Passerine Explained

A passerine is any bird of the order Passeriformes (; from Latin Latin: passer 'sparrow' and Latin: formis '-shaped') which includes more than half of all bird species. Sometimes known as perching birds, passerines generally have an anisodactyl arrangement of their toes (three pointing forward and one back), which facilitates perching.

With more than 140 families and some 6,500 identified species,[1] Passeriformes is the largest order of birds and among the most diverse clades of terrestrial vertebrates, representing 60% of birds.[2] [3] Passerines are divided into three suborders: Acanthisitti (New Zealand wrens), Tyranni (composed mostly of South American suboscines), and Passeri (oscines or songbirds).[4] Passerines originated in the Southern Hemisphere around 60 million years ago.[5]

Most passerines are insectivorous or omnivorous, and eat both insects and fruit or seeds.

The terms "passerine" and "Passeriformes" are derived from the scientific name of the house sparrow, Passer domesticus, and ultimately from the Latin term passer, which refers to sparrows and similar small birds.

Description

The order is divided into three suborders, Tyranni (suboscines), Passeri (oscines or songbirds), and the basal Acanthisitti.[6] Oscines have the best control of their syrinx muscles among birds, producing a wide range of songs and other vocalizations, though some of them, such as the crows, do not sound musical to human beings. Some, such as the lyrebird, are accomplished mimics.[7] The New Zealand wrens are tiny birds restricted to New Zealand, at least in modern times; they were long placed in Passeri.

Most passerines are smaller than typical members of other avian orders. The heaviest and altogether largest passerines are the thick-billed raven[8] and the larger races of common raven, each exceeding 1.5kg (03.3lb) and 70cm (30inches). The superb lyrebird and some birds-of-paradise, due to very long tails or tail coverts, are longer overall. The smallest passerine is the short-tailed pygmy tyrant, at 6.5cm (02.6inches) and 4.2g.[9]

Anatomy

The foot of a passerine has three toes directed forward and one toe directed backward, called anisodactyl arrangement. The hind toe (hallux) is long and joins the leg at approximately the same level as the front toes. This arrangement enables passerine birds to easily perch upright on branches. The toes have no webbing or joining, but in some cotingas, the second and third toes are united at their basal third.

The leg of passerine birds contains an additional special adaptation for perching. A tendon in the rear of the leg running from the underside of the toes to the muscle behind the tibiotarsus will automatically be pulled and tighten when the leg bends, causing the foot to curl and become stiff when the bird lands on a branch. This enables passerines to sleep while perching without falling off.[10] [11]

Most passerine birds have 12 tail feathers but the superb lyrebird has 16,[12] and several spinetails in the family Furnariidae have 10, 8, or even 6, as is the case of Des Murs's wiretail. Species adapted to tree trunk climbing such as treecreepers and woodcreeper have stiff tail feathers that are used as props during climbing.[13] Extremely long tails used as sexual ornaments are shown by species in different families. A well-known example is the long-tailed widowbird.

Eggs and nests

See also: List of brood parasitic passerines. The chicks of passerines are altricial: blind, featherless, and helpless when hatched from their eggs. Hence, the chicks require extensive parental care. Most passerines lay colored eggs, in contrast with nonpasserines, most of whose eggs are white except in some ground-nesting groups such as Charadriiformes and nightjars, where camouflage is necessary, and in some parasitic cuckoos, which match the passerine host's egg. The vinous-throated parrotbill has two egg colors, white and blue, to deter the brood parasitic common cuckoo.

Clutches vary considerably in size: some larger passerines of Australia such as lyrebirds and scrub-robins lay only a single egg, most smaller passerines in warmer climates lay between two and five, while in the higher latitudes of the Northern Hemisphere, hole-nesting species like tits can lay up to a dozen and other species around five or six.The family Viduidae do not build their own nests, instead, they lay eggs in other birds' nests.

The Passeriformes contain several groups of brood parasites such as the viduas, cuckoo-finches, and the cowbirds.

Origin and evolution

The evolutionary history of the passerine families and the relationships among them remained rather mysterious until the late 20th century. In many cases, passerine families were grouped together on the basis of morphological similarities that, it is now believed, are the result of convergent evolution, not a close genetic relationship. For example, the wrens of the Americas and Eurasia, those of Australia, and those of New Zealand look superficially similar and behave in similar ways, yet belong to three far-flung branches of the passerine family tree; they are as unrelated as it is possible to be while remaining Passeriformes.

Advances in molecular biology and improved paleobiogeographical data gradually are revealing a clearer picture of passerine origins and evolution that reconciles molecular affinities, the constraints of morphology, and the specifics of the fossil record.[14] The first passerines are now thought to have evolved in the Southern Hemisphere in the late Paleocene or early Eocene, around 50 million years ago.[15] [5]

The initial diversification of passerines coincides with the separation of the southern continents in the early Eocene. The New Zealand wrens are the first to become isolated in Zealandia, and the second split involved the origin of the Tyranni in South America and the Passeri in the Australian continent.[2] [5] [3] The Passeri experienced a great radiation of forms in Australia. A major branch of the Passeri, the parvorder Passerida, dispersed into Eurasia and Africa about 40 million years ago, where they experienced further radiation of new lineages.[5] This eventually led to three major Passerida lineages comprising about 4,000 species, which in addition to the Corvida and numerous minor lineages make up songbird diversity today. Extensive biogeographical mixing happens, with northern forms returning to the south, southern forms moving north, and so on.[3]

Fossil record

Earliest passerines

Perching bird osteology, especially of the limb bones, is rather diagnostic.[16] [17] However, the early fossil record is poor because passerines are relatively small, and their delicate bones do not preserve well. Queensland Museum specimens F20688 (carpometacarpus) and F24685 (tibiotarsus) from Murgon, Queensland, are fossil bone fragments initially assigned to Passeriformes.[16] However, the material is too fragmentary and their affinities have been questioned.[18] Several more recent fossils from the Oligocene of Europe, such as Wieslochia, Jamna, Resoviaornis, and Crosnoornis,[19] are more complete and definitely represent early passeriforms, and have been found to belong to a variety of modern and extinct lineages.[20]

From the Bathans Formation at the Manuherikia River in Otago, New Zealand, MNZ S42815 (a distal right tarsometatarsus of a tui-sized bird) and several bones of at least one species of saddleback-sized bird have recently been described. These date from the Early to Middle Miocene (Awamoan to Lillburnian, 19–16 mya).[21]

Early European passerines

In Europe, perching birds are not too uncommon in the fossil record from the Oligocene onward, belonging to several lineages:

That suboscines expanded much beyond their region of origin is proven by several fossils from Germany such as a presumed broadbill (Eurylaimidae) humerus fragment from the Early Miocene (roughly 20 mya) of Wintershof, Germany, the Late Oligocene carpometacarpus from France listed above, and Wieslochia, among others.[17] [5] Extant Passeri super-families were quite distinct by that time and are known since about 12–13 mya when modern genera were present in the corvoidean and basal songbirds. The modern diversity of Passerida genera is known mostly from the Late Miocene onward and into the Pliocene (about 10–2 mya). Pleistocene and early Holocene lagerstätten (<1.8 mya) yield numerous extant species, and many yield almost nothing but extant species or their chronospecies and paleosubspecies.

American fossils

See also: Late Quaternary prehistoric birds. In the Americas, the fossil record is more scant before the Pleistocene, from which several still-existing families are documented. Apart from the indeterminable MACN-SC-1411 (Pinturas Early/Middle Miocene of Santa Cruz Province, Argentina), an extinct lineage of perching birds has been described from the Late Miocene of California, United States: the Palaeoscinidae with the single genus Palaeoscinis. "Palaeostruthus" eurius (Pliocene of Florida) probably belongs to an extant family, most likely passeroidean.

Systematics and taxonomy

The Passeriformes is currently divided into three suborders: Acanthisitti (New Zealand wrens), Tyranni, (suboscines) and Passeri (oscines or songbirds). The Passeri is now subdivided into two major groups recognized now as Corvides and Passerida respectively containing the large superfamilies Corvoidea and Meliphagoidea, as well as minor lineages, and the superfamilies Sylvioidea, Muscicapoidea, and Passeroidea but this arrangement has been found to be oversimplified. Since the mid-2000s, studies have investigated the phylogeny of the Passeriformes and found that many families from Australasia traditionally included in the Corvoidea actually represent more basal lineages within oscines. Likewise, the traditional three-superfamily arrangement within the Passeri has turned out to be far more complex and will require changes in classification.

Major "wastebin" families such as the Old World warblers and Old World babblers have turned out to be paraphyletic and are being rearranged. Several taxa turned out to represent highly distinct lineages, so new families had to be established, some of theirs – like the stitchbird of New Zealand and the Eurasian bearded reedling – monotypic with only one living species.[24] In the Passeri alone, a number of minor lineages will eventually be recognized as distinct superfamilies. For example, the kinglets constitute a single genus with less than 10 species today but seem to have been among the first perching bird lineages to diverge as the group spread across Eurasia. No particularly close relatives of theirs have been found among comprehensive studies of the living Passeri, though they might be fairly close to some little-studied tropical Asian groups. Nuthatches, wrens, and their closest relatives are currently grouped in a distinct super-family Certhioidea.

Taxonomic list of Passeriformes families

This list is in taxonomic order, placing related families next to one another. The families listed are those recognised by the International Ornithologists' Union (IOC).[1] The order and the division into infraorders, parvorders, and superfamilies follows the phylogenetic analysis published by Carl Oliveros and colleagues in 2019.[25] The relationships between the families in the suborder Tyranni (suboscines) were all well determined but some of the nodes in Passeri (oscines or songbirds) were unclear owing to the rapid splitting of the lineages.[25]

Suborder Acanthisitti

Suborder Tyranni (suboscines)

Infraorder Eurylaimides: Old World suboscinesInfraorder Tyrannides: New World suboscines
Parvorder FurnariidaParvorder Tyrannida

Suborder Passeri (oscines or songbirds)

Phylogeny

Relationships between living Passeriformes families based on the phylogenetic analysis of Oliveros et al (2019).[25] Some terminals have been renamed to reflect families recognised by the IOC but not in that study.[1] The IOC families Alcippeidae and Teretistridae were not sampled in this study.

Further reading

Notes and References

  1. Web site: Gill . Frank . Frank Gill (ornithologist) . Donsker . David . Rasmussen . Pamela . Pamela Rasmussen . 2020 . Family Index . IOC World Bird List Version 10.1 . International Ornithologists' Union . 26 April 2020 .
  2. Ericson, P.G.P. et al. (2003) Evolution, biogeography, and patterns of diversification in passerine birds. J. Avian Biol, 34:3–15.
  3. Selvatti, A.P. et al. (2015) "A Paleogene origin for crown passerines and the diversification of the Oscines in the New World". Molecular Phylogenetics and Evolution, 88:1–15.
  4. 10.1098/rspb.2001.1883. A phylogenetic hypothesis for passerine birds: Taxonomic and biogeographic implications of an analysis of nuclear DNA sequence data. Proceedings of the Royal Society B: Biological Sciences. 269. 1488. 295–308. 2002. Barker. F. Keith. Barrowclough. George F.. Groth. Jeff G.. 11839199 . 1690884.
  5. Claramunt . S. . Cracraft . J. . A new time tree reveals Earth history's imprint on the evolution of modern birds . Science Advances . 2015 . 1 . 11 . e1501005 . 10.1126/sciadv.1501005 . 4730849 . 26824065. 2015SciA....1E1005C .
  6. Book: Chatterjee, Sankar. The Rise of Birds: 225 Million Years of Evolution. JHU Press. 2015. 9781421415901. 206–207.
  7. Winkler, D. W., S. M. Billerman, and I.J. Lovette (2020). Lyrebirds (Menuridae), version 1.0. In Birds of the World (S. M. Billerman, B. K. Keeney, P. G. Rodewald, and T. S. Schulenberg, Editors). Cornell Lab of Ornithology, Ithaca, New York, US. https://doi.org/10.2173/bow.menuri1.01
  8. Madge, S. (2020). Thick-billed Raven (Corvus crassirostris), version 1.0. In Birds of the World (J. del Hoyo, A. Elliott, J. Sargatal, D. A. Christie, and E. de Juana, Editors). Cornell Lab of Ornithology, Ithaca, New York, US. https://doi.org/10.2173/bow.thbrav1.01
  9. Clock, B. (2020). Short-tailed Pygmy-Tyrant (Myiornis ecaudatus), version 1.0. In Birds of the World (J. del Hoyo, A. Elliott, J. Sargatal, D. A. Christie, and E. de Juana, Editors). Cornell Lab of Ornithology, Ithaca, New York, US. https://doi.org/10.2173/bow.stptyr1.01
  10. Book: Stefoff, Rebecca . 2008. 9780761426936. The Bird Class . Marshall Cavendish Benchmark.
  11. Brooke, Michael and Birkhead, Tim (1991) The Cambridge Encyclopedia of Ornithology, Cambridge University Press .
  12. Jones, D. (2008) "Flight of fancy". Australian Geographic, (89), 18–19.
  13. Claramunt . Santiago . Derryberry . Elizabeth P. . Brumfield . Robb T. . Remsen . J. V. . May 2012 . Ecological Opportunity and Diversification in a Continental Radiation of Birds: Climbing Adaptations and Cladogenesis in the Furnariidae . The American Naturalist . en . 179 . 5 . 649–666 . 10.1086/664998 . 22504546 . 205998536 . 0003-0147.
  14. 10.1111/j.1096-3642.2004.00118.x. The evolutionary radiation of modern birds (Neornithes): Reconciling molecules, morphology and the fossil record. June 2004. Dyke. Gareth J.. Van Tuinen. Marcel. Zoological Journal of the Linnean Society. 141. 2. 153–177. free.
  15. 1690883. 11839192. 7 February 2002. Ericson. P.G.. Christidis. L.. Cooper. A.. Irestedt. M.. Jackson. J.. Johansson. U.S.. Norman. J.A.. A Gondwanan origin of passerine birds supported by DNA sequences of the endemic New Zealand wrens. 269. 1488. 235–241. 10.1098/rspb.2001.1877. Proceedings of the Royal Society B.
  16. Boles, Walter E. . 1997. Fossil songbirds (Passeriformes) from the Early Eocene of Australia. . 97. 1. 43–50. 10.1071/MU97004. 1997EmuAO..97...43B .
  17. Manegold, Albrecht . Mayr, Gerald . Mourer-Chauviré, Cécile . amp . 2004. Miocene Songbirds and the Composition of the European Passeriform Avifauna. . 121. 4. 1155–1160. 10.1642/0004-8038(2004)121[1155:MSATCO]2.0.CO;2. 73668280 . free.
  18. Mayr . G . The age of the crown group of passerine birds and its evolutionary significance–molecular calibrations versus the fossil record . Systematics and Biodiversity . 2013 . 11 . 1 . 7–13 . 10.1080/14772000.2013.765521. 2013SyBio..11....7M . 85167051 .
  19. Bochenski, Z.M., Tomek, T., Bujoczek, M. (2021) A new passeriform (Aves: Passeriformes) from the early Oligocene of Poland sheds light on the beginnings of Suboscines. J Ornithol. https://doi.org/10.1007/s10336-021-01858-0
  20. Lowi-Merri . Talia M. . Gjevori . Martina . Bochenski . Zbigniew M. . Wertz . Krzysztof . Claramunt . Santiago . 2024-12-31 . Total-evidence dating and the phylogenetic affinities of early fossil passerines . Journal of Systematic Palaeontology . en . 22 . 1 . 10.1080/14772019.2024.2356086 . 1477-2019.
  21. Worthy, Trevor H. . Tennyson, A.J.D. . Jones, C. . McNamara, J.A. . Douglas, B.J. . 2007. Miocene waterfowl and other birds from central Otago, New Zealand. . 5. 1. 1–39. 10.1017/S1477201906001957. 2007JSPal...5....1W . Trevor H. Worthy . 2440/43360 . 85230857 . free .
  22. Hugueney, Marguerite . Berthet, Didier . Bodergat, Anne-Marie . Escuillié, François . Mourer-Chauviré, Cécile . Wattinne, Aurélia . amp . 2003. La limite Oligocène-Miocène en Limagne: changements fauniques chez les mammifères, oiseaux et ostracodes des différents niveaux de Billy-Créchy (Allier, France) . The Oligocene-Miocene boundary in Limagne: faunal changes in the mammals, birds and ostracods from the different levels of Billy-Créchy (Allier, France). Geobios. 36. 6. 719–731. 10.1016/j.geobios.2003.01.002. 2003Geobi..36..719H .
  23. Mayr . Gerald . Manegold . Albrecht . amp . 2006. A Small Suboscine-like Passeriform Bird from the Early Oligocene of France. . 108. 3. 717–720. 10.1650/0010-5422(2006)108[717:ASSPBF]2.0.CO;2 . free .
  24. The former does not even have recognized subspecies, while the latter is one of the most singular birds alive today. Good photos of a bearded reedling are for example here and here .
  25. Oliveros . C.H. . etal . 2019 . Earth history and the passerine superradiation . Proceedings of the National Academy of Sciences of the United States of America . 116 . 16 . 7916–7925 . 10.1073/pnas.1813206116 . 30936315 . free . 6475423 . 2019PNAS..116.7916O .
  26. Book: Cracraft, Joel . Avian higher-level relationships and classification: passeriformes . Dickinson . E.C. . Edward C. Dickinson . Christidis . L. . Leslie Christidis . 2014 . The Howard & Moore Complete Checklist of the Birds of the World . 2: Passerines . 4th . Eastbourne, UK . Aves Press . 978-0-9568611-2-2 . xvii-xxxiii [xxiv].