Megacheira Explained

Megacheira ("great hands", also historically great appendage arthropods) is an extinct class of predatory arthropods defined by their possession of spined "great appendages".[1] Their taxonomic position is controversial, with studies either considering them stem-group euarthropods, or stem-group chelicerates.[2] [3] The homology of the great appendages to the cephalic appendages of other arthropods is also controversial. Uncontested members of the group were present in marine environments worldwide from the lower to middle Cambrian.

Morphology

Megacheirans are defined by their possession of uniramous "great appendages", which are their first pair of head appendages. The first one or two proximalmost segments/podomeres are spineless (it has been argued that the supposed first of the two proximal podomeres is actually an arthrodial membrane), while the remaining 3–4 more distal podomeres each typically bore a single upward pointing spine attached towards the distal end of the segment, with the spineless proximal segment/s typically being connected to the spined distal segments by an elbow-like joint, which curled upwards.[4] The great appendages have been interpreted as raptorial limbs involved in predation, with those of some genera such as Yohoia being structurally comparable to the raptorial maxillipeds of mantis shrimp. The spines on the great appendages of leanchoilid megacheirans such as Leanchoilia and Yawunik are elongated into flagella-like structures, suggesting a sensory role alongside predatory function.[5] The body is divided into the head and the trunk. The biramous limbs of megacheirans are homonomous (i.e. having little differentiation from each other), with endopods typically divided into seven segments/podomeres, and paddle-shaped exopods, which are fringed with thin lamellae. The morphology of the terminal telson segment is variable.[6] The biramous limbs of at least some megacheirans have been suggested to have borne exites.[7]

Taxonomy

Several subdivisions within the group are recognised including Jianfengiidae (including Fortiforceps, Jianfengia, Sklerolibyon and possibly Parapeytoia) which are known from the Early Cambrian of China, as well as the Cheiromorpha (containing at least Yohoia, Haikoucaris, and Leanchoiliidae), known with certainty from the Early-Mid Cambrian of North America, China and Australia, which is distinguished from Jianfengiidae by having a fewer number of body segments (20+ in Jianfengiidae, as compared to typically only 11 to 13 in Cheiromorpha). The monophyly of Megacheira is uncertain, with some studies recovering the group as paraphyletic.

Parapeytoia, which formerly misinterpreted as a radiodont was later suggested to be a member of this group.[8] [9] [10] Possible megacheirans include Enalikter described from the Silurian of the United Kingdom, and Bundenbachiellus from the Early Devonian of Germany;[11] [12] due to their possession of great appendage-like cephalic appendages. However, their relationship to megacheirans has been questioned, due to the uncertain homology of their appendages.[13] Kootenichela has been suggested to be a chimera of various arthropod taxa. Previous inclusion of some "bivalved" genera such as Forfexicaris, Ovalicephalus, and Occacaris to Megacheira was questioned by later investigations.[14] The Late Cambrian Orsten taxon Oelandocaris typically considered to be a crustacean relative, has also been suggested in some studies to be a megacheiran.[15]

List of genera

Relationship to other arthropods

See main article: Arthropod head problem. Megacheirans are either suggested to be stem-group chelicerates or stem-group arthropods, with the former hypothesis based on the chelicerae-like morphology of the great appendages[16] [17] [18] alongside neuroanatomy[19] and the presence of a reduced labrum[20] resembling those of modern chelicerates, it being argued that chelicerae and the great appendages are homologous structures.[21] Other studies suggest that the megacheirans are stem-group arthropods based on the argument that the great appendages are homologous to the frontal appendages of stem-group arthropods like Isoxys and radiodonts. This identity is disputed, with other authors suggesting that the frontal appendages of radiodonts are homologous to the labrum of modern arthropods.

Notes and References

  1. 10.1111/j.1096-3642.2009.00562.x. A new arthropod from the Early Cambrian of North Greenland, with a 'great appendage'-like antennula. March 2010. 26 February 2010 . Stein . Martin. Zoological Journal of the Linnean Society. 158. 3. 477–500.
  2. Aria . Cédric . 26 April 2022 . The origin and early evolution of arthropods . Biological Reviews . 97 . 5 . en . 1786–1809 . 10.1111/brv.12864 . 35475316 . 243269510 . 1464-7931 . 8 May 2024 . 8 May 2024 . https://web.archive.org/web/20240508131708/http://paleorxiv.org/4zmey/download . live .
  3. Liu . Cong . Fu . Dongjing . Wu . Yu . Zhang . Xingliang . Cambrian euarthropod Urokodia aequalis sheds light on the origin of Artiopoda body plan . iScience . July 2024 . 110443 . 10.1016/j.isci.2024.110443. free . 11325232 .
  4. Haug . Joachim T. . Waloszek . Dieter . Maas . Andreas . Liu . Yu . Haug . Carolin . March 2012 . Functional morphology, ontogeny and evolution of mantis shrimp-like predators in the Cambrian: MANTIS SHRIMP-LIKE CAMBRIAN PREDATORS . Palaeontology . en . 55 . 2 . 369–399 . 10.1111/j.1475-4983.2011.01124.x. free .
  5. Aria . Cédric . Caron . Jean-Bernard . Gaines . Robert . 2015 . A large new leanchoiliid from the Burgess Shale and the influence of inapplicable states on stem arthropod phylogeny . Palaeontology . 58 . 4 . 629–660 . 10.1111/pala.12161. 86443516 . free .
  6. Aria . Cédric . Zhao . Fangchen . Zeng . Han . Guo . Jin . Zhu . Maoyan . December 2020 . Fossils from South China redefine the ancestral euarthropod body plan . BMC Evolutionary Biology . en . 20 . 1 . 4 . 10.1186/s12862-019-1560-7 . 1471-2148 . 6950928 . 31914921 . free .
  7. Liu . Yu . Edgecombe . Gregory D. . Schmidt . Michel . Bond . Andrew D. . Melzer . Roland R. . Zhai . Dayou . Mai . Huijuan . Zhang . Maoyin . Hou . Xianguang . 30 July 2021 . Exites in Cambrian arthropods and homology of arthropod limb branches . Nature Communications . 12 . 1 . 4619 . 10.1038/s41467-021-24918-8 . 34330912 . 8324779 . 2041-1723. free .
  8. Stein . Martin . 1 March 2010 . A new arthropod from the Early Cambrian of North Greenland, with a 'great appendage'-like antennula . Zoological Journal of the Linnean Society . en . 158 . 3 . 477–500 . 10.1111/j.1096-3642.2009.00562.x . 0024-4082 . subscription . 29 October 2019 . 3 November 2019 . https://web.archive.org/web/20191103021239/https://academic.oup.com/zoolinnean/article/158/3/477/3798454 . live .
  9. Book: Xian-Guang . Hou . The Cambrian Fossils of Chengjiang, China: The Flowering of Early Animal Life . Siveter . David J. . Siveter . Derek J. . Aldridge . Richard J. . Pei-Yun . Cong . Gabbott . Sarah E. . Xiao-Ya . Ma . Purnell . Mark A. . Williams . Mark . 24 April 2017 . John Wiley & Sons . 9781118896389 . en . 10 May 2021 . 8 May 2024 . https://web.archive.org/web/20240508131607/https://books.google.com/books?id=2YWhDgAAQBAJ&q=Tanglangia&pg=PA184#v=snippet&q=Tanglangia&f=false . live .
  10. Daley . Allison C. . Budd . Graham E. . Caron . Jean-Bernard . Edgecombe . Gregory D. . Collins . Desmond . 20 March 2009 . The Burgess Shale Anomalocaridid Hurdia and Its Significance for Early Euarthropod Evolution . Science . en . 323 . 5921 . 1597–1600 . 10.1126/science.1169514 . 0036-8075 . 19299617 . 206517995.
  11. Siveter . Derek J. . Briggs . Derek E. G. . Siveter . David J. . Sutton . Mark D. . Legg . David . Joomun . Sarah . 7 March 2014 . A Silurian short-great-appendage arthropod . . 281 . 1778 . 20132986 . 10.1098/rspb.2013.2986 . 3906945 . 24452026.
  12. Derek J. Siveter . Derek E. G. Briggs . David J. Siveter . Mark D. Sutton . David Legg . Sarah Joomun . 2015 . Enalikter aphson is an arthropod: a reply to Struck et al. (2014) . . 282 . 1804 . 20142663 . 10.1098/rspb.2014.2663 . 4375861.
  13. Aria . Cédric . October 2022 . The origin and early evolution of arthropods . Biological Reviews . en . 97 . 5 . 1786–1809 . 10.1111/brv.12864 . 35475316 . 243269510 . 1464-7931 . 8 May 2024 . 8 May 2024 . https://web.archive.org/web/20240508131708/http://paleorxiv.org/4zmey/download . live .
  14. Ortega-Hernández . Javier . Janssen . Ralf . Budd . Graham E. . 1 May 2017 . Origin and evolution of the panarthropod head – A palaeobiological and developmental perspective . Arthropod Structure & Development . Evolution of Segmentation . 46 . 3 . 354–379 . 10.1016/j.asd.2016.10.011 . 1467-8039 . 27989966. free .
  15. Aria . Cédric . Caron . Jean-Bernard . May 2017 . Burgess Shale fossils illustrate the origin of the mandibulate body plan . Nature . en . 545 . 7652 . 89–92 . 10.1038/nature22080 . 28445464 . 4454526 . 0028-0836 . subscription . 12 January 2023 . 23 September 2022 . https://web.archive.org/web/20220923174326/https://www.nature.com/articles/nature22080 . live .
  16. Chen. Junyuan. Waloszek. Dieter. Maas. Andreas. 2004. A new 'great-appendage' arthropod from the Lower Cambrian of China and homology of chelicerate chelicerae and raptorial antero-ventral appendages. Lethaia. en. 37. 1. 3–20. 10.1080/00241160410004764. 1502-3931.
  17. Chen . Jun-Yuan . 2009 . The sudden appearance of diverse animal body plansduring the Cambrian explosion . The International Journal of Developmental Biology . 53 . 5–6 . 733–751 . 10.1387/ijdb.072513cj . 1696-3547 . 19557680 . free.
  18. Haug . Joachim T. . Waloszek . Dieter . Maas . Andreas . Liu . Yu . Haug . Carolin . March 2012 . Functional morphology, ontogeny and evolution of mantis shrimp-like predators in the Cambrian: MANTIS SHRIMP-LIKE CAMBRIAN PREDATORS . Palaeontology . en . 55 . 2 . 369–399 . 10.1111/j.1475-4983.2011.01124.x . 82841481. free .
  19. Tanaka . Gengo . Hou . Xianguang . Ma . Xiaoya . Edgecombe . Gregory D. . Strausfeld . Nicholas J. . 17 October 2013 . Chelicerate neural ground pattern in a Cambrian great appendage arthropod . . 502 . 7471 . 364–367 . 10.1038/nature12520 . 24132294 . 4456458.
  20. Liu. Yu. Ortega-Hernández. Javier. Zhai. Dayou. Hou. Xianguang. 25 June 2020. A Reduced Labrum in a Cambrian Great-Appendage Euarthropod. Current Biology. 30. 15. 3057–3061.e2. en. 10.1016/j.cub.2020.05.085. 0960-9822. 32589912. 220057956. free.
  21. Tanaka . Gengo . Hou . Xianguang . Ma . Xiaoya . Edgecombe . Gregory D. . Strausfeld . Nicholas J. . 17 October 2013 . Chelicerate neural ground pattern in a Cambrian great appendage arthropod . Nature . en . 502 . 7471 . 364–367 . 10.1038/nature12520 . 24132294 . 4456458 . 0028-0836 . subscription . 12 January 2023 . 16 October 2022 . https://web.archive.org/web/20221016211810/https://www.nature.com/articles/nature12520 . live .