The group was initially contested by a significant minority of biologists. Some argued for groupings based on more traditional taxonomic techniques,[9] while others contested the interpretation of the molecular data.[10][11]
The most notable characteristic shared by ecdysozoans is a three-layered
cuticle (four in
Tardigrada[12]) composed of organic material, which is periodically molted as the animal grows. This process of molting is called
ecdysis, and gives the group its name. The ecdysozoans lack locomotory
cilia and produce mostly
amoeboid sperm, and their
embryos do not undergo
spiral cleavage as in most other protostomes. Ancestrally, the group exhibited sclerotized teeth within the foregut, and a ring of spines around the mouth opening, though these features have been secondarily lost in certain groups.[13][14] A respiratory and circulatory system is only present in
onychophorans and arthropods (often absent in smaller arthropods like mites); in the rest of the groups, both systems are missing.
Phylogeny
The Ecdysozoa include the following phyla:
Arthropoda,
Onychophora,
Tardigrada,
Kinorhyncha,
Priapulida,
Loricifera,
Nematoda, and
Nematomorpha. A few other groups, such as the
gastrotrichs, have been considered possible members but lack the main characters of the group, and are now placed elsewhere. The Arthropoda, Onychophora, and Tardigrada have been grouped together as the
Panarthropoda because they are distinguished by segmented body plans.[15] Dunn et al. in 2008 suggested that the tardigrada could be grouped along with the nematodes, leaving Onychophora as the sister group to the arthropods.[7] The non-panarthropod members of Ecdysozoa have been grouped as
Cycloneuralia but they are more usually considered
paraphyletic in representing the primitive condition from which the Panarthropoda evolved.[16]
A modern consensus
phylogenetic tree for the protostomes is shown below.[17][18][19][20][21][22] It is indicated when approximately clades radiated into newer clades in millions of years ago (Mya); dashed lines show especially uncertain placements.[23]
The phylogenetic tree is based on Nielsen et al.[24] and Howard et al.[25]
The grouping proposed by Aguinaldo et al. is almost universally accepted, replacing an older hypothesis that
Panarthropoda should be classified with
Annelida in a group called the
Articulata, and that Ecdysozoa are
polyphyletic. Nielsen has suggested that a possible solution is to regard Ecdysozoa as a sister-group of
Annelida,[26] though later considered them unrelated.[27]
Inclusion of the
roundworms within the Ecdysozoa was initially contested[10][28][29] but since 2003, a broad consensus has formed supporting the Ecdysozoa [30] and in 2011 the
Darwin–Wallace Medal was awarded to
James Lake for the discovery of the New Animal Phylogeny consisting of the Ecdysozoa, the
Lophotrochozoa, and the Deuterostomia.[31]
Coelomata hypothesis
Before Aguinaldo's Ecdysozoa proposal, one of the prevailing theories for the evolution of the
bilateral animals was based on the morphology of their
body cavities. There were three types, or
grades of organization: the
Acoelomata (no
coelom), the
Pseudocoelomata (partial coelom), and the
Eucoelomata (true
coelom). Adoutte and coworkers were among the first to strongly support the Ecdysozoa.[32] With the introduction of molecular phylogenetics, the coelomate hypothesis was abandoned, although some molecular, phylogenetic support for the Coelomata continued until as late as 2005.[33]
^Eernisse, D.J.; Albert, J.S.; Anderson, F.E. (1992). "Annelida and Arthropoda are not sister taxa: A phylogenetic analysis of spiralian metazoan morphology". Systematic Biology. 41 (3): 305–330.
doi:
10.1093/sysbio/41.3.305.
^Aguinaldo, A.M.A.; Turbeville, J.M.; Linford, L.S.; Rivera, M.C.; Garey, J.R.; Raff, R.A.; Lake, J.A. (29 May 1997). "Evidence for a clade of nematodes, arthropods, and other moulting animals". Nature. 387 (6632): 489–493.
Bibcode:
1997Natur.387R.489A.
doi:
10.1038/387489a0.
PMID9168109.
S2CID4334033.
^Ax, P. (1985). "The position of the Gnathostomulida and Platyhelminthes in the phylogenetic system of the Bilateria". In Conway Morris, S.; George, J.D.; Gibson, R.; Platt, H.M. (eds.).
The Origins and Relationships of Lower Invertebrates. Systematics Association Special Volume. Vol. 28. New York, NY: Clarendon / Oxford University Press. pp. 168–180.
ISBN019857181X.
OCLC59186778 – via Internet Archive (archive.org). proceedings of an international symposium held in London, September 1983ISBN9780198571810
^Nielsen, Claus (1995). Animal Evolution: Interrelationships of the living phyla. Oxford University Press.
ISBN978-0-19-850682-9.
Garey, James R.; Schmidt-Rhaesa, Andreas (December 1998) [3–7 January 1998].
Essential role of "minor" phyla in understanding animal evolution. Annual Meeting of the Society for Integrative and Comparative Biology, 3–7 January 1998, Boston, Massachusetts. Symposium on Evolutionary Relationships of Metazoan Phyla: Advances, problems, and approaches. American Zoologist. Vol. 38, no. 6. pp. 907–917.
doi:10.1093/icb/38.6.907.
JSTOR4620218. Archived from
the original on 2003-03-13. Retrieved 2023-07-30 – via chuma.cas.usf.edu/~garey.