Shoebill

The shoebill (Balaeniceps rex) also known as whalehead, whale-headed stork, or shoe-billed stork, is a very large stork-like bird. It derives its name from its enormous shoe-shaped bill. It has a somewhat stork-like overall form and has previously been classified with the storks in the order Ciconiiformes based on this morphology. However, genetic evidence places it with the Pelecaniformes. The adult is mainly grey while the juveniles are browner. It lives in tropical east Africa in large swamps from South Sudan to Zambia.[2]

Shoebill
At the Pairi Daiza in Brugelette, Belgium
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Aves
Order: Pelecaniformes
Family: Balaenicipitidae
Genus: Balaeniceps
Gould, 1850
Species:
B. rex
Binomial name
Balaeniceps rex
Gould, 1850
Shoebill range

Taxonomy and systematics

Molecular studies have found the hamerkop to be the closest relative of the shoebill.

The shoebill was known to both ancient Egyptians[3] and Arabs, but was not classified until the 19th century, after skins and eventually live specimens were brought to Europe. John Gould described it in 1850, giving it the name Balaeniceps rex. The genus name comes from the Latin words balaena "whale",[4] and caput "head", abbreviated to -ceps in compound words.[5]

Traditionally allied with the storks (Ciconiiformes), it was retained there in the Sibley-Ahlquist taxonomy which lumped a massive number of unrelated taxa into their "Ciconiiformes". More recently, the shoebill has been considered to be closer to the pelicans (based on anatomical comparisons)[6] or the herons (based on biochemical evidence).[7] Microscopic analysis of eggshell structure by Konstantin Mikhailov in 1995 found that the eggshells of shoebills closely resembled those of other Pelecaniformes in having a covering of thick microglobular material over the crystalline shells.[8] A recent DNA study reinforces their membership of the Pelecaniformes.[9]

So far, two fossil relatives of the shoebill have been described: Goliathia from the early Oligocene of Egypt and Paludavis from the Early Miocene of the same country. It has been suggested that the enigmatic African fossil bird Eremopezus was a relative too, but the evidence for that is unconfirmed. All that is known of Eremopezus is that it was a very large, probably flightless bird with a flexible foot, allowing it to handle either vegetation or prey.

Description

The shoebill's conspicuous bill is its most well-known feature.

The shoebill is a tall bird, with a typical height range of 110 to 140 cm (43 to 55 in) and some specimens reaching as much as 152 cm (60 in). Length from tail to beak can range from 100 to 140 cm (39 to 55 in) and wingspan is 230 to 260 cm (7 ft 7 in to 8 ft 6 in). Weight has reportedly ranged from 4 to 7 kg (8.8 to 15.4 lb).[10][11] A male will weigh on average around 5.6 kg (12 lb) and is larger than a typical female of 4.9 kg (11 lb).[12] The signature feature of the species is its huge, bulbous bill, which is straw-coloured with erratic greyish markings. The exposed culmen (or the measurement along the top of the upper mandible) is 18.8 to 24 cm (7.4 to 9.4 in), the third longest bill among extant birds after pelicans and large storks, and can outrival the pelicans in bill circumference, especially if the bill is considered as the hard, bony keratin portion.[12] As in the pelicans, the upper mandible is strongly keeled, ending in a sharp nail. The dark coloured legs are fairly long, with a tarsus length of 21.7 to 25.5 cm (8.5 to 10.0 in). The shoebill's feet are exceptionally large, with the middle toe reaching 16.8 to 18.5 cm (6.6 to 7.3 in) in length, likely assisting the species in its ability to stand on aquatic vegetation while hunting. The neck is relatively shorter and thicker than other long-legged wading birds such as herons and cranes. The wings are broad, with a wing chord length of 58.8 to 78 cm (23.1 to 30.7 in), and well-adapted to soaring.

The skull

The plumage of adult birds is blue-grey with darker slaty-grey flight feathers. The breast presents some elongated feathers, which have dark shafts. The juvenile has a similar plumage colour, but is a darker grey with a brown tinge.[2] When they are first born, shoebills have a more modestly-sized bill, which is initially silvery-grey. The bill becomes more noticeably large when the chicks are 23 days old and becomes well developed by 43 days.[12]

Flight pattern

Its wings are held flat while soaring and, as in the pelicans and the storks of the genus Leptoptilos, the shoebill flies with its neck retracted. Its flapping rate, at an estimated 150 flaps per minute, is one of the slowest of any bird, with the exception of the larger stork species. The pattern is alternating flapping and gliding cycles of approximately seven seconds each, putting its gliding distance somewhere between the larger storks and the Andean condor (Vultur gryphus). When flushed, shoebills usually try to fly no more than 100 to 500 m (330 to 1,640 ft).[12] Long flights of the shoebill are rare, and only a few flights beyond its minimum foraging distance of 20 m (66 ft) have been recorded.

Identification

At close range, it can be easily identified by its unique features. In flight, if its unique bill cannot be seen, the shoebill's silhouette resembles that of a stork or condor, but its feathers are a distinctive medium blue-grey. Also unusual, its tail is the same colour as its wings. Under poor viewing conditions, its size and wingspan can distinguish it from other birds in its habitat. Its legs, roughly the length of storks', extend straight back far past its tail when in flight. The wing to tail size cannot be used for identification; it is similar to those of several other birds.

Distribution and habitat

The shoebill is distributed in freshwater swamps of central tropical Africa, from southern Sudan and South Sudan through parts of eastern Congo, Rwanda, Uganda, western Tanzania and northern Zambia. The species is most numerous in the West Nile sub-region and South Sudan (especially the Sudd, a main stronghold for the species); it is also significant in wetlands of Uganda and western Tanzania. More isolated records have been reported of shoebills in Kenya, the Central African Republic, northern Cameroon, south-western Ethiopia, Malawi. Vagrant strays to the Okavango Basin, Botswana and the upper Congo River have also been sighted. The distribution of this species seems to largely coincide with that of papyrus and lungfish. They are often found in areas of flood plain interspersed with undisturbed papyrus and reedbeds. When shoebill storks are in an area with deep water, a bed of floating vegetation is a requirement. They are also found where there is poorly oxygenated water. This causes the fish living in the water to surface for air more often, increasing the likelihood a shoebill stork will successfully capture it.[13] The shoebill is non-migratory with limited seasonal movements due to habitat changes, food availability and disturbance by humans.[12]

Petroglyphs from Oued Djerat, eastern Algeria, show that the shoebill occurred during the Early Holocene much more to the north, in the wetlands that covered the present-day Sahara Desert at that time.[14]

The shoebill occurs in extensive, dense freshwater marshes. Almost all wetlands that attract the species have undisturbed Cyperus papyrus and reed beds of Phragmites and Typha. Although their distribution largely seems to correspond with the distribution of papyrus in central Africa, the species seems to avoid pure papyrus swamps and is often attracted to areas with mixed vegetation. More rarely, the species has been seen foraging in rice fields and flooded plantations.[12]

Behaviour and ecology

The shoebill is noted for its slow movements and tendency to stay still for long periods, resulting in descriptions of the species as "statue-like". They are quite sensitive to human disturbance and may abandon their nests if flushed by humans. However, while foraging, if dense vegetation stands between it and humans, this wader can be fairly tame. The shoebill is attracted to poorly oxygenated waters such as swamps, marshes and bogs where fish frequently surface to breathe. Exceptionally for a bird this large, the shoebill often stands and perches on floating vegetation, making them appear somewhat like a giant jacana, although the similarly sized and occasionally sympatric Goliath heron (Ardea goliath) is also known to stand on aquatic vegetation. Shoebills, being solitary, forage at 20 m (66 ft) or more from one another even where relatively densely populated. This species stalks its prey patiently, in a slow and lurking fashion. While hunting, the shoebill strides very slowly and is frequently motionless. Unlike some other large waders, this species hunts entirely using vision and is not known to engage in tactile hunting. When prey is spotted, it launches a quick violent strike. However, depending on the size of the prey, handling time after the strike can exceed 10 minutes. Around 60% of strikes yield prey. Frequently water and vegetation is snatched up during the strike and is spilled out from the edges of the mandibles. The activity of hippopotamus may inadvertently benefit the shoebill, as submerged hippos occasionally force fish to the surface.[12]

A shoebill standing at Ueno Zoo, Tokyo

Shoebills are largely piscivorous but are assured predators of a considerable range of wetland vertebrates. Preferred prey species have reportedly included marbled lungfish (Protopterus aethiopicus) and Senegal bichir (Polypterus senegalus) and various Tilapia species and catfish, the latter mainly in the genus Clarias. Other prey eaten by this species has included frogs, water snakes, Nile monitors (Varanus niloticus) and baby crocodiles. More rarely, turtles, snails, rodents and small waterfowl have reportedly been eaten. There is a single unconfirmed report of shoebills feeding on lechwe (Kobus leche) calves. Given its sharp-edged beak, huge bill and wide gape, the shoebill can hunt large prey, often targeting prey bigger than is taken by other large wading birds. Fish eaten by this species are commonly in the range of 15 to 50 cm (5.9 to 19.7 in) long and weigh around 500 g (1.1 lb), though lungfish of as much as 1 m (3.3 ft) have been attacked. Snakes preyed upon are commonly from 50 to 60 cm (20 to 24 in) long. In the Bangweulu Swamps of Zambia, the main prey items fed to young by the parents were the catfish Clarias gariepinus [15] (syn. C. mossambicus) and water snakes. In Uganda, lungfish and catfish were mainly fed to the young.[12] The big beak is sometimes used to dig into pond-bottom mud to extract lungfish from their aestivation burrows.

Breeding

A sitting shoebill in Prague Zoo, Czech Republic

The solitary nature of shoebills extends to their breeding habits. Nests typically occur at less than three nests per square kilometre, unlike herons, cormorants, pelicans and storks which predominantly nest in colonies. The breeding pair of shoebills vigorously defends a territory of 2 to 4 km2 (0.77 to 1.54 sq mi) from conspecifics. In the extreme north and south of the species' range, nesting starts right after the rains end. In more central regions of the range, it may nest near end of wet season in order to hatch around the beginning of the following wet season. Both parents engage in building the nest on floating platform, after clearing out an area of approximately 3 m (9.8 ft) across. The large, flattish nesting platform is often partially submerged in water and can be as much as 3 m (9.8 ft) deep. The nest itself is about 1 to 1.7 m (3.3 to 5.6 ft) wide. Both the nest and platform are made of aquatic vegetation. In Sudan, the nests apparently were able to support the weight of an adult man, although this was not the case in Zambia. From one to three white eggs are laid. These eggs measure 80 to 90 mm (3.1 to 3.5 in) high by 56 to 61 mm (2.2 to 2.4 in) and weigh around 164 g (5.8 oz). Incubation lasts for approximately 30 days. Both parents actively brood, shade, guard and feed the nestling, though the females are perhaps slightly more attentive. Food items are regurgitated whole from the gullet straight into the bill of the young. Shoebills rarely raise more than one chick, but will hatch more. The younger chicks usually die and are intended as "back-ups" in case the eldest chick dies or is weak. Fledging is reached at around 105 days and the young birds can fly well by 112 days. However, they are still fed for possibly a month or more after this. It will take the young shoebills three years before they become fully sexually mature.[12]

Voice

The shoebill is normally silent, but they perform bill-clattering displays at the nest.[2] When engaging in these displays, adult birds have also been noted to utter a cow-like moo as well as high-pitched whines. Both nestlings and adults engage in bill-clattering during the nesting season as a means of communication. When young are begging for food, they call out with a sound uncannily like human hiccups. In one case, a flying adult bird was heard uttering hoarse croaks, apparently as a sign of aggression at a nearby marabou stork (Leptoptilos crumeniferus).[12]

Status and conservation

The population is estimated at between 5,000 and 8,000 individuals, the majority of which live in swamps in South Sudan, Uganda, eastern Democratic Republic of the Congo, and Zambia.[16] There is also a viable population in the Malagarasi wetlands in Tanzania.[17] BirdLife International has classified it as Vulnerable with the main threats being habitat destruction, disturbance and hunting. The bird is listed under Appendix II of the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES).[18]

Relationship to humans

This species is considered to be one of the five most desirable birds in Africa by birdwatchers.[19] They are docile with humans and show no threatening behavior. Researchers were able to observe a bird on its nest at a close distance (within 2 meters).[20]

References

  1. BirdLife International (13 August 2018). "IUCN Red List of Threatened Species: Shoebill". IUCN Red List of Threatened Species. 13 August 2018. Retrieved 6 May 2020.
  2. Handbook of the birds of the world. Barcelona: Lynx Edicions. 1992–2013. ISBN 84-87334-10-5. OCLC 861071869.
  3. Houlihan, Patrick F. (1986). The Birds of Ancient Egypt. Wiltshire: Aris & Phillips. p. 26.
  4. "Dictionary entry for the Latin word "balaena"". Wiktionary - The Free Dictionary. Retrieved 27 May 2020.
  5. Hall, Whitmore (1861). The principal roots and derivatives of the Latin language, with a display of their incorporation into English. London: Longman, Green, Longman & Roberts. p. 153.
  6. Mayr, Gerald (2003). "The phylogenetic affinities of the Shoebill (Balaeniceps rex)" (PDF). Journal für Ornithologie. 144 (2): 157–175. doi:10.1007/BF02465644. S2CID 36046887. Archived from the original (PDF) on 29 September 2018. Retrieved 21 August 2012.
  7. Hagey, J. R.; Schteingart, C. D.; Ton-Nu, H.-T. & Hofmann, A. F. (2002). "A novel primary bile acid in the Shoebill stork and herons and its phylogenetic significance". Journal of Lipid Research. 43 (5): 685–90. PMID 11971938.
  8. Mikhailov, Konstantin E. (1995). "Eggshell structure in the shoebill and pelecaniform birds: comparison with hamerkop, herons, ibises and storks". Canadian Journal of Zoology. 73 (9): 1754–70. doi:10.1139/z95-207.
  9. Hackett, SJ; Kimball, RT; Reddy, S; Bowie, RC; Braun, EL; Braun, MJ; Chojnowski, JL; Cox, WA; Han, KL; et al. (2008). "A phylogenomic study of birds reveals their evolutionary history" (PDF). Science. 320 (5884): 1763–8. Bibcode:2008Sci...320.1763H. doi:10.1126/science.1157704. PMID 18583609. S2CID 6472805.
  10. "Balaeniceps rex" (in German). 19 July 2011. Archived from the original on 19 July 2011. Retrieved 6 May 2020.
  11. Stevenson, Terry; Fanshawe, John (2002). Field guide to the birds of East Africa : Kenya, Tanzania, Uganda, Rwanda, Burundi. London: T & A D Poyser. ISBN 0-85661-079-8. OCLC 47150215.
  12. Hancock, James A.; Kushan (1992). Storks, ibises and spoonbills of the world. London: Academic Press/Harcourt Brace Jovanovich, Publishers. ISBN 0-12-322730-5. OCLC 26933579.
  13. Steffen, Angie. "Balaeniceps rex (shoebill)". Animal Diversity Web. Retrieved 6 May 2020.
  14. Oeschger, E. (2004). "Sahara - Algeria - Rock Art in Oued Derat and the Tefedest Region" (PDF). Adoranten. 2004: 5–19.
  15. Tomita, Julie (2014). "Challenges and successes in the propagation of the Shoebill Balaeniceps rex: with detailed observations from Tampa's Lowry Park Zoo, Florida". International Zoo Yearbook. 48 (1): 69–82. doi:10.1111/izy.12038.
  16. Williams, John G.; Arlott, N (1980). A field guide to the birds of East Africa (Rev. ed.). London: Collins. ISBN 0-00-219179-2. OCLC 7649557.
  17. John, Jasson; Nahonyo, Cuthbert; Lee, Woo; Msuya, Charles (March 2013). "Observations on nesting of shoebill Balaeniceps rex and wattled crane Bugeranus carunculatus in Malagarasi wetlands, western Tanzania". African Journal of Ecology. 51 (1): 184–187. doi:10.1111/aje.12023.
  18. "Appendices I, II and III". Convention on International Trade in Endangered Species of Wild Flora and Fauna. 14 October 2010. Retrieved 20 December 2019.
  19. Matthiessen, Peter (1991). African silences (1st ed.). New York: Random House. p. 56. ISBN 0-679-40021-4. OCLC 22707869.
  20. "Balaeniceps rex (shoebill)". Animal Diversity Web. Retrieved 2 March 2020.

Further reading

Muir, Allan; King, C.E. (January 2013). "Management and husbandry guidelines for Shoebills Balaeniceps rex in captivity". International Zoo Yearbook. 47 (1): 181–189. doi:10.1111/j.1748-1090.2012.00186.x.

Guillet, A (1978). "Distribution and Conservation of the Shoebill (Balaeniceps Rex) in the Southern Sudan". Biological Conservation. 13 (1): 39–50. doi:10.1016/0006-3207(78)90017-4.

Tomita, Julie (2014). "Challenges and successes in the propagation of the Shoebill Balaeniceps rex: with detailed observations from Tampa's Lowry Park Zoo, Florida". International Zoo Yearbook. 132 (1): 69–82. doi:10.1111/izy.12038.

John, Jasson; Nahonyo, Cuthbert; Lee, Woo; Msuya, Charles (March 2013). "Observations on nesting of shoebill Balaeniceps rex and wattled crane Bugeranus carunculatus in Malagarasi wetlands, western Tanzania". African Journal of Ecology. 51 (1): 184–187. doi:10.1111/aje.12023.

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