Parrotbill

The parrotbills (sometimes called crow-tits) are a group of peculiar birds native to East and Southeast Asia, though feral populations exist elsewhere. They are generally small, long-tailed birds which inhabit reedbeds and similar habitat. They feed mainly on seeds, e.g. of grasses, to which their bill, as the name implies, is well-adapted. Living in tropical to southern temperate climates, they are usually non-migratory.

Parrotbill
White-breasted parrotbill
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Aves
Order: Passeriformes
Superfamily: Sylvioidea
Family: Paradoxornithidae
Penhallurick & Robson, 2009
Genera

The bearded reedling or "bearded tit", a Eurasian species long placed here, is more insectivorous by comparison, especially in summer. It also strikingly differs in morphology, and was time and again placed in a monotypic family Panuridae. DNA sequence data supports this.

As names like "bearded tit" imply, their general habitus and acrobatic habits resemble birds like the long-tailed tits. Together with these and others they were at some time placed in the titmouse family Paridae. Later studies found no justification to presume a close relationship between all these birds, and consequently the parrotbills and bearded reedling were removed from the tits and chickadees and placed into a distinct family, Paradoxornithidae. As names like Paradoxornis paradoxus – "puzzling, paradox bird" – suggest, their true relationships were very unclear, although by the latter 20th century they were generally seen as close to Timaliidae ("Old World babblers") and Sylviidae ("Old World warblers").

Since 1990 (Sibley & Ahlquist 1990),[1] molecular data has been added to aid the efforts of discovering the parrotbills' true relationships. As Paradoxornis species are generally elusive and in many cases little-known birds, usually specimens of the bearded reedling which are far more easy to procure were used for the analyses. Often, the entire group was entirely left out of analyses, being small and seemingly insignificant in the large pattern of bird evolution (e.g. Barker et al. 2002, 2004). The bearded reedling tended to appear close to larks in phylogenies based on e.g. DNA-DNA hybridization (Sibley & Ahlquist 1990), or on mtDNA cytochrome b and nDNA c-myc exon 3, RAG-1 and myoglobin intron 2 sequence data (Ericson & Johansson 2003). Placement in a superfamily Sylvioidea which contained birds such as Sylviidae, Timaliidae and long-tailed tits – but not Paridae – was confirmed.

Cibois (2003a) analyzed mtDNA cytochrome b and 12S/16S rRNA sequences of some Sylvioidea, among them several species of Paradoxornis but not the bearded reedling. These formed a robust clade closer to the Sylvia typical warblers and some presumed "Old World babblers" such as Chrysomma sinense than to other birds. The puzzle was finally resolved by Alström et al. (2006), who studied mtDNA cytochrome b and nDNA myoglobin intron 2 sequences of a wider range of Sylvioidea: The bearded reedling was not a parrotbill at all, but forms a distinct lineage on its own, the relationships of which are not entirely resolved at present. The parrotbills' presence in the clade containing Sylvia, on the other hand, necessitates that the Paradoxornithidae are placed in synonymy of the Sylviidae. Cibois (2003b) even suggested that these themselves were to be merged with the remaining Timaliidae and the latter name to be adopted. This has hitherto not been followed and researchers remain equivocal as many taxa in Sylviidae and Timaliidae remain to be tested for their relationships. In any case, it is most likely that the typical warbler-parrotbill group is monophyletic and therefore agrees with the modern requirements for a taxon. Hence, whether to keep or to synonymize it is entirely a matter of philosophy, as the scientific facts would agree with either approach.

The interesting conclusion from an evolutionary point of view is that the morphologically both internally homogenous and compared to each other highly dissimilar typical warblers and parrotbills form the two extremes in the divergent evolution of the Sylviidae. This is underscored by looking at the closest living relatives of the parrotbills in the rearranged Sylviidae: The genus Chrysomma are non-specialized species altogether intermediate in habitus, habitat and habits between the typical warblers and the parrotbills. Presumably, the ancestral sylviids looked much like these birds. How dramatic the evolutionary changes wrought upon the parrotbills in their adaptation to feeding on grass caryopses and similar seeds were can be seen by comparing them with the typical fulvettas, which were formerly considered Timaliidae and united with the alcippes (Pasquet 2006). These look somewhat like drab fairy-wrens and have none of the parrotbills' adaptations to food and habitat. Yet it appears that the typical fulvettas' and parrotbills' common ancestor evolved into at least two parrotbill lineages independently (Cibois 2003a) & (Yeung et al. 2006). Only the wrentit, the only American sylviid, resembles the parrotbills much in habitus, though not in color pattern, and of course, as an insectivore, neither in bill shape.

Species of parrotbills

There are 37 species of parrotbills and allies distributed among 16 genera.[2] This list is presented according to the IOC taxonomic sequence and can also be sorted alphabetically by common name and binomial.

Common nameBinomial nameIOC sequence
Fire-tailed myzornisMyzornis pyrrhoura1
Rufous-tailed babblerMoupinia poecilotis2
Golden-breasted fulvettaLioparus chrysotis3
Yellow-eyed babblerChrysomma sinense4
Jerdon's babblerChrysomma altirostre5
Tarim babblerRhopophilus albosuperciliaris6
Beijing babblerRhopophilus pekinensis7
Spectacled fulvettaFulvetta ruficapilla8
Indochinese fulvettaFulvetta danisi9
Chinese fulvettaFulvetta striaticollis10
White-browed fulvettaFulvetta vinipectus11
Brown-throated fulvettaFulvetta ludlowi12
Manipur fulvettaFulvetta manipurensis13
Grey-hooded fulvettaFulvetta cinereiceps14
Taiwan fulvettaFulvetta formosana15
WrentitChamaea fasciata16
Reed parrotbillCalamornis heudei17
Black-breasted parrotbillParadoxornis flavirostris18
Spot-breasted parrotbillParadoxornis guttaticollis19
Great parrotbillConostoma aemodium20
Brown parrotbillCholornis unicolor21
Three-toed parrotbillCholornis paradoxus22
Grey-headed parrotbillPsittiparus gularis23
Black-headed parrotbillPsittiparus margaritae24
White-breasted parrotbillPsittiparus ruficeps25
Rufous-headed parrotbillPsittiparus bakeri26
Short-tailed parrotbillNeosuthora davidiana27
Fulvous parrotbillSuthora fulvifrons28
Black-throated parrotbillSuthora nipalensis29
Golden parrotbillSuthora verreauxi30
Pale-billed parrotbillChleuasicus atrosuperciliaris31
Spectacled parrotbillSinosuthora conspicillata32
Grey-hooded parrotbillSinosuthora zappeyi33
Brown-winged parrotbillSinosuthora brunnea34
Vinous-throated parrotbillSinosuthora webbiana35
Ashy-throated parrotbillSinosuthora alphonsiana36
Przevalski's parrotbillSinosuthora przewalskii37

Parrotbill egg recognition

Parrotbill egg recognition is the ability of the parrotbill to distinguish its own eggs against the eggs of a brood parasite.[3] Without their own eggs in the nest, parrotbills are not able to identify whether their nest has been intruded by the eggs of a brood parasite.[3] Because the colour and number of eggs may vary, there are varying outcomes to whether parrotbills will reject or accept the eggs whether it be their own or if they are acting host for another species.[3] Cognitive mechanisms including recognition by discordance and template-based recognition are hypothesized to be the manner in which a host's eggs are identified.[4] The common cuckoo lays its eggs in the nests of parrotbills and the two have co-evolved together over time to promote the reproductive success of both species.[5] The common cuckoo is an example of an avian brood parasite that reduces the energy cost of caring for its eggs by placing them in the parrotbill's nest.[3]

Depending on the parrotbill species, the eggs will either be maculate with spots or marks or immaculate, meaning without spots or marks.[3][6] The cuckoo is also able to lay eggs that replicate the ones of its hosts in a means to have its eggs accepted by the host.[3] Whether the parasitic eggs are accepted by the host is based on two hypothetical cognitive mechanisms.[3] True or template-based recognition predicts that by learning or by instinct, the parrotbill would be able to reject the brood parasite eggs.[3] If learned, the parrotbill would imprint on its own eggs and would be able to use it as a template to compare to foreign eggs.[3] Recognition by discordancy is the least favoured hypothesis among scientists of the two mechanisms, but describes the action of rejecting the eggs which appear to be the minority whether it is their own eggs or the parasite's eggs; it does not require learning or instinctive behaviour.[3] Some studies have predicted discordancy is favoured as certain species demonstrate the behaviour at all life stages; if the behaviour is demonstrated at a young age, it may not be an example of learning as the time for learning could be too short.[4]

One parrotbill species that has been studied is the ashy-throated parrotbill (Paradoxornis alphonsianus) and demonstrated the use of both mechanisms relaying there may not be one "universal method".[3] The eggs of the ashy-throated parrotbill are immaculate and polymorphic in which multiple phenotypic colours in that species is produced; its eggs are placed in competition with the eggs of the common cuckoo (Cuculus canorus).[3] Typically, the female cuckoo lays its eggs in the nest of the parrotbill after taking out one of the host's eggs.[4] The immaculate colours in this species are blue, pale blue and white, but only one colour is present at a time and the female produces only one colour over its lifetime.[3][4]

If parrotbills do not have their own eggs within the nest, it has been observed they accept the eggs of the avian brood parasite, as the "cue" of the presence of their own eggs has not been established.[3] Time is also important for both male and female parrotbills as it can be the factor in whether the parrotbill will recognize parasitic eggs.[4] For females, it is crucial they learn the egg phenotype as the eggs are being laid, but if this learning is not immediate, parasitic eggs can be accepted and imprinted.[4] Males learn their respective egg phenotype once the clutch has reached completion.[4]

In some species, male parrotbills also incubate eggs, and they are predicted to follow discordancy recognition for this behaviour as the males may encounter multiple egg types with different mates over time.[3] This could lead to rejection of their own eggs based on previous knowledge of egg colour.[3] A possible exception to this idea is if the host parrotbill produces eggs that are monomorphic.[4] If male parrotbills do not imprint on their own eggs, they increase the probability of production of varied phenotypes of egg colour and patterns within the population.[4]

If a host species is new to an area, it is suspected cuckoo parasitism will be favoured as recognition of parasitic eggs has not yet occurred.[5] Over time, the two species co-evolve with the parrotbill first utilizing one of the hypothesized cognitive mechanisms in order to recognize parasitic eggs.[4] In order to compensate for this new behaviour in parrotbills, the parasite produces eggs that are similar to those of the host and leads to the evolution of polymorphisms over time for both species.[4]

References

  1. Ricklefs, Robert E. "Small clades at the periphery of passerine morphological space." The American Naturalist 165.6 (2005): 651–659.
  2. Gill, F.; Donsker, D.; Rasmussen, P. (July 2020). "IOC World Bird List (v 10.2)". Retrieved July 15, 2020.
  3. Yang, C., Møller, A. P., Røskaft, E., Moksnes, A., Liang, W., & Stokke, B. (2014). Reject the odd egg: Egg recognition mechanisms in parrotbills. Behavioral Ecology, 25(6), 1320–1324. doi:10.1093/beheco/aru124
  4. Liang, W., Yang, C., Antonov, A., Fossøy, F., Stokke, B., Moksnes, A., et al. (2012). Sex roles in egg recognition and egg polymorphism in avian brood parasitism. Behavioral Ecology, 23(2), 397–402. doi:10.1093/beheco/arr203
  5. Yang, C., Li, D., Wang, L., Liang, G., Zhang, Z., & Liang, W. (2014). Geographic variation in parasitism rates of two sympatric cuckoo hosts in china. Zoological Research, 35(1), 67–71.
  6. "the definition of immaculate". Dictionary.com. Retrieved 2017-11-18.
  • Alström, Per; Ericson, Per G.P.; Olsson, Urban & Sundberg, Per (2006): Phylogeny and classification of the avian superfamily Sylvioidea. Molecular Phylogenetics and Evolution 38(2): 381–397. doi:10.1016/j.ympev.2005.05.015 PMID 16054402
  • Barker, F. Keith; Barrowclough, George F. & Groth, Jeff G. (2002): A phylogenetic hypothesis for passerine birds: taxonomic and biogeographic implications of an analysis of nuclear DNA sequence data. Proc. R. Soc. B 269(1488): 295–308. doi:10.1098/rspb.2001.1883 PDF fulltext
  • Barker, F. Keith; Cibois, Alice; Schikler, Peter A.; Feinstein, Julie & Cracraft, Joel (2004): Phylogeny and diversification of the largest avian radiation. PNAS 101(30): 11040-11045. doi:10.1073/pnas.0401892101 PMID 15263073 PDF fulltext Supporting information
  • Cibois, Alice (2003a): Mitochondrial DNA Phylogeny of Babblers (Timaliidae). Auk 120(1): 1–20. DOI: 10.1642/0004-8038(2003)120[0035:MDPOBT]2.0.CO;2 HTML fulltext without images
  • Cibois, Alice (2003b): Sylvia is a babbler: taxonomic implications for the families Sylviidae and Timaliidae.Bull. B. O. C. 123: 257–261.
  • Del Hoyo, J.; Elliot, A. & Christie D. (editors). (2007). Handbook of the Birds of the World. Volume 12: Picathartes to Tits and Chickadees. Lynx Edicions. ISBN 978-84-96553-42-2
  • Jønsson, Knud A. & Fjeldså, Jon (2006): A phylogenetic supertree of oscine passerine birds (Aves: Passeri). Zool. Scripta 35(2): 149–186. doi:10.1111/j.1463-6409.2006.00221.x (HTML abstract)
  • Pasquet, Eric; Bourdon, Estelle; Kalyakin, Mikhail V. & Cibois, Alice (2006). The fulvettas (Alcippe), Timaliidae, Aves): a polyphyletic group. Zool. Scripta 35, 559–566. doi:10.1111/j.1463-6409.2006.00253.x (HTML abstract)
  • Penhallurick, John. (see )
  • Sibley, Charles Gald & Ahlquist, Jon Edward (1990): Phylogeny and classification of birds. Yale University Press, New Haven, Conn.
  • Walters, Michael (2006): Colour in birds’ eggs: the collections of the Natural History Museum, Tring. Historical Biology 18(2): 141–204. doi:10.1080/08912960600640887 (HTML abstract)
  • Yeung, C.; Lai, F-M.; Yang, X-J.; Han, L-X.; Lin, M-C. & Li, S-H. (2006). Molecular phylogeny of the parrotbills (Paradoxornithidae). J Ornithol 147: Suppl 1 p 87-88. doi:10.1007/s10336-006-0093-1 PDF of all conference abstracts
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