Red knot

Red knot
Calidris canutus rufa, breeding plumage
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Aves
Order: Charadriiformes
Family: Scolopacidae
Genus: Calidris
Species: C. canutus
Binomial name
Calidris canutus
(Linnaeus, 1758)
Distribution and migration routes of the six subspecies of the red knot
Synonyms

Tringa canutus

The red knot (Calidris canutus) (just knot in English-speaking Europe) is a medium-sized shorebird which breeds in tundra and the Arctic Cordillera in the far north of Canada, Europe, and Russia. It is a large member of the Calidris sandpipers, second only to the great knot.[2] Six subspecies are recognised.

Their diet varies according to season; arthropods and larvae are the preferred food items at the breeding grounds, while various hard-shelled molluscs are consumed at other feeding sites at other times. North American breeders migrate to coastal areas in Europe and South America, while the Eurasian populations winter in Africa, Papua New Guinea, Australia, and New Zealand. This species forms enormous flocks when not breeding.

Taxonomy, systematics, and evolution

The red knot was first described by Linnaeus in the landmark 1758 tenth edition of his Systema Naturae as Tringa canutus.[3] One theory is that it gets its name and species epithet from King Canute, knot being another form of Canute; the name would refer to the knot's foraging along the tide line and the story of Canute and the tide.[4] There appears to be no historical foundation for this etymology.[5] Another etymology is that the name is onomatopoeic, based on the bird's grunting call note.[6]

 
Population relatedness and divergence

 


canutus


 

 


roselaari



rufa



islandica



 


piersmai



rogersi





The diversification events may be associated with the Wisconsinan (Weichselian) glaciation 18,000 to 22,000 years ago; the opening of the ice-free corridor in North America 12,000 to 14,000 years ago; and the Holocene climatic optimum 7,000 to 9,000 years ago.[7]

The red knot and the great knot were originally the only two species placed in the genus Calidris, but many other species of sandpiper were subsequently added.[8] A 2004 study found that the genus was polyphyletic and that the closest relative of the two knot species is the surfbird (currently Aphriza virgata).[9]

There are six subspecies,[10] in order of size;

Studies based on mitochondrial sequence divergence and models of paleoclimatic changes during the glacial cycles suggest that canutus is the most basal population, separating about 20,000 years ago (95% confidence interval: 60,000–4,000 years ago) with two distinct lineages of the American and Siberian breeders emerging about 12,000 years ago (with a 95% confidence interval: 45,000–3,500 years ago).[7][11]

Distribution and migration

Large flocks of C. c. islandica winter in the coastal marshes of Britain, along with other waders. The Wash, Norfolk

In the breeding season, the red knot has a circumpolar distribution in the high Arctic, then migrates to coasts around the world from 50° N to 58° S. The red knot has one of the longest migrations of any bird. Every year it travels more than 9,000 mi (14,000 km) from the Arctic to the southern tip of South America.[12] The exact migration routes and wintering grounds of individual subspecies are still somewhat uncertain. The nominate race C. c. canutus breeds in the Taymyr Peninsula and possibly Yakutia and migrates to Western Europe and then down to western and southern Africa. C. c. rogersi breeds in the Chukchi Peninsula in eastern Siberia, and winters in eastern Australia and New Zealand.[8] Small and declining numbers[13] of rogersi (but possibly of the later described piersmai) winter in the mudflats in the Gulf of Mannar and on the eastern coast[14] of India.[15] The recently split race C. c. piersmai breeds in the New Siberian Islands and winters in north-western Australia.[16] C. c. roselaari breeds in Wrangel Island in Siberia and north-western Alaska, and it apparently winters in Florida, Panama and Venezuela. C. c. rufa breeds in the Canadian low Arctic, and winters South America, and C. c. islandica breeds in the Canadian high Arctic as well as Greenland, and winters in Western Europe.

Birds wintering in west Africa were found to restrict their daily foraging to a range of just 2–16 km2 (0.77–6.18 sq mi) of intertidal area and roosted a single site for several months. In temperate regions such as the Wadden Sea they have been found to change roost sites each week and their feeding range may be as much as 800 km2 (310 sq mi) during the course of a week.[17]

B95, also known as Moonbird, is a noted individual of the subspecies C. c. rufa. A male, he has become famous amongst conservationists for his extreme longevity — he was aged at least 20 as of his last sighting in May 2014.[18]

Description and anatomy

Nonbreeding adult

An adult red knot is the second largest Calidris sandpiper, measuring 23–26 cm (9.1–10.2 in) long with a 47–53 cm (19–21 in) wingspan. The body shape is typical for the genus, with a small head and eyes, a short neck and a slightly tapering bill that is no longer than its head.[19] It has short dark legs and a medium thin dark bill. The winter, or basic, plumage becomes uniformly pale grey, and is similar between the sexes. The alternate, or breeding, plumage is mottled grey on top with a cinnamon face, throat and breast and light-coloured rear belly. The alternate plumage of females is similar to that of the male except it is slightly lighter and the eye-line is less distinct. Canutus, islandica and piersmai are the "darker" subspecies. Subspecies rogersi has a lighter belly than either roselaari or piersmai, and rufa is the lightest in overall plumage. The transition from alternate to basic plumages begins at the breeding site but is most pronounced during the southwards migration. The molt to alternate plumage begins just prior to the northwards migration to the breeding grounds, but is mostly during the migration period.[19]

The large size, white wing bar and grey rump and tail make it easy to identify in flight. When feeding the short dark green legs give it a characteristic 'low-slung' appearance. When foraging singly, they rarely call, but when flying in a flock they make a low monosyllabic knutt and when migrating they utter a disyllabic knuup-knuup. They breed in the moist tundra during June to August. The display song of the male is a fluty poor-me. The display includes circling high with quivering wing beats and tumbling to the ground with the wings held upward. Both sexes incubate the eggs, but the female leaves parental care to the male once the eggs have hatched.[2]

Juvenile birds have distinctive submarginal lines and brown coverts during the first year. In the breeding season the males can be separated with difficulty (<80% accuracy in comparison to molecular methods[20]) based on the more even shade of the red underparts that extend towards the rear of the belly.[2]

The weight varies with subspecies, but ranges between 100 and 200 g (3.5 and 7.1 oz). Red knots can double their weight prior to migration. Like many migratory birds they also reduce the size of their digestive organs prior to migration. The extent of the atrophy is not as pronounced as species like the bar-tailed godwit, probably because there are more opportunities to feed during migration for the red knot.[21] Red knots are also able to change the size of their digestive organs seasonally. The size of the gizzard increases in thickness when feeding on harder foods on the wintering ground and decreases in size while feeding on softer foods in the breeding grounds. These changes can be very rapid, occurring in as little as six days.[22][23]

Behaviour

Diet and feeding

On the breeding grounds, knots eat mostly spiders, arthropods, and larvae obtained by surface pecking, and on the wintering and migratory grounds they eat a variety of hard-shelled prey such as bivalves, gastropods and small crabs that are ingested whole and crushed by a muscular stomach.[19]

While feeding in mudflats during the winter and migration red knots are tactile feeders, probing for unseen prey in the mud. Their feeding techniques include the use of shallow probes into the mud while pacing along the shore. When the tide is ebbing, they tend to peck at the surface and in soft mud they may probe and plough forward with the bill inserted to about 1 cm (0.39 in) in depth. The bivalved mollusc Macoma is their preferred prey on European coasts, swallowing them whole and breaking them up in their gizzard.[24][25] In Delaware Bay, they feed in large numbers on the eggs of horseshoe crabs which spawn just as the birds arrive in mid-summer.[26] They are able to detect molluscs buried under wet sand from changes in the pressure of water that they sense using Herbst corpuscles in their bill.[27] Unlike many tactile feeders their visual field is not panoramic (allowing for an almost 360 degree field of view), as during the short breeding season they switch to being visual hunters of mobile, unconcealed prey, which are obtained by pecking.[28] Pecking is also used to obtain some surface foods in the wintering and migratory feeding grounds, such as the eggs of horseshoe crabs.[19]

Breeding

Calidris canutus MHNT
Red knot in breeding plumage

The red knot is territorial and seasonally monogamous; it is unknown if pairs remain together from season to season. Males and females breeding in Russia have been shown to exhibit site fidelity towards their breeding locales from year to year, but there is no evidence as to whether they exhibit territorial fidelity. Males arrive before females after migration and begin defending territories. As soon as males arrive, they begin displaying, and aggressively defending their territory from other males.[19]

The red knot nests on the ground, near water, and usually inland. The nest is a shallow scrape lined with leaves, lichens and moss.[12] Males construct three to five nest scrapes in their territories prior to the arrival of the females. The female lays three or more usually four eggs, apparently laid over the course of six days. The eggs measure 43 mm × 30 mm (1.7 in × 1.2 in) in size and are ground coloured, light olive to deep olive buff, with a slight gloss. Both parents incubate the eggs, sharing the duties equally. The off duty parent forages in flocks with others of the same species. The incubation period lasting around 22 days. At early stages of incubation the adults are easily flushed from the nest by the presence of humans near the nest, and may not return for several hours after being flushed. However, in later stages of incubation they will stay fast on the eggs. Hatching of the clutch is usually synchronised. The chicks are precocial at hatching, covered in downy cryptic feathers. The chicks and the parents move away from the nest within a day of hatching and begin foraging with their parents. The female leaves before the young fledge while the males stay on. After the young have fledged, the male begins his migration south and the young make their first migration on their own.[19]

Status

The red knot has an extensive range, estimated at 100,000–1,000,000 km2 (39,000–386,000 sq mi), and a large population of about 1.1 million individuals. The species is not believed to approach the thresholds for the population decline criterion of the IUCN Red List (i.e., declining more than 30% in ten years or three generations), and is therefore evaluated as Least Concern.[1] However many local declines have been noted such as the dredging of intertidal flats for edible cockles (Cerastoderma edule) which led to reductions in the wintering of islandica in the Dutch Wadden Sea.[29] The quality of food at migratory stopover sites is a critical factor in their migration strategy.[30]

This is one of the species to which the Agreement on the Conservation of African-Eurasian Migratory Waterbirds (AEWA) applies.[31] This commits signatories to regulate the taking of listed species or their eggs, to establish protected areas to conserve habitats for the listed species, to regulate hunting and to monitor the populations of the birds concerned.[32]

Threats to the subspecies rufa

Large numbers of brown, white and reddish birds dip their heads into shallow water behind the carapace of a large crab-like creature
Red knot feeding on horseshoe crab eggs in Delaware Bay

Towards the end of the 19th century, large numbers of red knot were shot for food as they migrated through North America. It is hypothesized that more recently, the birds have become threatened as a result of commercial harvesting of horseshoe crabs in the Delaware Bay which began in the early 1990s. Delaware Bay is a critical stopover point during spring migration; the birds refuel by eating the eggs laid by these crabs (with little else to eat in the Delaware Bay).[33] If horseshoe crab abundance in the Bay is reduced there may fewer eggs to feed on which could negatively affect knot survival.[34][35][36]

In 2003, scientists projected that at its current rate of decline the American subspecies, rufa, might become extinct as early as 2010, but as of April 2011 the subspecies is still extant. In New Jersey, state and local agencies are taking steps to protect these birds by limiting horseshoe crab harvesting and restricting beach access. In Delaware, a two-year ban on the harvesting of horseshoe crabs was enacted but struck down by a judge who cited insufficient evidence to justify the potential disruption to the fishing industry but a male-only harvest has been in place in recent years.

Late in the fall of 2014, the red knot rufa was listed as a federally threatened species under the United States Endangered Species Act[37][38] – the second most critical status that can be awarded to a subspecies. This followed a decade of intensive petitioning by environmental groups and a lawsuit against the Department of the Interior for alleged negligence in the protection of endangered species through failure to evaluate and list them. The reasons for the red knot rufa's listing were varied; habitat degradation, loss of key food supplies, and threats posed by climate change and sea level rise were all listed as factors that were considered when the red knot rufa was listed.[37]

References

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  2. 1 2 3 Marchant, John; Hayman, Peter; Prater, Tony (1986). Shorebirds: an identification guide to the waders of the world. Boston: Houghton Mifflin. pp. 363–364. ISBN 0-395-37903-2.
  3. (in Latin) Linnaeus, Carl (1758). Systema naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis. Tomus I. Editio decima, reformata. Holmiae. (Laurentii Salvii). p. 149. T. roftro laevi, pedibus cinerascentibus, remigibus primoribus ferratis.
  4. Holloway, Joel Ellis (2003). Dictionary of Birds of the United States: Scientific and Common Names. Portland, Oregon: Timber Press. p. 50. ISBN 0-88192-600-0.
  5. "Knot". Oxford English Dictionary (3rd ed.). Oxford University Press. September 2005. (Subscription or UK public library membership required.)
  6. Higgins, Peter J.; Davies, S.J.J.F., eds. (1996). Handbook of Australian, New Zealand and Antarctic Birds. Vol. 3: Snipe to Pigeons. Melbourne, Victoria: Oxford University Press. pp. 224–232. ISBN 0-19-553070-5.
  7. 1 2 Buehler, Deborah M.; Baker, Allan J.; Piersma, Theunis (2006). "Reconstructing palaeoflyways of the late Pleistocene and early Holocene Red Knot Calidris canutus" (PDF). Ardea. 94 (3): 485–498.
  8. 1 2 Piersma, T.; van Gils, J.; Wiersma, P. (1996). "Scolopacidae (Sandpipers and Allies)". In Josep, del Hoyo; Andrew, Sargatal; Jordi, Christie. Handbook of the Birds of the World. Volume 3, Hoatzin to Auks. Barcelona: Lynx Edicions. p. 519. ISBN 84-87334-20-2.
  9. Thomas, Gavin H.; Wills, Matthew A.; Székely, Tamás (2004). "A supertree approach to shorebird phylogeny". BMC Evolutionary Biology. 4 (28): 1–18. PMC 515296Freely accessible. PMID 15329156. doi:10.1186/1471-2148-4-28.
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  12. 1 2 "Red Knot Fact Sheet". www.lpzoo.org. Lincoln Park Zoo. External link in |website= (help)
  13. Boere, G.C.; Galbraith, C.A.; Stroud, D.A., eds. (2006). "Waterbirds around the world" (PDF). Edinburgh, UK: The Stationery Office.
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  16. Tomkovich, P.S. (2001). "A new subspecies of Red Knot Calidris canutus from the New Siberian Islands". Bulletin of the British Ornithologists' Club. 121: 257–263.
  17. Leyrer, Jutta; Spaans, Bernard; Camara, Mohamed; Piersma, Theunis (2006). "Small home ranges and high site fidelity in red knots (Calidris c. canutus) wintering on the Banc d'Arguin, Mauritania" (PDF). Journal of Ornithology. 147 (2): 376–384. doi:10.1007/s10336-005-0030-8.
  18. Bauers, Sandy. "Globe-spanning bird B95 is back for another year". Philadelphia Inquirer. Retrieved 2 June 2014.
  19. 1 2 3 4 5 6 Baker, Allan; Gonzalez, Patricia; Morrison, R.I.G.; Harrington, Brian A. (2013). Poole, A., ed. "Red Knot (Calidris canutus)". The Birds of North America Online. Ithaca: Cornell Lab of Ornithology. doi:10.2173/bna.563. Retrieved 27 April 2009.
  20. Baker, A.J.; Piersma, T.; Greenslade, A.D. (1999). "Molecular vs. phenotypic sexing in red knots" (PDF). The Condor. Cooper Ornithological Society. 101 (4): 887–893. JSTOR 1370083. doi:10.2307/1370083.
  21. Piersma, Theunis (1998). "Phenotypic Flexibility during Migration: Optimization of Organ Size Contingent on the Risks and Rewards of Fueling and Flight?". Journal of Avian Biology. Blackwell Publishing. 29 (4): 511–520. JSTOR 3677170. doi:10.2307/3677170.
  22. Dekinga, A.; Dietz, M.W.; Koolhaas, A.; Piersma, T. (2001). "Time course and reversibility of changes in the gizzards of red knots alternately eating hard and soft food" (PDF). Journal of Experimental Biology. 204 (12): 2167–2173.
  23. Piersma, Theunis; Dietz, M.W.; Dekinga, A.; Nebel, S.; van Gils, J.A.; Battley, P.F.; Spaans, B. (1999). "Reversible size-changes in stomachs of shorebirds: when, to what extent, and why?" (PDF). Acta Ornithologica. 34: 175–181.
  24. Prater, A.J. (1972). "The Ecology of Morecambe Bay. III. The Food and Feeding Habits of Knot (Calidris canutus L.) in Morecambe Bay". Journal of Applied Ecology. British Ecological Society. 9 (1): 179–194. JSTOR 2402055. doi:10.2307/2402055.
  25. Zwarts, L.; Blomert, A-M. (1992). "Why knot Calidris canutus take medium-sized Macoma balthica when six prey species are available" (PDF). Marine Ecology Progress Series. 83 (2–3): 113–128. doi:10.3354/meps083113.
  26. "Petition to List the Red Knot (Caladris canutus rufa) as Endangered and Request for Emergency Listing under the Endangered Species Act" (PDF). Federal Wildlife Service. 2 August 2005. Retrieved 27 March 2009.
  27. Piersma, Theunis; van Aelst, Renee; Kurk, Karin; Berkhoudt, Herman; Maas, Leo R.M. (1998). "A new pressure sensory mechanism for prey detection in birds: the use of principles of seabed dynamics?" (PDF). Proceedings of the Royal Society B: Biological Sciences. 265 (1404): 1377–1383. doi:10.1098/rspb.1998.0445.
  28. Martin, Graham R.; Piersma, Theunis (2009). "Vision and touch in relation to foraging and predator detection: insightful contrasts between a plover and a sandpiper". Proceedings of the Royal Society B. 276 (1656): 437–445. PMC 2664340Freely accessible. PMID 18842546. doi:10.1098/rspb.2008.1110.
  29. van Gils, Jan A.; Piersma, Theunis; Dekinga, Anne; Spaans, Bernard; Kraan, Casper (2006). "Shellfish Dredging Pushes a Flexible Avian Top Predator out of a Marine Protected Area". PLOS Biology. 4 (12): e376. PMC 1635749Freely accessible. PMID 17105350. doi:10.1371/journal.pbio.0040376.
  30. van Gils, Jan A.; Battley, Phil F.; Piersma, Theunis; Drent, Rudi (2005). "Reinterpretation of gizzard sizes of red knots world-wide emphasises overriding importance of prey quality at migratory stopover sites". Proceedings of the Royal Society B. 272 (1581): 2609–2618. PMC 1559986Freely accessible. PMID 16321783. doi:10.1098/rspb.2005.3245.
  31. "Annex 2: Waterbird species to which the Agreement applies" (PDF). Agreement on the conservation of African-Eurasian migratory Waterbirds (AEWA). AEWA. Retrieved 22 April 2008.
  32. "Annex 3: Waterbird species to which the Agreement applies" (PDF). Agreement on the conservation of African-Eurasian migratory Waterbirds (AEWA). AEWA. Retrieved 22 April 2008.
  33. Karpanty, Sarah; Fraser, James D.; Berkson, Jim; Niles, Lawrence J.; Dey, Amanda; Smith, Eric P. (2006). "Horseshoe crab eggs determine red knot distribution in Delaware Bay". Journal of Wildlife Management. 70 (6): 1704–1710. JSTOR 4128104. doi:10.2193/0022-541X(2006)70[1704:HCEDRK]2.0.CO;2.
  34. Baker, Allan J.; Gonzalez, Patricia M.; Piersma, Theunis; Niles, Lawrence J.; do Nascimento, Inês de Lima Serrano; Atkinson, Philip W.; Clark, Nigel A.; Minton, Clive D.T.; Peck, Mark K.; Aarts, Geert (2004). "Rapid population decline in red knots: fitness consequences of decreased refueling rates and late arrival in Delaware Bay". Proceedings of the Royal Society B. 271 (1541): 875–882. PMC 1691665Freely accessible. PMID 15255108. doi:10.1098/rspb.2003.2663.
  35. Niles, Lawrence J.; Sitters, Humphrey P.; Dey, Amanda D.; Atkinson, Philip W.; Baker, Allan J.; Bennett, Karen A.; Carmona, Roberto; Clark, Kathleen E.; Clark, Nigel A.; Espoz, Carmen; González, Patricia M.; Harrington, Brian A.; Hernández, Daniel E.; Kalasz, Kevin S.; Lathrop, Richard G.; Matus, Ricardo N.; Minton, Clive D.T.; Morrison, R.I. Guy; Peck, Mark K.; Pitts, William; Robinson, Robert A.; Serrano, Inês L. (2008). "Status of the Red Knot (Calidris canutus rufa) in the Western Hemisphere" (PDF). Studies in Avian Biology No. 36. Cooper Ornithological Society.
  36. Niles, Lawrence J.; Bart, Jonathan; Sitters, Humphrey P.; Dey, Amanda D.; Clark, Kathleen E.; Atkinson, Philip W.; Baker, Allan J.; Bennett, Karen A.; Kalasz, Kevin S.; Clark, Nigel A.; Clark, Jacquie; Gillings, Simon; Gates, Albert S.; González, Patricia M.; Hernández, Daniel E.; Minton, Clive D.T.; Morrison, R.I. Guy; Porter, Ronald R.; Ross, R. Ken; Veitch, C. Richard (2009). "Effects of horseshoe crab harvest in Delaware Bay on red knots: are harvest restrictions working?". BioScience. 59 (2): 153–164. doi:10.1525/bio.2009.59.2.8.
  37. 1 2 http://www.fws.gov/northeast/redknot/
  38. http://ecos.fws.gov/speciesProfile/profile/speciesProfile.action?spcode=B0DM
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