Woodcreepers
Cocoa woodcreeper
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Aves
Order: Passeriformes
Family: Furnariidae
Subfamily: Dendrocolaptinae
Genera

16, see article text

The woodcreepers (Dendrocolaptinae) comprise a subfamily of suboscine passerine birds endemic to the Neotropics. They have traditionally been considered a distinct family Dendrocolaptidae, but most authorities now place them as a subfamily of the ovenbirds (Furnariidae). They superficially resemble the Old World treecreepers, but they are unrelated and the similarities are due to convergent evolution. The subfamily contains 63 species in 16 genera.[1]

Woodcreepers range from 14 to 35 cm in length.[2][3] Generally brownish birds, the true woodcreepers maintain an upright vertical posture, supported by their specialized stiff tails.[4]

They feed mainly on insects taken from tree trunks. Some woodcreepers often form part of the core group at the centre of flocks attending army ant swarms. Woodcreepers are arboreal cavity-nesting birds; two or three white eggs are laid and incubated for about 15 to 21 days.[2]

These birds can be difficult to identify in that they tend to have similar brown upperparts, and the more distinctive underparts are hard to see on a bird pressed against a trunk in deep forest shade. The bill shape, extend/shape of spots/streaks, and call are useful aids to determining species.

Description

The wedge-billed woodcreeper is the smallest species in the subfamily (the xenops are smaller, but their exact taxonomic position has not been resolved).

The woodcreepers are generally fairly uniform in appearance. They range in size from the wedge-billed woodcreeper (13 cm (5.1 in)) to the strong-billed woodcreeper (35 cm (14 in)). Males tend to be slightly larger than females on average, but considerable overlap in size occurs in most species. Pronounced sexual dimorphism in size and plumage is rare. Bill size and shape accounts for much of the variation between the species. Bills can be straight or highly decurved, and can account for as much as a quarter of the length of the bird (as happens in the long-billed woodcreeper). The plumage is usually subdued and often brown, or sometimes rufous or other dark colours. Many species have patterns such as checking, spotting, or barring on their plumage. The feathers of the tail are rigid and are used for supporting the body when climbing tree trunks;[5][4] the tail can support most of the body weight and birds that lose their tail find climbing difficult. Woodcreepers climb by flexing their legs and hopping up the trunk. The feet of the woodcreepers are also modified for climbing. The front toes are strongly clawed and toe IV is as long as toe III to increase the ability of the bird to grasp around branches.[4] The legs are short but strong.[3] Woodcreepers are also characterized by a belly feather growth pattern not found in any other birds.

Habitat and distribution

The scimitar-billed woodcreeper is unusual for the subfamily in living in open woodlands, and in being predominately a ground forager.

The woodcreepers are generally forest birds of Central and South America. Most species occur in rainforests, with the centre of diversity of the subfamily being the Amazon Basin. As many as 19 species of woodcreeper may co-occur in some areas of the Amazon, although in other rainforests, such as those in Costa Rica, the numbers are much lower. Other habitats used by the woodcreepers include pine-oak woodland, montane cloud forest, and pine forests. A few species, like the scimitar-billed woodcreeper, inhabit savannah or other partly open environments. Woodcreepers are absent from the temperate forests of southern South America.[3]

Behaviour

Diet and feeding

The woodcreepers are insectivores that are mostly arboreal in nature. Insects form the majority of the diet, with some spiders, centipedes, millipedes and even lizards being taken as well. A few specimens collected by scientists had fruit or seeds in their stomachs, but plant material is not thought to be regularly taken by any species. A few species forage on the ground, but most forage on the trunks of trees, on and on the underside of branches. They are generally solitary or occur in pairs, but frequently join mixed-species feeding flocks. The flocks they join are usually the lower level ones rather than canopy flocks, and are usually those insectivorous ones rather than frugivorous ones. Prey is almost always obtained by moving up the trunk or branch, and there are two main foraging techniques, probing and sallying. Probers investigate rough bark, mosses, masses of trapped dead leaves, bromeliads, and other areas where prey may be hiding, whereas those that sally launch into the air briefly to snatch prey that has been flushed by their movement. Several species regularly attend swarms of army ants to catch prey flushed by the ants.[6]

Systematics

The former family has been merged into the ovenbird family, Furnariidae, by most authorities because analyses of mt and nDNA sequence data showed Sclerurus leaftossers and Geositta miners to be basal to the Furnariidae and the woodcreepers.[7] An alternative option was recommended by Moyle et al. (2009),[8] in which the woodcreepers maintain their status as a family, while the ovenbirds (as traditionally defined) are split into two families: Scleruridae and Furnariidae.

The genus Xenops, which have usually been considered ovenbirds, represent an early divergence. Although some analyses suggested that they are more closely related to the woodcreepers than to true furnariids,[9] other studies have not found the same results.[8][10] Others suggested placing Xenops in its own family Xenopidae.[11]

Evolutionary relationships among woodcreeper species are now fairly well known thanks to the use of DNA sequence data.[12][8][10] Some previous results based on morphology[13] were not supported by molecular data, mostly due to instances of convergent evolution in beak morphology.[12] Plumage patterns, on the other hand, are more in agreement with the molecular data.

DNA studies revealed that Deconychura species belong into separate genera[14] and that the Greater scythebill is not closely related to other scythebills in the genus Campylorhamphus but to Drymornis.[15] Moving Lepidocolaptes fuscus to Xiphorhynchus restores monophyly of Lepidocolaptes.

Additionally, the species-level taxonomy of several groups requires further study. Examples of "species" where vocal and morphological variations suggests that more than one species-level taxon could be involved are the curve-billed scythebill and the white-chinned, olivaceous, strong-billed and straight-billed woodcreepers. The genus Xiphorhynchus also requires much more research in this regard.[16][17] Hylexetastes may contain anything from one to four species.

A cladogram of the 16 woodcreeper genera based on the results of a 2020 molecular phylogenetic study of the suboscines by Michael Harvey and collaborators is shown below.[18]

Dendrocolaptinae

Glyphorynchus – wedge-billed woodcreeper

Certhiasomus – spot-throated woodcreeper

Dendrocincla – 6 species

Deconychura – long-tailed woodcreeper

Sittasomus – olivaceous woodcreeper

Xiphocolaptes – 4 species

Hylexetastes – 4 species

Dendrocolaptes – 5 species

Dendrexetastes – cinnamon-throated woodcreeper

Nasica – long-billed woodcreeper

Xiphorhynchus – 14 species

Dendroplex – 2 species

Campylorhamphus – 4 species (scythebills)

Lepidocolaptes – 11 species

Drymotoxeres – greater scythebill

Drymornis – scimitar-billed woodcreeper

Tribe Image Genus Species
Sittasomini – "intermediate" woodcreepers [8] Certhiasomus Derryberry et al., 2010
Deconychura Cherrie, 1891
Sittasomus Swainson, 1827
Dendrocincla G.R. Gray, 1840
Dendrocolaptini – "strong-billed" woodcreepers [8]
Glyphorynchus Wied-Neuwied, 1831
Nasica Lesson, 1830
Dendrexetastes Eyton, 1851
Dendrocolaptes Hermann, 1804
Hylexetastes P.L. Sclater, 1889
Xiphocolaptes Lesson, 1840
Dendroplex Swainson, 1827
Xiphorhynchus Swainson, 1827 (possibly polyphyletic)
Campylorhamphus W. Bertoni, 1901
Drymotoxeres Claramunt, Derryberry, Chesser, RT, Aleixo & Brumfield, 2010
Drymornis Eyton, 1852
Lepidocolaptes Reichenbach, 1853

References

  1. Gill, Frank; Donsker, David; Rasmussen, Pamela, eds. (January 2023). "Ovenbirds, woodcreepers". IOC World Bird List Version 13.1. International Ornithologists' Union. Retrieved 8 March 2023.
  2. 1 2 Willis, Edwin O. (1991). Forshaw, Joseph (ed.). Encyclopaedia of Animals: Birds. London: Merehurst Press. p. 163. ISBN 1-85391-186-0.
  3. 1 2 3 Marantz, C. A.; Aleixo, A.; Bevier, L. R.; Patten, M. A., (2003): Family Dendrocolaptidae (Woodcreepers). In: del Hoyo, Josep; Elliott, Andrew & Sargatal, Jordi (editors): Handbook of Birds of the World, Volume 6: Broadbills to Tapaculos: 358–447. Lynx Edicions, Barcelona. ISBN 84-87334-50-4
  4. 1 2 3 Claramunt, Santiago; Derryberry, Elizabeth P.; Brumfield, Robb T.; Remsen, J. V. (2012). "Ecological Opportunity and Diversification in a Continental Radiation of Birds: Climbing Adaptations and Cladogenesis in the Furnariidae". The American Naturalist. 179 (5): 649–666. doi:10.1086/664998. ISSN 0003-0147. PMID 22504546. S2CID 205998536.
  5. Tubaro, Pablo L.; Lijtmaer, Dario A.; Palacios, Maria G.; Kopuchian, Cecilia (2002). "Adaptive Modification of Tail Structure in Relation to Body Mass and Buckling in Woodcreepers". The Condor. 104 (2): 281–296. doi:10.1650/0010-5422(2002)104[0281:AMOTSI]2.0.CO;2. hdl:11336/136482. JSTOR 1370031. S2CID 85776837.
  6. Willis, E.; Oniki, Y. (1978). "Birds and Army Ants". Annual Review of Ecology and Systematics. 9: 243–263. doi:10.1146/annurev.es.09.110178.001331. JSTOR 2096750.
  7. Irestedt, Martin; Fjeldså, Jon; Johansson, Ulf S.; Ericson, Per G.P. (2002). "Systematic relationships and biogeography of the tracheophone suboscines (Aves: Passeriformes)". Molecular Phylogenetics and Evolution. 23 (3): 499–512. doi:10.1016/S1055-7903(02)00034-9. PMID 12099801.
  8. 1 2 3 4 5 Moyle, R. G.; Chesser, R. T.; Brumfield, R. T.; Tello, J. G.; Marchese, D. J.; Cracraft, J. (2009). "Phylogeny and phylogenetic classification of the antbirds, ovenbirds, woodcreepers, and allies (Aves: Passeriformes: infraorder Furnariides)". Cladistics. 25 (4): 386–405. doi:10.1111/j.1096-0031.2009.00259.x. PMID 34879609.
  9. Fjeldså, Jon; Irestedt, Martin; Ericson, Per G. P. (2005). "Molecular data reveal some major adaptational shifts in the early evolution of the most diverse avian family, the Furnariidae" (PDF). Journal of Ornithology. 146: 1–13. doi:10.1007/s10336-004-0054-5. S2CID 11581358.
  10. 1 2 Derryberry, Elizabeth P.; Claramunt, Santiago; Derryberry, Graham; Chesser, R. Terry; Cracraft, Joel; Aleixo, Alexandre; Pérez-Emán, Jorge; Remsen Jr., J. V.; Brumfield, Robb T. (2011). "Lineage diversification and morphological evolution in a large-scale continental radiation: the Neotropical ovenbirds and woodcreepers (Aves: Furnariidae)". Evolution. 65 (10): 2973–2986. doi:10.1111/j.1558-5646.2011.01374.x. ISSN 0014-3820. PMID 21967436.
  11. Ohlson, J; Irestedt, M; Ericson, P; Fjeldså, J (2013). "Phylogeny and classification of the New World suboscines (Aves, Passeriformes)". Zootaxa. 3613 (1): 1–35. doi:10.11646/zootaxa.3613.1.1. PMID 24698900.
  12. 1 2 Irestedt, Martin; Fjeldså, Jon; Ericson, Per G. P. (2004). "Phylogenetic relationships of woodcreepers (Aves: Dendrocolaptinae) – incongruence between molecular and morphological data" (PDF). Journal of Avian Biology. 35 (3): 280–288. doi:10.1111/j.0908-8857.2004.03234.x.
  13. Raikow, Robert J. (1994). "A phylogeny of the woodcreepers (Dendrocolaptinae)" (PDF). Auk. 111 (1): 104–114. doi:10.2307/4088509. JSTOR 4088509.
  14. Derryberry, E.; Claramunt, S.; Chesser, R. T.; Aleixo, A.; Cracraft, J.; Moyle, R. G.; Brumfield, R. T. (2010). "Certhiasomus, a new genus of woodcreeper (Aves: Passeriformes: Dendrocolaptidae)". Zootaxa. 2416: 44–50. doi:10.11646/zootaxa.2416.1.2.
  15. Claramunt, Santiago; Derryberry, Elizabeth P.; Chesser, R. Terry; Aleixo, Alexandre; Brumfield, Robb T. (2010). "Polyphyly of Campylorhamphus, and description of a new genus for C. pucherani (Dendrocolaptinae)". Auk. 127 (2): 430–439. doi:10.1525/auk.2009.09022.
  16. Aleixo, Alexandre (2002). Molecular systematics, phylogeography, and population genetics of Xiphorhynchus (Aves: Dendrocolaptidae) in the Amazon basin (PDF). Ph.D. dissertation, Louisiana State University, Baton Rouge, LA.
  17. Aleixo, Alexandre (2002). "Molecular Systematics and the Role of the "Várzea"-"Terra-Firme" Ecotone in the Diversification of Xiphorhynchus Woodcreepers (Aves: Dendrocolaptidae)" (PDF). Auk. 119 (3): 621–640. doi:10.1642/0004-8038(2002)119[0621:MSATRO]2.0.CO;2. S2CID 55344179.
  18. Harvey, M.G.; Bravo, G.A.; Claramunt, S.; Cuervo, A.M.; Derryberry, G.E.; Battilana, J.; Seeholzer, G.F.; McKay, J.S.; O'Meara, B.C.; Faircloth, B.C.; Edwards, S.V.; Pérez-Emán, J.; Moyle, R.G.; Sheldon, F.H.; Aleixo, A.; Smith, B.T.; Chesser, R.T.; Silveira, L.F.; Cracraft, J.; Brumfield, R.T.; Derryberry, E.P. (2020). "The evolution of a tropical biodiversity hotspot". Science. 370 (6522): 1343–1348. doi:10.1126/science.aaz6970. hdl:10138/329703. PMID 33303617. S2CID 228084618. A high resolution version of the phylogenetic tree in Figure 1 is available from the first author's website here.


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