Charadriiformes

Charadriiformes
Temporal range: Late Cretaceous-Present, 75–0 Ma
Several members of the order
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Aves
Clade: Passerea
Clade: Gruae
Clade: Gruimorphae
Order: Charadriiformes
Huxley, 1867
Families

See text.

Charadriiformes is a diverse order of small to medium-large birds. It includes about 350 species and has members in all parts of the world. Most Charadriiformes live near water and eat invertebrates or other small animals; however, some are pelagic (seabirds), some occupy deserts and a few are found in thick forest.

Taxonomy, systematics and evolution

The order was formerly divided into three suborders:

The Sibley-Ahlquist taxonomy, which has been widely accepted in America, lumps all the Charadriiformes together with other seabirds and birds of prey into a greatly enlarged order Ciconiiformes. However, the resolution of the DNA-DNA hybridization technique used by Sibley & Ahlquist was not sufficient to properly resolve the relationships in this group, and indeed it appears as if the Charadriiformes constitute a single large and very distinctive lineage of modern birds of their own.[1]

The auks, usually considered distinct because of their peculiar morphology, are more likely related to gulls, the "distinctness" being a result of adaptation for diving. Following recent research,[2] a better arrangement may be as follows:

Families in taxonomic order

This is a list of the charadriiform families, presented in taxonomic order.

More conservatively, the Thinocori could be included in the Scolopaci (this combined sub-order is called Limicoli), and the Chionidi in the Charadrii. The suborders Thincori, Scolopaci, Chionidi, and Charadri are commonly referred to collectively as Waders. Some taxonomy sources place the Glareolidae family in its own suborder, instead of being classified under suborder Lari.[3] The buttonquails are of indeterminate or basal position in the Lari-Scolopaci sensu lato group. The arrangement as presented here is a consensus of the recent studies.[4]

Charadriiformes

Chionidi

Burhinidae


Burhinus



Esacus



Chionidae

Chionis


Pluvianellidae

Pluvianellus



Charadrii

Pluvianidae

Pluvianus


Ibidorhynchidae

Ibidorhyncha


Haematopodidae

Haematopus


Recurvirostridae


Himantopus



Cladorhynchus



Recurvirostra



Charadriidae

Charadriinae


Oreopholus



Phegornis



Zonibyx



Eudromias



Charadrius



Thinornis



Pluvialis



Elseyornis



Vanellinae

Vanellus


Anarhynchinae


Erythrogonys



Peltohyas



Eupoda



Anarhynchus



Ochthodromus





Thinocori

Pedionomidae

Pedionomus


Thinocoridae


Attagis



Thinocorus



Rostratulidae


Nycticryphes



Rostratula



Jacanidae


Hydrophasianus



Jacana



Actophilornis



Metopidius



Microparra



Irediparra




Scolopaci

Scolopacidae

Numeniinae


Bartramia



Numenius



Limosinae

Limosa


Arenariinae


Arenaria



Prosobonia



Calidris



Limicola



Ereunetes



Tringinae


Xenus



Phalaropus



Actitis



Tringa



Scolopacinae


Lymnocryptes



Limnodromus



Scolopax



Chubbia



Coenocorypha



Gallinago





Turnici


Ortyxelos



Turnix



Lari

Dromadidae

Dromas ardeola


Glareolidae


Rhinoptilus



Cursorius



Glareola



Stiltia



Stercorariidae

Stercorarius


Alcidae

Alcinae


Uria



Alle



Alca



Synthliboramphus



Cepphus



Brachyramphus



Pinguinus - Ex.



Fraterculinae


Cerorhinca



Fratercula



Ptychoramphus



Aethia




Laridae

Gyginae

Gygis


Rynchopinae

Rynchops


Anoinae

Anous


Sterninae


Onychoprion



Sternula



Phaetusa



Gelochelidon



Hydroprogne



Larosterna



Chlidonias



Thalasseus



Sterna



Larinae


Creagrus



Hydrocoloeus



Rhodostethia



Rissa



Pagophila



Xema



Saundersilarus



Chroicocephalus



Larus



Leucophaeus



Ichthyaetus







Cladogram based on Baker, A.J. et al. (2012)[5] and Boyd, J. H. et al. (2016) [3]

Evolution history

That the Charadriiformes are an ancient group is also borne out by the fossil record. Much of the Neornithes' fossil record around the Cretaceous–Paleogene extinction event is made up of bits and pieces of birds which resemble this order. In many, this is probably due to convergent evolution brought about by semiaquatic habits. Specimen VI 9901 (López de Bertodano Formation, Late Cretaceous of Vega Island, Antarctica) is probably a basal charadriiform somewhat reminiscent of a thick-knee.[6] However, more complete remains of undisputed charadriiforms are known only from the mid-Paleogene onwards. Present-day orders emerged around the Eocene-Oligocene boundary, roughly 35-30 mya. Basal or unresolved charadriiforms are:

The "transitional shorebirds" ("Graculavidae") are a generally Mesozoic form taxon formerly believed to constitute the common ancestors of charadriiforms, waterfowl and flamingos. They are now assumed to be mostly basal taxa of the charadriiforms and/or "higher waterbirds", which probably were two distinct lineages 65 mya already, and few if any are still believed to be related to the well-distinct waterfowl. Taxa formerly considered graculavids are:

Other wader- or gull-like birds incertae sedis, which may or may not be Charadriiformes, are:

Evolution of parental care in Charadriiformes

Shorebirds pursue a larger diversity of parental care strategies than do most other avian orders. They therefore present an attractive set of examples to support the understanding of the evolution of parental care in avians generally (as reviewed in Thomas et al. 2007). The ancestral avian most likely had a female parental care system (Tullberg et al. 2002). The shorebird ancestor specifically evolved from a bi-parental care system, yet the species within the clade Scolopacidae evolved from a male parental care system. These transitions might have occurred for several reasons. Brooding density is correlated with male parental care. Male care systems in birds are shown to have a very low breeding density while female care systems in birds have a high breeding density. (Owens 2005). Certain rates of male and female mortality, male and female egg maturation rate, and egg death rate have been associated with particular systems as well (Klug et al. 2013). It has also been shown that sex role reversal is motivated by the male-biased adult sex ratio (Liker et al. 2013). The reason for such diversity in shorebirds, compared to other birds, has yet to be understood.

See also

Footnotes

  1. Fain & Houde (2004)
  2. Ericson et al. (2003), Paton et al. (2003), Thomas et al. (2004a,b), van Tuinen et al. (2004), Paton & Baker (2006)
  3. 1 2 John, Boyd. "Charadriiformes". jboyd.net. Retrieved 2017-07-16.
  4. van Tuinen et al. (2004), Paton & Baker (2006)
  5. Baker, A.J. et al. (2012) Eight independent nuclear genes support monophyly of the plovers: The role of mutational variance in gene trees.
  6. Case, J. A. and C. P. Tambussi. 1999. Maastrichtian record of neornithine birds in Antarctica: comments on a Late Cretaceous radiation
  7. Proximal right humerus (MNZ S42416) and proximal left carpometacarpi (MNZ S42415, S42435) of a bird the size of a red-necked stint: Worthy et al. (2007)
  8. Several wing and thorax bones of a bird the size of a double-banded plover: Worthy et al. (2007)
  9. Premaxillae (MNZ S42681, S42736) and proximal right scapula (MNZ S41058) of a bird apparently similar to the black-billed gull but almost the size of a kelp gull: Worthy et al. (2007)
  10. Gál et al. (1998-99)
  11. A wading bird the size of a white stork (Ciconia ciconia): Bourdon (2005)

References

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