts of it were again incorrectly identified as stegosaurian material of Lexovisaurus 14 From 1973 onwards fragmentary Leedsichthys fossils were uncovered in Chile In March 1994 a more complete specimen was found SMNK 2573 PAL In 1999 the Chilean finds were named as a second species Leedsichthys notocetes the Southern Sea Monster 15 However Liston later concluded that the presumed distinguishing traits of this species depressions on the gill rakers were artefacts caused by erosion 13 Leedsichthys notocetes would be a junior synonym of Leedsichthys problematicus 16 Fossil range edit The fossil remains of Leedsichthys have been found in the Callovian of England and northern Germany the Oxfordian of Chile and the Callovian and upper Kimmeridgian of France 17 These occurrences span a temporal range of at least five million years 7 A complete and isolated gill raker from the Vaca Muerta formation of Argentina MOZ Pv 1788 has been assigned to the genus and dates to the early Tithonian 18 Description edit nbsp Restoration based on modern interpretation of the fossils Although the remains of over seventy individuals have been found most of them are partial and fragmentary The skeleton of Leedsichthys is thus only imperfectly known This is largely caused by the fact that many skeletal elements including the front of the skull and the vertebral centra did not ossify but remained cartilage Furthermore those that did ossify were gradually hollowed out during the lifetime of the animal by resorption of the inner bone tissue In the fossil phase compression flattened and cracked these hollow structures making it extraordinarily difficult to identify them or determine their original form 1 The head was probably relatively large and wide but still elongated The snout is completely unknown Frontal bones are absent The skull roof is rather robust with bosses on the parietals continuing sideways over the dermopterotica and the postparietals The parietals have a notch on the front midline A dermosphenoticum is present above the eye socket The jaws are toothless Behind the jaw joint a robust hyomandibula is present The gill basket rests on paired hypohyalia At least the first two gill arches have ossified hypobranchialia the lower parts of the gill arch a third hypobranchiale was likely present The hypobranchials are attached at their lower ends at an angle of 21 5 via a functional joint that possibly served to increase the gape of the mouth to about two feet 7 All five gill arches have ossified ceratobranchialia with a triangular cross section the middle sections of the arches The hypobranchials are fused with their ceratobranchials The fifth gill arch is fused with the front parts of the basket Higher epibranchialia and pharyngobranchialia are present but poorly known The fourth arches are supported by a midline fourth basibranchiale An ossified operculum is present 19 The gill arches are equipped with rows of parallel 3 to 12 centimetre long 1 2 to 4 7 inch long gill rakers in life probably attached to the ceratobranchials via soft tissue On the top of each raker one or two rows of dozens of low teeth are present When there are two rows they are placed on the edges of the upper surface and separated by a deep trough itself separated from an internal hollow space by a transverse septum The teeth or fimbriations are obliquely directed towards the front and the top They are grooved at their sides the striations continuing over the sides of the raker Detailed study of exquisitely preserved French specimens revealed to Liston that these teeth were again via soft tissue each attached to delicate 2 millimetre long 0 08 inch long bony plates structures that had never before been observed among living or extinct fishes An earlier hypothesis that the striations would function as sockets for sharp needle teeth as with the basking shark was hereby refuted The rakers served to filter plankton the main food supply of Leedsichthys from the sea water 17 2 Large parts of the Leedsichthys fossils consist of bony finrays Leedsichthys has two pectoral fins that probably were located rather low on the body They are large very elongated about five times longer than wide and scythe like with a sudden kink at the lower end curving 10 to the rear Also a dorsal fin is present although its position is unknown Pelvic fins at the belly are lacking also a pelvic plate is absent However there are indications for a small triangular anal fin The vertical tail fin is very large and symmetrical with paired upper and lower lobes there is a smaller lobe in the middle protruding between them The rays are unsegmented lepidotrichia resulting in a rather stiff structure They are bifurcated at up to three splitting points along their length so a proximally single ray may have eight distal ends A row of bony supraneuralia is present behind the head at each side of the vertebral column Uroneuralia at the tail are unknown No bony scales are present 19 Size edit nbsp Largest specimen of Leedsichthys compared to other Pachycormid fish Leedsichthys is the largest known member of the Osteichthyes or bony fishes 20 The largest extant non tetrapodomorph bony fish is the ocean sunfish Mola mola being with a weight of up to two tonnes an order of magnitude smaller than Leedsichthys The extant giant oarfish might rival Leedsichthys in length but is much thinner The lack of a preserved vertebral column has made it difficult to estimate the exact length of Leedsichthys 1 Arthur Smith Woodward who described the type specimen in 1889 4 estimated specimen BMNH P 10000 to be of an around nine metre long individual 21 22 by comparing this tail of Leedsichthys having a preserved height of 274 centimetres 8 99 feet with another pachycormid Hypsocormus The length of Leedsichthys was not historically the subject of much attention the only reference to it being made by Woodward himself when he in 1937 indicated it again as 9 metres 30 feet on the museum label of BMNH P 10000 However in 1986 David Martill compared the bones of Leedsichthys to a pachycormid that he had recently discovered Asthenocormus 20 The unusual proportions of that specimen gave a wide range of possible sizes 17 Some were as low as 13 5 metres 44 feet but extrapolating from the gill basket resulted in an estimated length of 27 6 metres 91 feet for Leedsichthys specimen NHM P 10156 the earlier BMNH P 10156 Martill considered the higher estimate as a plausible size of the largest individuals 23 Subsequently a length of thirty metres hundred feet was often mentioned in popular science publications sometimes one as high as thirty five metres 115 feet 24 Liston in his studies concluded to much lower estimates Documentation of historical finds 25 and the excavation of Ariston the most complete specimen ever from the Star Pit near Whittlesey Peterborough 26 support Woodward s figures of between 9 and 10 metres 30 and 33 ft With Ariston the pectoral fins are 100 5 centimetres 3 30 feet apart indicating a narrow body of no excessive size even though it was initially thought to have been 22 metres 72 feet long 27 In 2007 Liston stated that most specimens indicated lengths between 7 and 12 metres 23 and 39 ft A linear extrapolation from the gill basket would be flawed because the gills grow disproportionally in size having to increase their surface allometrically to ensure the oxygen supply of a body increasing in volume to the third power The growth ring structures within the remains of Leedsichthys have indicated that it would have taken 21 to 25 years to reach these lengths 28 and isolated elements from other specimens showed that a maximum size of just over 16 m 52 ft 29 is not unreasonable In 2013 Liston and colleagues estimated that the age of the five specimens PETMG F174 NHMUK PV P10000 GLAHM V3363 NHMUK PV P6921 and NHMUK PV P10156 would have ranged between 19 and 40 years old The largest specimen NHMUK PV P10156 on the basis of its gill basket with a preserved width of 114 centimetres 3 74 ft and height of 154 5 centimetres 5 07 ft would have been 38 years old 2 years younger than the holotype NHMUK PV P6921 and measured 16 5 metres 54 ft long 2 In 2018 Ferron and colleagues estimated that this specimen would have weighed 44 9 metric tons 49 5 short tons 30 Phylogeny editWoodward initially assigned Leedsichthys to the Acipenseroidea considering it related to the sturgeon having the large gill rakers and branching finrays in common In 1905 he changed this to the Pachycormidae The Pachycormidae have a somewhat uncertain position Often they are considered very basal Teleostei 31 32 if so Leedsichthys would be the largest known teleost others see them as members of a Pachycormiformes forming the sister group of the Teleostei and sometimes they are seen as even more basal Amiiformes 33 In the latter case the extant bowfin Amia calva would be the closest living relative of Leedsichthys Within the Pachycormidae a cladistic analysis found Leedsichthys to be the sister species of Asthenocormus their clade being the sister group of Martillichthys 19 This cladogram after Friedman et al shows a possible position of Leedsichtys in the evolutionary tree 34 Pteronisculus Discoserra pectinodon Watsonulus eugnathoides Macrepistius rostratus Caturus Amia calva Lepisosteus platostomus Macrosemius rostratus Semionotus elegans Lepidotes Pholidophorus bechei Elops hawaiensis Hiodon alosoides Pachycormidae Euthynotus Hypsocormus insignis Hypsocormus tenuirostris Orthocormus Australopachycormus hurleyi Protosphyraena Pachycormus Asthenocormus titanius Martillichthys renwickae Bonnerichthys gladius Leedsichthys problematicus Rhinconichthys tayloriPaleobiology edit nbsp Leedsichthys being attacked by Pliosaurus rossicus The reconstruction of Leedsichthys follows that of Martill 1986 and the BBC which has been criticised as showing an incorrectly sloping head and visible dermal head bosses Like the largest fish today the whale sharks and basking sharks Leedsichthys problematicus derived its nutrition as a suspension feeder using an array of specialised gill rakers lining its gill basket to extract zooplankton small animals from the water passing through its mouth and across its gills It is less clear whether also phytoplankton algae were part of the diet Leedsichthys could have been a ram feeder making the water pass through its gills by swimming but could also have actively pumped the water through the gill basket In 2010 Liston suggested that fossilised furrows discovered in ancient sea floors in Switzerland and attributed to the activity of plesiosaurs had in fact been made by Leedsichthys spouting water through its mouth to disturb and eat the benthos the animals dwelling in the sea floor mud 7 Much is still uncertain about the life cycle of Leedsichthys Liston s 2013 study suggested a slow nearly linear growth 2 A French study in 1993 of its bone structure concluded however that the metabolism was rather high 35 Also problematic is how Leedsichthys could increase its size quickly during the first year of its life Teleostei typically lay relatively small eggs and this has been seen as an obstacle for them attaining giant sizes 36 In 1986 Martill reported the presence of a tooth of the marine crocodile Metriorhynchus in a bone of Leedsichthys The bone would have healed a sign that the about 3 metre long 10 foot long Metriorhynchus was actively hunting the much larger fish 37 However in 2007 Liston concluded the bone tissue had not in fact healed and that this was probably a case of scavenging A 2 5 m long specimen FBS 2012 4 67 80 assigned to Metriorhynchus cf superciliosus was found with the gill apparatus of Leedsichthys and remains of invertebrates inside its stomach Such content indicates that the diet of metriorhynchids was varied and this individual most likely ate already dead fish 38 An apex predator of the Oxford Clay seas large enough to attack Leedsichthys was the pliosaurid Liopleurodon In 1999 Martill suggested that a climate change at the end of the Callovian led to the extinction of Leedsichthys in the northern seas the southern Ocean offering a last refuge during the Oxfordian 15 However in 2010 Liston pointed out that Leedsichthys during the later Kimmeridgian was still present in the north as testified by Normandian finds 7 Liston did nevertheless consider in 2007 that the lack of any vertebrate suspension feeders as large as 0 5 metres 1 6 feet prior to the Callovian stage of the Mesozoicum might indicate that the Callovian had seen a marked change in productivity as regarded zooplankton populations Indeed further studies supported this viewing Leedsichthys as the beginning of a long line of large gt 2 metres 6 6 feet in length pachycormid suspension feeders that continued to flourish well into the Late Cretaceous such as Bonnerichthys and Rhinconichthys 39 and emphasising the convergent evolutionary paths taken by pachycormids and baleen whales 40 Recent studies have uncovered some estimations regarding metabolic rate and speed for Leedsichthys Using data from living teleost fish as a comparison scientists discovered that Leedsichthys could have cruised along at potential speeds of 11 mph 17 8 km h while still maintaining oxygenation of its body tissues 41 42 Footnotes edit a b c d e f g h Liston JJ 2004 An overview of the pachycormiform Leedsichthys In Arratia G and Tintori A eds Mesozoic Fishes 3 Systematics Paleoenvironments and Biodiversity Verlag Dr Friedrich Pfeil Munchen pp 379 390 a b c d Liston J Newbrey M Challands T and Adams C 2013 2013 Growth age and size of the Jurassic pachycormid Leedsichthys problematicus Osteichthyes Actinopterygii PDF In Arratia G Schultze H and Wilson M ed Mesozoic Fishes 5 Global Diversity and Evolution Munchen Germany Verlag Dr Friedrich Pfeil pp 145 175 ISBN 9783899371598 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link CS1 maint numeric names authors list link Hulke J W 1887 Note on some Dinosaurian remains in the collection of A Leeds Esq of Eyebury Northamptonshire Quarterly Journal of the Geological Society of London 43 695 702 a b Woodward Smith A 1889 Preliminary notes on some new and little known British Jurassic fishes Geological Magazine Decade 3 Volume 6 448 455 Woodward A S 1889 Notes on some new and little known British Jurassic Fishes Annals of the Magazine of natural History series 6 4 405 407 Woodward A S 1890 Note on the gill rakers of Leedsia problematica a gigantic fish from the Oxford Clay Geological Magazine December III 7 292 293 a b c d e Liston J J 2010 The occurrence of the Middle Jurassic pachycormid fish Leedsichthys Oryctos 9 1 36 Gunter M 2005 Conservation of P 10000 Leedsichthys problematicus 35 pp London RCA V amp A Conservation Huene F von 1901 Notizen aus dem Woodwardian Museum in Cambridge Centralblatt fur Mineralogie Geologie und Palaeontologie 1901 715 719 Douglas Palmer amp Hermione Cockburn 2012 The Fossil Detectives Discovering Prehistoric Britain Google eBook p 146 Dawn A 2004 Leedsichthys problematicus Geology Today 20 53 55 Dawn A 2004 Leedsichthys problematicus The Mercian Geologist 16 1 43 45 a b Liston J J 2007 A Fish Fit For Ozymandias The Ecology Growth and Osteology of Leedsichthys Pachycormidae Actinopterygii Unpublished PhD Thesis 464 pp Faculty of BioMedical amp LifeSciences University of Glasgow Scotland Michelis I Martin Sander P Metzdorf R amp Breitkreuz H 1996 Die Vertebratenfauna des Calloviums Mittlerer Jura aus dem Steinbruch Stormer Wallucke Wiehengebirge Geologie und Palaeontologie in Westfalen 44 5 66 a b Martill D M Frey E Caceras R P amp Diaz G C 1999 The giant pachycormid Leedsichthys Actinopterygii in the southern hemisphere further evidence for a Jurassic Atlanto Pacific marine faunal province Neues Jahrbuch fur Geologie und Palaontologie Monatshefte 1999 243 256 Liston J J 2013 The plasticity of gill raker characteristics in suspension feeders Implications for Pachycormiformes In G Arratia H P Schultze amp M V H Wilson eds Mesozoic Fishes 5 Global Diversity and Evolution pp 121 143 Verlag Dr Friedrich Pfeil Munchen a b c Liston JJ 2008a Leedsichthys des Vaches Noires au peigne fin translation by M C Buchy L Echo des Falaises Ech des Fal No 12 41 49 2008 ISSN 1253 6946 Gouiric Cavalli Soledad Large and Mainly Unnoticed The First Lower Tithonian Record of a Suspension Feeding Pachycormid from Southern Gondwana Ameghiniana 54 3 2017 283 289 a b c Liston J J 2008 A review of the characters of the edentulous pachycormiforms Leedsichthys Asthenocormus and Martillichthys nov gen In Mesozoic Fishes 4 Homology and Phylogeny G Arratia H P Schultze amp M V H Wilson eds pp 181 198 10 figs 1 tab c 2008 by Verlag Dr Friedrich Pfeil Munchen Germany ISBN 978 3 89937 080 5 a b Martill DM 1986 The world s largest fish Geology Today March April 61 63 Woodward Smith A 1905 A Guide to the Fossil Reptiles Amphibians and Fishes in the Department of Geology and Palaeontology of the British Museum Natural History Eighth edition British Museum Natural History London Pp xviii 110 pages Woodward A S 1917 Alfred Nicholson Leeds F G S Geological Magazine 6 4 478 480 Martill D M 1988 Leedsichthys problematicus a giant filter feeding teleost from the Jurassic of England and France Neues Jahrbuch fur Geologie und Palaontologie Monatshefte 1988 11 670 680 Ed Catch the 100ft fish The Mirror London England September 18 2003 Liston JJ amp Noe LF 2004 The tail of the Jurassic fish Leedsichthys problematicus Osteichthyes Actinopterygii collected by Alfred Nicholson Leeds an example of the importance of historical records in palaeontology Archives of Natural History 31 236 252 Liston JJ 2006 From Glasgow to the Star Pit and Stuttgart A short journey around the world s longest fish The Glasgow Naturalist 24 59 71 Sloan C 2004 Big Fish Story National Geographic Magazine p 42 1 9 2004 Liston JJ Steel L amp Challands TJ 2005 Lured by the Rings Growth structures in Leedsichthys In Poyato Ariza FJ ed Fourth International Meeting on Mesozoic Fishes Systematics Homology and Nomenclature Extended Abstracts Servicio de Publicaciones de la Universidad Autonoma de Madrid UAM Ediciones Madrid pp 147 149 Liston JJ 2005 Homologies amongst the fragments searching for synapomorphies in shattered skulls In Poyato Ariza FJ ed Fourth International Meeting on Mesozoic Fishes Systematics Homology and Nomenclature Extended Abstracts Servicio de Publicaciones de la Universidad Autonoma de Madrid UAM Ediciones Madrid pp 141 145 Ferron H G Holgado B Liston J J Martinez Perez C amp Botella H 2018 Assessing metabolic constraints on the maximum body size of actinopterygians locomotion energetics of Leedsichthys problematicus Actinopterygii Pachycormiformes Palaeontology 61 5 775 783 Bibcode 2018Palgy 61 775F doi 10 1111 pala 12369 hdl 10550 85571 S2CID 134886017 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Arratia G 1999 The monophyly of Teleostei and stem group teleosts Consensus and disagreements In Arratia G amp Schultze H P eds Mesozoic Fishes 2 Systematics and Fossil Record 265 334 Munchen Dr Friedrich Pfeil Verlag M Friedmann 2012 Parallel evolutionary trajectories underlie the origin of giant suspension feeding whales and bony fish Proceedings of the Royal Society B 279 944 951 J J Sepkoski 2002 A compendium of fossil marine animal genera Bulletins of American Paleontology 363 1 560 Matt Friedman Kenshu Shimada Larry D Martin Michael J Everhart Jeff Liston Anthony Maltese Michael Triebold 2010 100 million year dynasty of giant planktivorous bony fishes in the Mesozoic seas PDF Science 327 5968 990 993 Bibcode 2010Sci 327 990F doi 10 1126 science 1184743 PMID 20167784 S2CID 206524637 Bardet N Pennettier E Pennetier G Charles A amp Charles J 1993 Des os enigmatiques a section triangulaire dans le Jurassique Moyen Callovien de Normandie Bulletin trimestriel de la Societe geologique de Normandie et des amis du Museum du Havre 80 7 10 Freedman J A amp Noakes L G 2002 Why are there no really big bony fishes A point of view on maximum body size in teleosts and elasmobranchs Reviews in Fish Biology and Fisheries 12 403 416 Martill D M 1986 The diet of Metriorhynchus a Mesozoic marine crocodile Neues Jahrbuch fur Geologie und Palaontologie Monatshefte 1986 621 625 Stephane Hua Jeff Liston Jerome Tabouelle February 2024 The Diet of Metriorhynchus Thalattosuchia Metriorhynchidae Additional Discoveries and Paleoecological Implications Fossils 2 1 66 76 doi 10 3390 fossils2010002 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Friedman M K Shimada L D Martin M J Everhart J Liston A Maltese and M Triebold 2010 100 million year dynasty of giant planktivorous bony fishes in the Mesozoic seas Science 327 990 993 Friedman M 2011 Parallel evolutionary trajectories underlie the origin of giant suspension feeding whales and bony fishes Proceedings of the Royal Society B 279 944 951 This ancient fish was bigger than a whale shark and faster than scientists ever imagined 2018 05 29 Humberto G Ferron Borja Holgado Jeffrey J Liston Carlos Martinez Perez amp Hector Botella 2018 Assessing metabolic constraints on the maximum body size of actinopterygians locomotion energetics of Leedsichthys problematicus Actinopterygii Pachycormiformes Palaeontology 61 5 775 783External links edit nbsp Paleontology portal nbsp Fish portal For more on the Star Pit dig of 2002 2003 look here and also here where the dig was featured in the BBC Open University series Fossil Detectives Archived 2011 06 11 at the Wayback Machine For a more accurate reconstruction of Leedsichthys visit Paleocreations The artist went on to produce the most accurate reconstruction of Leedsichthys to date which was used on Fossil Detectives see above Article on Leedsichthys by Darren Naish Profile of Leedsichthys problematicus from the BBC series Sea Monsters Biggest Fish Ever Found Unearthed in U K National Geographic News Published October 1 2003 Article on the latest discovery of a Leedsichthys problematicus fossil estimated 22 meters 72 feet 22 m long Picture of Leedsichthys problematicus Article on Leedsichthys from BBC news Retrieved from https en wikipedia org w index php title Leedsichthys amp oldid 1211507866, wikipedia, wiki, book, books, library,

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