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Hooded pitohui

March 04, 2023

The hooded pitohui (Pitohui dichrous) is a species of bird in the genus Pitohui found in New Guinea. It was long thought to be a whistler (Pachycephalidae) but is now known to be in the Old World oriole family (Oriolidae). Within the oriole family this species is most closely related to the variable pitohuis in the genus Pitohui, and then the figbirds.

Hooded pitohui
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Aves
Order: Passeriformes
Family: Oriolidae
Genus: Pitohui
Species:
P. dichrous
Binomial name
Pitohui dichrous
(Bonaparte, 1850)
Synonyms
  • Rectes dichrous Bonaparte, 1850

A medium-sized songbird with reddish-brown and black plumage, this species is one of the few known poisonous birds, containing a range of batrachotoxin compounds in its skin, feathers and other tissues. These toxins are thought to be derived from their diet, in a process known as kleptotoxicism, and may function both to deter predators and to protect the bird from parasites. The close resemblance of this species to other unrelated birds also known as pitohuis which are also poisonous is an example of convergent evolution and Müllerian mimicry. Their appearance is also mimicked by unrelated non-poisonous species, a phenomenon known as Batesian mimicry. The toxic nature of this bird is well known to local hunters, who avoid it. It is one of the most poisonous species of pitohui, but the toxicity of individual birds can vary geographically.

The hooded pitohui is found in forests from sea level up to 2,000 m (6,600 ft), but is most common in hills and low mountains. A social bird, it lives in family groups and frequently joins and even leads mixed-species foraging flocks. The diet is made up of fruits, seeds and invertebrates. This species is apparently a cooperative breeder, with family groups helping to protect the nest and feed the young. The hooded pitohui is common and is currently not at risk of extinction, with its numbers being stable.

Taxonomy and systematics

The hooded pitohui (Pitohui dichrous)[2] was described by the French ornithologist Charles Lucien Bonaparte in 1850.[3] Bonaparte placed it in the genus Rectes which had been erected in the same year by Ludwig Reichenbach as an alternative name for the genus Pitohui, which had been described by René Lesson in 1831. No explanation was given for the preference of the newer name over the established older one, but it was common to prefer Latin names over non-Latin names, and to provide Latin names to those without.[4] Richard Bowdler Sharpe encapsulated that attitude when he wrote in 1903 "Pitohui is doubtless an older name than Rectes, but can surely be laid aside as a barbarous word".[5][6] Eventually however the principle of priority, which favours the first formal name given to a taxon, was applied, and Rectes was suppressed as the junior synonym of Pitohui.[4]

The hooded pitohui was placed in the genus Pitohui with five other species, and the genus was thought to reside within the Australasian whistler family (Pachycephalidae).[7] A 2008 examination of the genus, however, found it to be polyphyletic (meaning that the genus contained unrelated species), with some purported members of the genus not actually falling within the whistlers. The hooded pitohui and the closely related variable pitohui were both found to be related to the Old World orioles (Oriolidae).[8] A 2010 study by the same team confirmed that the hooded pitohui and variable pitohui were orioles and indeed were sister species, and that together with the figbirds they formed a well defined basal clade within the family.[9] As the variable pitohui was the type species for the genus Pitohui,[a] the hooded pitohui was retained in that genus and the four remaining species were moved to other genera.[4]

The hooded pitohui is monotypic, lacking any subspecies. Birds in the south east of New Guinea are sometimes separated into a proposed subspecies, P. d. monticola, but the differences are very slight and the supposed subspecies are generally regarded as inseparable.[10]

Pitohui, the common name for the group and the genus name, is a Papuan term for rubbish bird, a reference to its inedibility.[11] The specific name dichrous is from the Ancient Greek word dikhrous for two coloured.[12] Alternate names for the hooded pitohui include the black-headed pitohui[13] and lesser pitohui.[14]

Physiology and description

 
The plumage of the hooded pitohui is dichromatic, black and reddish brown

The hooded pitohui is 22 to 23 cm (8.7–9.1 in) long and weighs 65–76 g (2.3–2.7 oz). The adult has a black upperwing, head, chin, throat and upper breast and a black tail. The rest of the plumage is a reddish brown. The bill and legs are black, and the irises are either reddish brown, dark brown or black. Both sexes look alike. Juvenile birds look like adults, except that the rectrices of the tail and remiges of the wing are tinged with brown.[10]

Toxicity

 
The hooded pitohui uses the same family of batrachotoxin compounds as the golden poison frog of Colombia.

In 1990 scientists preparing the skins of the hooded pitohui for museum collections experienced numbness and burning when handling them. It was reported in 1992 that this species and some other pitohuis contained a neurotoxin called homobatrachotoxin, a derivative of batrachotoxin, in their tissues. This made them the first documented poisonous birds,[15] other than some reports of coturnism caused by consuming quail (although toxicity in quails is unusual), and the first bird discovered with toxins in the skin.[16] The same toxin had previously been found only in Colombian poison dart frogs from the genus Phyllobates (family Dendrobatidae). The batrachotoxin family of compounds are the most toxic compounds by weight in nature,[17] being 250 times more toxic than strychnine.[18] Later research found that the hooded pitohui had other batrachotoxins in its skin, including batrachotoxinin-A cis-crotonate, batrachotoxinin-A and batrachotoxinin-A 3′-hydroxypentanoate.[19]

Bioassays of their tissue found that the skins and feathers were the most toxic, the heart and liver less toxic, and the skeletal muscles the least toxic parts of the birds.[17] Of the feathers the toxin is most prevalent in those covering the breast and belly.[19] Microscopy has shown that the toxins are sequestered in the skin in organelles analogous to lamellar bodies and are secreted into the feathers.[20] The presence of the toxins in muscle, heart and liver shows that hooded pitohuis have a form of insensitivity to batrachotoxins.[17] A 65 g (2.3 oz) bird has been estimated to have up to 20 μg of toxins in its skin and up to 3 μg in its feathers.[15] This can vary dramatically geographically and by individual, and some have been collected with no detectable toxins.[19]

The poisonous pitohuis, including the hooded pitohui, are not thought to create the toxic compound themselves but instead sequester them from their diet. Phyllobates frogs kept in captivity do not develop the toxins, and the extent of the toxicity varies both in the pitohuis across their range and also across the range of the unrelated blue-capped ifrit, another New Guinean bird found with toxic skin and feathers. Both of these facts suggest that the toxins are obtained from the diet.[19] The presence of the toxins in the internal organs as well as the skins and feathers rules out the possibility that the toxins are applied topically from an unknown source by the birds.[17]

One possible source has been identified in the forests of New Guinea: beetles of the genus Choresine (family Melyridae), which contain the toxin and have been found in the stomachs of hooded pitohui. An alternative explanation, that the birds and beetles both get the toxin from a third source, is considered unlikely as the blue-capped ifrit is almost exclusively insectivorous.[18]

Ecology

The function of the toxins to the hooded pitohui has been the source of debate and research since its discovery. The initial suggestion was that the toxins acted as a chemical deterrent to predators.[15] Some researchers cautioned this suggestion was premature,[21] and others noted that the levels of batrachotoxins were three orders of magnitude lower than in the poison dart frogs that do use it in this way.[22]

Another explanation for the purpose of the toxins is to mitigate the effects of parasites.[22] In experimental conditions chewing lice were shown to avoid toxic feathers of hooded pitohui in favour of feathers with lower concentrations of toxin or no toxins at all. Additionally lice that did live in the toxic feathers did not live as long as control lice, suggesting that the toxins could lessen both the incidence of infestation and the severity.[23] A comparative study of the tick loads of wild birds in New Guinea would seem to support the idea, as hooded pitohuis had considerably fewer ticks than almost all the 30 genera examined.[24] The batrachotoxins do not seem to have an effect on internal parasites such as Haemoproteus or the malaria-causing Plasmodium.[25]

 
Brown tree snakes are bird predators that have been shown to be vulnerable to the poisons found in hooded pitohui.

A number of authors have noted that the two explanations, as a chemical defence against predators and as a chemical defence against ectoparasites, are not mutually exclusive, and evidence for both explanations exists.[16][24] The fact that the highest concentrations of toxins are bound in the feathers of the breast and belly, in both pitohuis and ifrits, has caused scientists to suggest that the toxins rub off on eggs and nestlings providing protection against predators and nest parasites.[19]

One argument in favour of the toxin acting as a defence against predators is the apparent Müllerian mimicry in some of the various unrelated pitohui species, which all have similar plumage. The species known as pitohuis were long thought congeneric, due to their similarities in plumage, but are now spread through three families,[b] the oriole, whistlers and Australo-Papuan bellbirds. The similarity in appearance therefore presumably evolved as a shared aposematic signal to common predators of their distasteful nature.[26][27] This signal is reinforced by the species' strong sour odor.[15] There is also evidence that some other birds in New Guinea have evolved Batesian mimicry, where a non-toxic species adopts the appearance of a toxic species. An example of this is the non-toxic juvenile greater melampitta, which has plumage similar to the hooded pitohui.[27]

There have also been experiments to test pitohui batrachotoxins on potential predators. They have been shown to irritate the buccal membranes of brown tree snakes and green tree pythons, both of which are avian predators in New Guinea. The unpalatability of the species is also known to local hunters, who otherwise hunt songbirds of the same size.[17]

The existence of resistance to batrachotoxins and the use of those toxins as chemical defences by several bird families have led to competing theories as to its evolutionary history. Jønsson (2008) suggested that it was an ancestral adaptation in Corvoidea songbirds, and that further studies would reveal more toxic birds.[8] Dumbacher (2008) argued instead that it was an example of convergent evolution.[27]

Distribution and habitat

The hooded pitohui is endemic to the islands of New Guinea. It is found widely across the main island, and also on the nearby island of Yapen. It inhabits rainforest, forest edge habitats and secondary growth, and sometimes mangrove forests. It is most commonly found in hills and low mountains, between 350–1,700 m (1,150–5,580 ft), but is found locally down to sea-level and up to 2,000 m (6,600 ft). It typically occurs at higher elevations than the lowland variable pitohui and lower than the (unrelated) black pitohui, although there is some overlap.[10]

Behaviour

Calls

The hooded pitohui makes a variety of calls, mostly forms of whistles. Its song is a variable collection of three to seven whistles, which can slur up or down with hesitant pauses in between. Usually the song begins with two similar notes followed by an upslur. It also makes an "tuk tuk w’oh tuw’uow" call, two whistled "woiy, woiy" notes, two downslurred whistled "tiuw tow" notes, and three whistles "hui-whui-whooee", which increase in volume.[10]

Diet and feeding

The diet of the hooded pitohui is dominated by fruit, particularly figs of the genus Ficus, grass seeds, some insects and other invertebrates,[10] and possibly small vertebrates.[19] Among the invertebrates found in their diet are beetles, spiders, earwigs, bugs (Hemiptera, including the families Membracidae and Lygaeidae), flies (Diptera), caterpillars and ants.[28][29] They feed at all levels of the forest, from the forest floor to the canopy,[10] and are reported to do so in small groups, presumably of related birds.[30] The species also regularly joins mixed-species foraging flocks, and on Yapen and between 1,100–1,300 m (3,600–4,300 ft) above sea-level it will often act as the flock leader. This leadership role, and indeed their participation in mixed flocks, is not true across all of their range however.[31]

Breeding

Little is known about the breeding biology of the hooded pitohui and its relatives due to the difficulties of studying the species high in the canopy of New Guinea.[30] Nests with eggs of the hooded pitohui have been found from October through to February.[10] The nest that has been described was 2 m (7 ft) off the ground. The nest is a cup of vine tendrils, lined with finer vines and suspended on thin branches.[10][30]

The clutch is one to two eggs, 27 mm–32.8 mm × 20.5 mm–22.2 mm (1.06 in–1.29 in × 0.81 in–0.87 in), which are creamy or pinkish with brown to black spots and blotches and faint grey patches; in one egg all the markings with at the larger end.[10][32] The incubation period is not known, but the species is thought to be a cooperative breeder, as more than two birds in a group have been observed defending the nest from intruders and feeding the young. Young birds, which are covered in white down as nestlings before developing their adult plumage,[33] have been observed being fed acorn-shaped red berries and insects. Young birds will make a threat display when approached in the nest, rising up and erecting their head feathers. As chicks develop directly into adult plumage, it has been suggested that this display may be signalling its identity as a toxic species, even though young birds have not developed toxicity at that age.[30]

Relationship with humans

 
The preparation of study skins for museums led to the discovery of toxins in the skins of hooded pitohui.

The toxic and unpalatable nature of the hooded pitohui has long been known to local people in New Guinea, and this knowledge has been recorded by Western scientists as far back as 1895.[34] In spite of this, and reports of toxicity in birds going back to classic antiquity, before the discovery that the hooded pitohui was toxic, toxicity was not a trait that scientists attributed to birds. The discovery of toxicity in birds, triggered by this species, sparked interest in the subject and a re-examination of older accounts of unpalatability and toxicity in birds, although the field is still understudied.[16]

Status and conservation

Common and widespread throughout New Guinea, the hooded pitohui is evaluated as a species of least concern on the IUCN Red List of Threatened Species.[1] In one study of the effects of small subsistence gardens, populations of hooded pitohui were lower in disturbed agricultural habitat in the lowlands, compared to undisturbed forest, but actually increased in disturbed habitat higher in the mountains.[35]

Notes

  1. ^ Since then the variable pitohui has been split into three species:
  2. ^ Or four, if the shrikethrushes are treated as a separate family, Colluricinclidae, from the whistlers.[4]

References

  1. ^ a b BirdLife International (2018). "Pitohui dichrous". IUCN Red List of Threatened Species. 2018: e.T22705576A130390714. doi:10.2305/IUCN.UK.2018-2.RLTS.T22705576A130390714.en. Retrieved 19 November 2021.
  2. ^ a b Gill, F.; Donsker, D., eds. (2017). "Orioles, drongos & fantails". IOC World Bird List (v 7.2). Retrieved 10 June 2017.
  3. ^ Bonaparte, Charles Lucien (1850). "Note sur plusieurs familles naturelles d'oiseaux, et descriptions d'espèces nouvelles". Comptes Rendus Hebdomadaires des Séances de l'Académie des Sciences (in French). 31: 561–564 [563].
  4. ^ a b c d Dumbacher, J. P. (2014). "A taxonomic revision of the genus Pitohui Lesson, 1831 (Oriolidae), with historical notes on names" (PDF). Bulletin of the British Ornithologists' Club. 134 (1): 19–22.
  5. ^ Sharpe, Richard Bowdler (1903). A Hand-List of the Genera and Species of Birds: Volume 4. Vol. 4. London: Trustees of the British Museum. p. 267.
  6. ^ Quoted in Dumbacher (2014), p. 20
  7. ^ Boles, Walter (2007). "Family Pachycephalidae (Whistlers)". In del Hoyo, Josep; Elliott, Andrew; Christie, David (eds.). Handbook of the Birds of the World. Volume 12: Picathartes to Tits and Chickadees. Barcelona: Lynx Edicions. p. 380. ISBN 978-84-96553-42-2.
  8. ^ a b Jønsson, K. A; Bowie, R. C.K; Norman, J. A; Christidis, L.; Fjeldsa, J. (2008). "Polyphyletic origin of toxic Pitohui birds suggests widespread occurrence of toxicity in corvoid birds". Biology Letters. 4 (1): 71–74. doi:10.1098/rsbl.2007.0464. PMC 2412923. PMID 18055416.
  9. ^ Jønsson, Knud A.; Bowie, Rauri C. K.; Moyle, Robert G.; Irestedt, Martin; Christidis, Les; Norman, Janette A.; Fjeldså, Jon (2010). "Phylogeny and biogeography of Oriolidae (Aves: Passeriformes)". Ecography. 33 (2): 232–241. doi:10.1111/j.1600-0587.2010.06167.x.
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  11. ^ Jobling, J. (2017). "Key to Scientific Names in Ornithology: Pitohui". Handbook of the Birds of the World Alive. Barcelona: Lynx Edicions. Retrieved 14 June 2017.
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  13. ^ Diamond, Jared M. (1983). "Melampitta gigantea: possible relation between feather structure and underground roosting habits" (PDF). The Condor. 85 (1): 89–91. doi:10.2307/1367895. JSTOR 1367895.
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  18. ^ a b Dumbacher, J. P.; Wako, A.; Derrickson, S. R.; Samuelson, A.; Spande, T. F.; Daly, J. W. (2004). "Melyrid beetles (Choresine): A putative source for the batrachotoxin alkaloids found in poison-dart frogs and toxic passerine birds". Proceedings of the National Academy of Sciences. 101 (45): 15857–15860. Bibcode:2004PNAS..10115857D. doi:10.1073/pnas.0407197101. PMC 528779. PMID 15520388.
  19. ^ a b c d e f Dumbacher, J. P.; Spande, T. F.; Daly, J. W. (2000). "Batrachotoxin alkaloids from passerine birds: A second toxic bird genus (Ifrita kowaldi) from New Guinea". Proceedings of the National Academy of Sciences. 97 (24): 12970–12975. Bibcode:2000PNAS...9712970D. doi:10.1073/pnas.200346897. PMC 27162. PMID 11035772.
  20. ^ Menon, Gopinathan K.; Dumbacher, John P. (2014). "A "toxin mantle" as defensive barrier in a tropical bird: evolutionary exploitation of the basic permeability barrier forming organelles". Experimental Dermatology. 23 (4): 288–290. doi:10.1111/exd.12367. PMID 24617754.
  21. ^ Glendinning, J. (1993). "Pitohui: how toxic and to whom?". Science. 259 (5095): 582–583. Bibcode:1993Sci...259..582G. doi:10.1126/science.8430299. PMID 8430299. S2CID 206631249.
  22. ^ a b Poulsen, B. O. (1994). "Poison in birds: against predators or ectoparasites?". Emu. 94 (2): 128–129. doi:10.1071/MU9940128.
  23. ^ Dumbacher, John P. (1999). "Evolution of toxicity in Pitohuis: I. Effects of homobatrachotoxin on chewing lice (Order Phthiraptera)" (PDF). The Auk. 116 (4): 957–963. doi:10.2307/4089675. JSTOR 4089675.
  24. ^ a b Mouritsen, Kim N.; Madsen, Jørn (1994). "Toxic birds: defence against parasites?" (PDF). Oikos. 69 (2): 357. doi:10.2307/3546161. JSTOR 3546161.
  25. ^ Beadell, J.; Gering, E.; Austin, J.; Dumbacher, J.; Peirce, M.; Pratt, T.; Atkinson, C.; Fleischer, R. (2004). "Prevalence and differential host-specificity of two avian blood parasite genera in the Australo-Papuan region" (PDF). Molecular Ecology. 13 (12): 3829–3844. doi:10.1111/j.1365-294X.2004.02363.x. PMID 15548295. S2CID 19317909.
  26. ^ Dumbacher, J. P.; Fleischer, R. C. (2001). "Phylogenetic evidence for colour pattern convergence in toxic pitohuis: Mullerian mimicry in birds?". Proceedings of the Royal Society B: Biological Sciences. 268 (1480): 1971–1976. doi:10.1098/rspb.2001.1717. PMC 1088837. PMID 11571042.
  27. ^ a b c Dumbacher, J.; Deiner, K.; Thompson, L.; Fleischer, R. (2008). "Phylogeny of the avian genus Pitohui and the evolution of toxicity in birds". Molecular Phylogenetics and Evolution. 49 (3): 774–781. doi:10.1016/j.ympev.2008.09.018. PMID 18929671.
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  30. ^ a b c d Legge, S.; Heinsohn, R. (1996). "Cooperative breeding in Hooded Pitohuis (Pitohui dichrous)". Emu. 96 (2): 139–140. doi:10.1071/MU9960139.
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External links

 
Wikimedia Commons has media related to Pitohui dichrous.
  • Xeno-canto: audio recordings of the hooded pitohui.

March 04, 2023
hooded, pitohui, hooded, pitohui, pitohui, dichrous, species, bird, genus, pitohui, found, guinea, long, thought, whistler, pachycephalidae, known, world, oriole, family, oriolidae, within, oriole, family, this, species, most, closely, related, variable, pitoh. The hooded pitohui Pitohui dichrous is a species of bird in the genus Pitohui found in New Guinea It was long thought to be a whistler Pachycephalidae but is now known to be in the Old World oriole family Oriolidae Within the oriole family this species is most closely related to the variable pitohuis in the genus Pitohui and then the figbirds Hooded pitohuiConservation statusLeast Concern IUCN 3 1 1 Scientific classificationKingdom AnimaliaPhylum ChordataClass AvesOrder PasseriformesFamily OriolidaeGenus PitohuiSpecies P dichrousBinomial namePitohui dichrous Bonaparte 1850 SynonymsRectes dichrous Bonaparte 1850A medium sized songbird with reddish brown and black plumage this species is one of the few known poisonous birds containing a range of batrachotoxin compounds in its skin feathers and other tissues These toxins are thought to be derived from their diet in a process known as kleptotoxicism and may function both to deter predators and to protect the bird from parasites The close resemblance of this species to other unrelated birds also known as pitohuis which are also poisonous is an example of convergent evolution and Mullerian mimicry Their appearance is also mimicked by unrelated non poisonous species a phenomenon known as Batesian mimicry The toxic nature of this bird is well known to local hunters who avoid it It is one of the most poisonous species of pitohui but the toxicity of individual birds can vary geographically The hooded pitohui is found in forests from sea level up to 2 000 m 6 600 ft but is most common in hills and low mountains A social bird it lives in family groups and frequently joins and even leads mixed species foraging flocks The diet is made up of fruits seeds and invertebrates This species is apparently a cooperative breeder with family groups helping to protect the nest and feed the young The hooded pitohui is common and is currently not at risk of extinction with its numbers being stable Contents 1 Taxonomy and systematics 2 Physiology and description 2 1 Toxicity 3 Ecology 4 Distribution and habitat 5 Behaviour 5 1 Calls 5 2 Diet and feeding 5 3 Breeding 6 Relationship with humans 6 1 Status and conservation 7 Notes 8 References 9 External linksTaxonomy and systematics EditThe hooded pitohui Pitohui dichrous 2 was described by the French ornithologist Charles Lucien Bonaparte in 1850 3 Bonaparte placed it in the genus Rectes which had been erected in the same year by Ludwig Reichenbach as an alternative name for the genus Pitohui which had been described by Rene Lesson in 1831 No explanation was given for the preference of the newer name over the established older one but it was common to prefer Latin names over non Latin names and to provide Latin names to those without 4 Richard Bowdler Sharpe encapsulated that attitude when he wrote in 1903 Pitohui is doubtless an older name than Rectes but can surely be laid aside as a barbarous word 5 6 Eventually however the principle of priority which favours the first formal name given to a taxon was applied and Rectes was suppressed as the junior synonym of Pitohui 4 The hooded pitohui was placed in the genus Pitohui with five other species and the genus was thought to reside within the Australasian whistler family Pachycephalidae 7 A 2008 examination of the genus however found it to be polyphyletic meaning that the genus contained unrelated species with some purported members of the genus not actually falling within the whistlers The hooded pitohui and the closely related variable pitohui were both found to be related to the Old World orioles Oriolidae 8 A 2010 study by the same team confirmed that the hooded pitohui and variable pitohui were orioles and indeed were sister species and that together with the figbirds they formed a well defined basal clade within the family 9 As the variable pitohui was the type species for the genus Pitohui a the hooded pitohui was retained in that genus and the four remaining species were moved to other genera 4 The hooded pitohui is monotypic lacking any subspecies Birds in the south east of New Guinea are sometimes separated into a proposed subspecies P d monticola but the differences are very slight and the supposed subspecies are generally regarded as inseparable 10 Pitohui the common name for the group and the genus name is a Papuan term for rubbish bird a reference to its inedibility 11 The specific name dichrous is from the Ancient Greek word dikhrous for two coloured 12 Alternate names for the hooded pitohui include the black headed pitohui 13 and lesser pitohui 14 Physiology and description Edit The plumage of the hooded pitohui is dichromatic black and reddish brown The hooded pitohui is 22 to 23 cm 8 7 9 1 in long and weighs 65 76 g 2 3 2 7 oz The adult has a black upperwing head chin throat and upper breast and a black tail The rest of the plumage is a reddish brown The bill and legs are black and the irises are either reddish brown dark brown or black Both sexes look alike Juvenile birds look like adults except that the rectrices of the tail and remiges of the wing are tinged with brown 10 Toxicity Edit The hooded pitohui uses the same family of batrachotoxin compounds as the golden poison frog of Colombia In 1990 scientists preparing the skins of the hooded pitohui for museum collections experienced numbness and burning when handling them It was reported in 1992 that this species and some other pitohuis contained a neurotoxin called homobatrachotoxin a derivative of batrachotoxin in their tissues This made them the first documented poisonous birds 15 other than some reports of coturnism caused by consuming quail although toxicity in quails is unusual and the first bird discovered with toxins in the skin 16 The same toxin had previously been found only in Colombian poison dart frogs from the genus Phyllobates family Dendrobatidae The batrachotoxin family of compounds are the most toxic compounds by weight in nature 17 being 250 times more toxic than strychnine 18 Later research found that the hooded pitohui had other batrachotoxins in its skin including batrachotoxinin A cis crotonate batrachotoxinin A and batrachotoxinin A 3 hydroxypentanoate 19 Bioassays of their tissue found that the skins and feathers were the most toxic the heart and liver less toxic and the skeletal muscles the least toxic parts of the birds 17 Of the feathers the toxin is most prevalent in those covering the breast and belly 19 Microscopy has shown that the toxins are sequestered in the skin in organelles analogous to lamellar bodies and are secreted into the feathers 20 The presence of the toxins in muscle heart and liver shows that hooded pitohuis have a form of insensitivity to batrachotoxins 17 A 65 g 2 3 oz bird has been estimated to have up to 20 mg of toxins in its skin and up to 3 mg in its feathers 15 This can vary dramatically geographically and by individual and some have been collected with no detectable toxins 19 The poisonous pitohuis including the hooded pitohui are not thought to create the toxic compound themselves but instead sequester them from their diet Phyllobates frogs kept in captivity do not develop the toxins and the extent of the toxicity varies both in the pitohuis across their range and also across the range of the unrelated blue capped ifrit another New Guinean bird found with toxic skin and feathers Both of these facts suggest that the toxins are obtained from the diet 19 The presence of the toxins in the internal organs as well as the skins and feathers rules out the possibility that the toxins are applied topically from an unknown source by the birds 17 One possible source has been identified in the forests of New Guinea beetles of the genus Choresine family Melyridae which contain the toxin and have been found in the stomachs of hooded pitohui An alternative explanation that the birds and beetles both get the toxin from a third source is considered unlikely as the blue capped ifrit is almost exclusively insectivorous 18 Ecology EditThe function of the toxins to the hooded pitohui has been the source of debate and research since its discovery The initial suggestion was that the toxins acted as a chemical deterrent to predators 15 Some researchers cautioned this suggestion was premature 21 and others noted that the levels of batrachotoxins were three orders of magnitude lower than in the poison dart frogs that do use it in this way 22 Another explanation for the purpose of the toxins is to mitigate the effects of parasites 22 In experimental conditions chewing lice were shown to avoid toxic feathers of hooded pitohui in favour of feathers with lower concentrations of toxin or no toxins at all Additionally lice that did live in the toxic feathers did not live as long as control lice suggesting that the toxins could lessen both the incidence of infestation and the severity 23 A comparative study of the tick loads of wild birds in New Guinea would seem to support the idea as hooded pitohuis had considerably fewer ticks than almost all the 30 genera examined 24 The batrachotoxins do not seem to have an effect on internal parasites such as Haemoproteus or the malaria causing Plasmodium 25 Brown tree snakes are bird predators that have been shown to be vulnerable to the poisons found in hooded pitohui A number of authors have noted that the two explanations as a chemical defence against predators and as a chemical defence against ectoparasites are not mutually exclusive and evidence for both explanations exists 16 24 The fact that the highest concentrations of toxins are bound in the feathers of the breast and belly in both pitohuis and ifrits has caused scientists to suggest that the toxins rub off on eggs and nestlings providing protection against predators and nest parasites 19 One argument in favour of the toxin acting as a defence against predators is the apparent Mullerian mimicry in some of the various unrelated pitohui species which all have similar plumage The species known as pitohuis were long thought congeneric due to their similarities in plumage but are now spread through three families b the oriole whistlers and Australo Papuan bellbirds The similarity in appearance therefore presumably evolved as a shared aposematic signal to common predators of their distasteful nature 26 27 This signal is reinforced by the species strong sour odor 15 There is also evidence that some other birds in New Guinea have evolved Batesian mimicry where a non toxic species adopts the appearance of a toxic species An example of this is the non toxic juvenile greater melampitta which has plumage similar to the hooded pitohui 27 There have also been experiments to test pitohui batrachotoxins on potential predators They have been shown to irritate the buccal membranes of brown tree snakes and green tree pythons both of which are avian predators in New Guinea The unpalatability of the species is also known to local hunters who otherwise hunt songbirds of the same size 17 The existence of resistance to batrachotoxins and the use of those toxins as chemical defences by several bird families have led to competing theories as to its evolutionary history Jonsson 2008 suggested that it was an ancestral adaptation in Corvoidea songbirds and that further studies would reveal more toxic birds 8 Dumbacher 2008 argued instead that it was an example of convergent evolution 27 Distribution and habitat EditThe hooded pitohui is endemic to the islands of New Guinea It is found widely across the main island and also on the nearby island of Yapen It inhabits rainforest forest edge habitats and secondary growth and sometimes mangrove forests It is most commonly found in hills and low mountains between 350 1 700 m 1 150 5 580 ft but is found locally down to sea level and up to 2 000 m 6 600 ft It typically occurs at higher elevations than the lowland variable pitohui and lower than the unrelated black pitohui although there is some overlap 10 Behaviour EditCalls Edit The hooded pitohui makes a variety of calls mostly forms of whistles Its song is a variable collection of three to seven whistles which can slur up or down with hesitant pauses in between Usually the song begins with two similar notes followed by an upslur It also makes an tuk tuk w oh tuw uow call two whistled woiy woiy notes two downslurred whistled tiuw tow notes and three whistles hui whui whooee which increase in volume 10 Diet and feeding Edit The diet of the hooded pitohui is dominated by fruit particularly figs of the genus Ficus grass seeds some insects and other invertebrates 10 and possibly small vertebrates 19 Among the invertebrates found in their diet are beetles spiders earwigs bugs Hemiptera including the families Membracidae and Lygaeidae flies Diptera caterpillars and ants 28 29 They feed at all levels of the forest from the forest floor to the canopy 10 and are reported to do so in small groups presumably of related birds 30 The species also regularly joins mixed species foraging flocks and on Yapen and between 1 100 1 300 m 3 600 4 300 ft above sea level it will often act as the flock leader This leadership role and indeed their participation in mixed flocks is not true across all of their range however 31 Breeding Edit Little is known about the breeding biology of the hooded pitohui and its relatives due to the difficulties of studying the species high in the canopy of New Guinea 30 Nests with eggs of the hooded pitohui have been found from October through to February 10 The nest that has been described was 2 m 7 ft off the ground The nest is a cup of vine tendrils lined with finer vines and suspended on thin branches 10 30 The clutch is one to two eggs 27 mm 32 8 mm 20 5 mm 22 2 mm 1 06 in 1 29 in 0 81 in 0 87 in which are creamy or pinkish with brown to black spots and blotches and faint grey patches in one egg all the markings with at the larger end 10 32 The incubation period is not known but the species is thought to be a cooperative breeder as more than two birds in a group have been observed defending the nest from intruders and feeding the young Young birds which are covered in white down as nestlings before developing their adult plumage 33 have been observed being fed acorn shaped red berries and insects Young birds will make a threat display when approached in the nest rising up and erecting their head feathers As chicks develop directly into adult plumage it has been suggested that this display may be signalling its identity as a toxic species even though young birds have not developed toxicity at that age 30 Relationship with humans Edit The preparation of study skins for museums led to the discovery of toxins in the skins of hooded pitohui The toxic and unpalatable nature of the hooded pitohui has long been known to local people in New Guinea and this knowledge has been recorded by Western scientists as far back as 1895 34 In spite of this and reports of toxicity in birds going back to classic antiquity before the discovery that the hooded pitohui was toxic toxicity was not a trait that scientists attributed to birds The discovery of toxicity in birds triggered by this species sparked interest in the subject and a re examination of older accounts of unpalatability and toxicity in birds although the field is still understudied 16 Status and conservation Edit Common and widespread throughout New Guinea the hooded pitohui is evaluated as a species of least concern on the IUCN Red List of Threatened Species 1 In one study of the effects of small subsistence gardens populations of hooded pitohui were lower in disturbed agricultural habitat in the lowlands compared to undisturbed forest but actually increased in disturbed habitat higher in the mountains 35 Notes Edit Since then the variable pitohui has been split into three species Northern variable pitohui Pitohui kirhocephalus Raja Ampat pitohui Pitohui cerviniventris Southern variable pitohui Pitohui uropygialis 2 Or four if the shrikethrushes are treated as a separate family Colluricinclidae from the whistlers 4 References Edit a b BirdLife International 2018 Pitohui dichrous IUCN Red List of Threatened Species 2018 e T22705576A130390714 doi 10 2305 IUCN UK 2018 2 RLTS T22705576A130390714 en Retrieved 19 November 2021 a b Gill F Donsker D eds 2017 Orioles drongos amp fantails IOC World Bird List v 7 2 Retrieved 10 June 2017 Bonaparte Charles Lucien 1850 Note sur plusieurs familles naturelles d oiseaux et descriptions d especes nouvelles Comptes Rendus Hebdomadaires des Seances de l Academie des Sciences in French 31 561 564 563 a b c d Dumbacher J P 2014 A taxonomic revision of the genus Pitohui Lesson 1831 Oriolidae with historical notes on names PDF Bulletin of the British Ornithologists Club 134 1 19 22 Sharpe Richard Bowdler 1903 A Hand List of the Genera and Species of Birds Volume 4 Vol 4 London Trustees of the British Museum p 267 Quoted in Dumbacher 2014 p 20 Boles Walter 2007 Family Pachycephalidae Whistlers In del Hoyo Josep Elliott Andrew Christie David eds Handbook of the Birds of the World Volume 12 Picathartes to Tits and Chickadees Barcelona Lynx Edicions p 380 ISBN 978 84 96553 42 2 a b Jonsson K A Bowie R C K Norman J A Christidis L Fjeldsa J 2008 Polyphyletic origin of toxic Pitohui birds suggests widespread occurrence of toxicity in corvoid birds Biology Letters 4 1 71 74 doi 10 1098 rsbl 2007 0464 PMC 2412923 PMID 18055416 Jonsson Knud A Bowie Rauri C K Moyle Robert G Irestedt Martin Christidis Les Norman Janette A Fjeldsa Jon 2010 Phylogeny and biogeography of Oriolidae Aves Passeriformes Ecography 33 2 232 241 doi 10 1111 j 1600 0587 2010 06167 x a b c d e f g h i Boles W 2020 del Hoyo Josep Elliott Andrew Sargatal Jordi Christie David A de Juana Eduardo eds Hooded Pitohui Pitohui dichrous Handbook of the Birds of the World Alive Barcelona Lynx Edicions doi 10 2173 bow hoopit1 01 S2CID 216419243 Retrieved 2 June 2017 Jobling J 2017 Key to Scientific Names in Ornithology Pitohui Handbook of the Birds of the World Alive Barcelona Lynx Edicions Retrieved 14 June 2017 Jobling J 2017 Key to Scientific Names in Ornithology dikhrous Handbook of the Birds of the World Alive Barcelona Lynx Edicions Retrieved 7 June 2017 Diamond Jared M 1983 Melampitta gigantea possible relation between feather structure and underground roosting habits PDF The Condor 85 1 89 91 doi 10 2307 1367895 JSTOR 1367895 Pitohui dichrous Avibase avibase bsc eoc org Retrieved 2017 06 03 a b c d Dumbacher J Beehler B Spande T Garraffo H Daly J 1992 Homobatrachotoxin in the genus Pitohui chemical defense in birds Science 258 5083 799 801 Bibcode 1992Sci 258 799D doi 10 1126 science 1439786 PMID 1439786 a b c Ligabue Braun Rodrigo Carlini Celia Regina 2015 Poisonous birds A timely review Toxicon 99 102 108 doi 10 1016 j toxicon 2015 03 020 hdl 10923 23106 PMID 25839151 a b c d e Dumbacher John P Menon Gopinathan K Daly John W 2009 Skin as a toxin storage organ in the endemic New Guinean genus Pitohui PDF The Auk 126 3 520 530 doi 10 1525 auk 2009 08230 S2CID 40669290 a b Dumbacher J P Wako A Derrickson S R Samuelson A Spande T F Daly J W 2004 Melyrid beetles Choresine A putative source for the batrachotoxin alkaloids found in poison dart frogs and toxic passerine birds Proceedings of the National Academy of Sciences 101 45 15857 15860 Bibcode 2004PNAS 10115857D doi 10 1073 pnas 0407197101 PMC 528779 PMID 15520388 a b c d e f Dumbacher J P Spande T F Daly J W 2000 Batrachotoxin alkaloids from passerine birds A second toxic bird genus Ifrita kowaldi from New Guinea Proceedings of the National Academy of Sciences 97 24 12970 12975 Bibcode 2000PNAS 9712970D doi 10 1073 pnas 200346897 PMC 27162 PMID 11035772 Menon Gopinathan K Dumbacher John P 2014 A toxin mantle as defensive barrier in a tropical bird evolutionary exploitation of the basic permeability barrier forming organelles Experimental Dermatology 23 4 288 290 doi 10 1111 exd 12367 PMID 24617754 Glendinning J 1993 Pitohui how toxic and to whom Science 259 5095 582 583 Bibcode 1993Sci 259 582G doi 10 1126 science 8430299 PMID 8430299 S2CID 206631249 a b Poulsen B O 1994 Poison in birds against predators or ectoparasites Emu 94 2 128 129 doi 10 1071 MU9940128 Dumbacher John P 1999 Evolution of toxicity in Pitohuis I Effects of homobatrachotoxin on chewing lice Order Phthiraptera PDF The Auk 116 4 957 963 doi 10 2307 4089675 JSTOR 4089675 a b Mouritsen Kim N Madsen Jorn 1994 Toxic birds defence against parasites PDF Oikos 69 2 357 doi 10 2307 3546161 JSTOR 3546161 Beadell J Gering E Austin J Dumbacher J Peirce M Pratt T Atkinson C Fleischer R 2004 Prevalence and differential host specificity of two avian blood parasite genera in the Australo Papuan region PDF Molecular Ecology 13 12 3829 3844 doi 10 1111 j 1365 294X 2004 02363 x PMID 15548295 S2CID 19317909 Dumbacher J P Fleischer R C 2001 Phylogenetic evidence for colour pattern convergence in toxic pitohuis Mullerian mimicry in birds Proceedings of the Royal Society B Biological Sciences 268 1480 1971 1976 doi 10 1098 rspb 2001 1717 PMC 1088837 PMID 11571042 a b c Dumbacher J Deiner K Thompson L Fleischer R 2008 Phylogeny of the avian genus Pitohui and the evolution of toxicity in birds Molecular Phylogenetics and Evolution 49 3 774 781 doi 10 1016 j ympev 2008 09 018 PMID 18929671 Lamothe L 1979 Diet of some birds in Araucaria and Pinus forests in Papua New Guinea Emu 79 1 36 37 doi 10 1071 MU9790036 Sam Katerina Koane Bonny Jeppy Samuel Sykorova Jana Novotny Vojtech 2017 Diet of land birds along an elevational gradient in Papua New Guinea Scientific Reports 7 44018 44018 Bibcode 2017NatSR 744018S doi 10 1038 srep44018 PMC 5343654 PMID 28276508 a b c d Legge S Heinsohn R 1996 Cooperative breeding in Hooded Pitohuis Pitohui dichrous Emu 96 2 139 140 doi 10 1071 MU9960139 Diamond J 1987 Flocks of brown and black New Guinean bird a bicolored mixed species foraging association Emu 87 4 201 211 doi 10 1071 MU9870201 Parker S A 1962 Notes on some undescribed eggs from New Guinea Bulletin of the British Ornithologists Club 82 132 133 Mayr E Rand A L 1937 The birds of the 1933 1934 Papuan Expedition Bulletin of the American Museum of Natural History Vol 73 pp 1 248 181 182 hdl 2246 833 Mead G S 1895 Birds of New Guinea Miscellaneous Continued The American Naturalist 29 343 627 636 doi 10 1086 276194 JSTOR 2452783 Marsden S Symes C Mack A 2006 The response of a New Guinean avifauna to conversion of forest to small scale agriculture PDF Ibis 148 4 629 640 doi 10 1111 j 1474 919X 2006 00577 x hdl 2263 2499 External links Edit Wikimedia Commons has media related to Pitohui dichrous Xeno canto audio recordings of the hooded pitohui Retrieved from https en wikipedia org w index php title Hooded pitohui amp oldid 1142757429, wikipedia, wiki, book, books, library,

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