Superregnum: Eukaryota
Cladus: Unikonta
Cladus: Opisthokonta
Cladus: Holozoa
Regnum: Animalia
Subregnum: Eumetazoa
Cladus: Bilateria
Cladus: Nephrozoa
Superphylum: Deuterostomia
Phylum: Chordata
Subphylum: Vertebrata
Infraphylum: Gnathostomata
Megaclassis: Osteichthyes
Cladus: Sarcopterygii
Cladus: Rhipidistia
Cladus: Tetrapodomorpha
Cladus: Eotetrapodiformes
Cladus: Elpistostegalia
Superclassis: Tetrapoda
Cladus: Reptiliomorpha
Cladus: Amniota
Cladus: Synapsida
Cladus: Eupelycosauria
Cladus: Sphenacodontia
Cladus: Sphenacodontoidea
Cladus: Therapsida
Cladus: Theriodontia
Cladus: Cynodontia
Cladus: Eucynodontia
Cladus: Probainognathia
Cladus: Prozostrodontia
Cladus: Mammaliaformes
Classis: Mammalia
Cladus: Theriimorpha
Cladus: Theriiformes
Cladus: Trechnotheria
Cladus: Zatheria
Subclassis: Theria
Cladus: Eutheria
Infraclassis: Placentalia
Magnordo: Boreoeutheria
Superordo: Laurasiatheria
Cladus: Scrotifera
Grandordo: Ferungulata
Mirordo: Ferae
Cladus: Pancarnivora
Cladus: Carnivoramorpha
Cladus: Carnivoraformes
Ordo: Carnivora
Subordo: Caniformia
Infraordo: Arctoidea
Parvordo: Mustelida
Cladus: Pan-Pinnipedia
Cladus: Pinnipedimorpha
Cladus: Pinnipediformes
Cladus: Pinnipedia
Superfamilia: Phocoidea
Familia: Phocidae
Subfamiliae: Cystophorinae – Monachinae – Phocinae – †Devinophocinae
Conspectus generum
Cystophora - Erignathus - Halichoerus - Histriophoca - Hydrurga - Leptonychotes - Lobodon - Mirounga - Monachus – Neomonachus – Ommatophoca - Pagophilus - Phoca - Pusa – †Acrophoca – †Afrophoca – †Auroraphoca – †Australophoca – †Batavipusa – †Callophoca – †Cryptophoca – †Devinophoca – †Eomonachus – †Frisiphoca – †Gryphoca – †Hadrokirus – †Homiphoca – †Kawas – †Leptophoca – †Magnotherium – †Magophoca – †Monachopsis – †Nanophoca – †Necromites – †Noriphoca – †Pachyphoca – †Palmidophoca – †Phocanella – †Piscophoca – †Planopusa – †Platyphoca – †Pliophoca – †Pontophoca – †Praepusa – †Prophoca – †Sarcodectes – †Sarmatonectes – †Seronectes – †Virginiaphoca
Name
Phocidae Gray, 1821
Synonymy
Phocadae Gray, 1821: 302
Phocidae Gray, 1825: 340
References
Primary references
Gray, J.E. 1821. On the Natural Arrangement of Vertebrose Animals. London Medical Repository 15: 296–310. HathiTrust. Reference page.
Gray, J.E. 1825. An Outline of an Attempt at the Disposition of Mammalia into Tribes and Families, with a List of the Genera apparently appertaining to each Tribe. Annals of Philosophy (ns) 10: 337–344. BHL Reference page.
Links
Phocidae in Mammal Species of the World.
Wilson, Don E. & Reeder, DeeAnn M. (Editors) 2005. Mammal Species of the World – A Taxonomic and Geographic Reference. Third edition. ISBN 0-8018-8221-4.
Vernacular names
Afrikaans: Robbe
azərbaycanca: Əsl suitilər
беларуская: Сапраўдныя цюлені
български: Същински тюлени
català: Foca
čeština: Tuleňovití
dansk: Ægte sæler
Deutsch: Hundsrobben
English: Earless seal
español: Fócidos
eesti: Hülglased
euskara: Itsas txakur
suomi: Hylkeet
Nordfriisk: Siahünjer
français: Phoque
galego: Foca
עברית: כלבי ים
hrvatski: Pravi tuljani
magyar: Valódi fókafélék
íslenska: Selaatt
italiano: Foche
日本語: アザラシ
ქართული: სელაპისებრნი
한국어: 물범과
lietuvių: Tikrieji ruoniai
latviešu: Roņi
македонски: Вистински фоки
Nederlands: Zeehonden
norsk nynorsk: Ekte sel
norsk: Hårselfamilien
polski: Fokowate
português: Foca
русский: Настоящие тюлени
svenska: Öronlösa sälar
ไทย: วงศ์แมวน้ำ
Türkçe: Fokgiller
українська: Тюленеві
Tiếng Việt: Họ Hải cẩu thật sự
閩南語 / Bân-lâm-gú: Hái-pà
粵語: 海豹
中文: 海豹
The earless seals, phocids, or true seals are one of the three main groups of mammals within the seal lineage, Pinnipedia. All true seals are members of the family Phocidae (/ˈfoʊsɪdiː/). They are sometimes called crawling seals to distinguish them from the fur seals and sea lions of the family Otariidae. Seals live in the oceans of both hemispheres and, with the exception of the more tropical monk seals, are mostly confined to polar, subpolar, and temperate climates. The Baikal seal is the only species of exclusively freshwater seal.
Taxonomy and evolution
Evolution
Fossil Pliophoca skull
The earliest known fossil earless seal is Noriphoca gaudini from the late Oligocene or earliest Miocene (Aquitanian) of Italy.[1] Other early fossil phocids date from the mid-Miocene, 15 million years ago in the north Atlantic.[1][3] Until recently, many researchers believed that phocids evolved separately from otariids and odobenids; and that they evolved from otter-like animals, such as Potamotherium, which inhabited European freshwater lakes. Recent evidence strongly suggests a monophyletic origin for all pinnipeds from a single ancestor, possibly Enaliarctos, most closely related to the mustelids and bears.[4]
Monk seals and elephant seals were previously believed to have first entered the Pacific through the open straits between North and South America,[5] with the Antarctic true seals either using the same route or travelled down the west coast of Africa.[6] It is now thought that the monk seals, elephant seals, and Antarctic seals all evolved in the southern hemisphere, and likely dispersed to their current distributions from more southern latitudes.[7]
Taxonomy
Pinnipedia |
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Cladogram showing relationships among the phocids, combining several phylogenetic analyses.[8]
In the 1980s and 1990s, morphological phylogenetic analysis of the phocids led to new conclusions about the interrelatedness of the various genera. More recent molecular phylogenetic analyses have confirmed the monophyly of the two phocid subfamilies (Phocinae and Monachinae).[9][10][11][5] The Monachinae (known as the "southern" seals), is composed of three tribes; the Lobodontini, Miroungini, and Monachini. The four Antarctic genera Hydrurga, Leptonychotes, Lobodon, and Ommatophoca are part of the tribe Lobodontini. Tribe Miroungini is composed of the elephant seals. The Monk seals (Monachus and Neomonachus) are all part of the tribe Monachini.[12] Likewise, subfamily Phocinae (the "northern" seals) also includes three tribes; Erignathini (Erignathus), Cystophorini (Cystophora), and Phocini (all other phocines). More recently, five species have been split off from Phoca, forming three additional genera.[13]
Alternatively the three monachine tribes have been evaluated to familiar status, which elephant seals and the Antarctic seals are more closely related to the phocines.[14]
Extant genera
Subfamily | Tribe | Image | Genus | species |
---|---|---|---|---|
Subfamily Monachinae | Tribe Monachini | Monachus Fleming, 1822 |
|
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Neomonachus Slater & Helgen, 2014 |
|
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Tribe Miroungini | Mirounga Gray, 1827 |
|
||
Tribe Lobodontini | Ommatophoca Gray, 1844 |
|
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Lobodon Gray, 1844 |
|
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Hydrurga Gistel, 1848 |
|
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Leptonychotes Gill, 1872 |
|
|||
Subfamily Phocinae | Tribe Cystophorini | Cystophora Nilsson, 1820 |
|
|
Tribe Erignathini | Erignathus Gill, 1866 |
|
||
Tribe Phocini | Phoca Linnaeus, 1758 |
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Pusa Scopoli, 1771 |
|
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Pagophilus Gray, 1844 |
|
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Histriophoca Gill, 1873 |
|
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Halichoerus Nilsson, 1820 |
|
Biology
External anatomy
Skeletal anatomy of a harbor seal. 1. Skull. 2. Spine. 3. Tail. 4. Hindlimb. 5. Forelimb. 6. Shoulder. 7. Pelvis. 8. Rib cage.
Harbor seal skull (Phoca vitulina)
Adult phocids vary from 1.17 m (3.8 ft) in length and 45 kg (99 lb) in weight in the ringed seal to 5.8 m (19 ft) and 4,000 kg (8,800 lb) in the southern elephant seal, which is the largest member of the order Carnivora. Phocids have fewer teeth than land-based members of the Carnivora, although they retain powerful canines. Some species lack molars altogether. The dental formula is: 2–3.1.4.0–21–2.1.4.0–2
While otariids are known for speed and maneuverability, phocids are known for efficient, economical movement. This allows most phocids to forage far from land to exploit prey resources, while otariids are tied to rich upwelling zones close to breeding sites. Phocids swim by sideways movements of their bodies, using their hind flippers to fullest effect.[15] Their fore flippers are used primarily for steering, while their hind flippers are bound to the pelvis in such a way that they cannot bring them under their bodies to walk on them. They are more streamlined than fur seals and sea lions, so they can swim more effectively over long distances. However, because they cannot turn their hind flippers downward, they are very clumsy on land, having to wriggle with their front flippers and abdominal muscles.
Seal kidney
Phocid respiratory and circulatory systems are adapted to allow diving to considerable depths, and they can spend a long time underwater between breaths. Air is forced from the lungs during a dive and into the upper respiratory passages, where gases cannot easily be absorbed into the bloodstream. This helps protect the seal from the bends. The middle ear is also lined with blood sinuses that inflate during diving, helping to maintain a constant pressure.[15]
Phocids are more specialized for aquatic life than otariids. They lack external ears and have sleek, streamlined bodies. Retractable nipples, internal testicles,[16] and an internal penile sheath provide further streamlining. A smooth layer of blubber lies underneath the skin. Phocids are able to divert blood flow to this layer to help control their temperatures.[17]
Communication
Unlike otariids, true seals do not communicate by 'barking'. Instead, they communicate by slapping the water and grunting.
Reproduction
Photo of seven adult and juvenile southern elephant seals packed closely on beach
Southern elephant seals in Argentina
Living only in Lake Saimaa, Finland, Saimaa ringed seals, a subspecies of ringed seal, are among the most endangered seals in the world, having a total population of only about 400 individuals.[18]
Phocids spend most of their time at sea, although they return to land or pack ice to breed and give birth. Pregnant females spend long periods foraging at sea, building up fat reserves, and then return to the breeding site to use their stored energy to nurse pups. However, the common seal displays a reproductive strategy similar to that used by otariids, in which the mother makes short foraging trips between nursing bouts.
Because a phocid mother's feeding grounds are often hundreds of kilometers from the breeding site, she must fast while lactating. This combination of fasting with lactation requires the mother to provide large amounts of energy to her pup at a time when she is not eating (and often, not drinking). Mothers must supply their own metabolic needs while nursing. This is a miniature version of the humpback whales' strategy, which involves fasting during their months-long migration from arctic feeding areas to tropical breeding/nursing areas and back.
Phocids produce thick, fat-rich milk that allows them to provide their pups with large amounts of energy in a short period. This allows the mother to return to the sea in time to replenish her reserves. Lactation ranges from five to seven weeks in the monk seal to just three to five days in the hooded seal. The mother ends nursing by leaving her pup at the breeding site to search for food (pups continue to nurse if given the opportunity). "Milk stealers" that suckle from unrelated, sleeping females are not uncommon; this often results in the death of the mother's pup, since a female can only feed one pup.
Growth and maturation
The pup's diet is so high in calories that it builds up a fat store. Before the pup is ready to forage, the mother abandons it, and the pup consumes its own fat for weeks or even months while it matures. Seals, like all marine mammals, need time to develop the oxygen stores, swimming muscles, and neural pathways necessary for effective diving and foraging. Seal pups typically eat no food and drink no water during the period, although some polar species eat snow. The postweaning fast ranges from two weeks in the hooded seal to 9–12 weeks in the northern elephant seal.[19] The physiological and behavioral adaptations that allow phocid pups to endure these remarkable fasts, which are among the longest for any mammal, remain an area of active study and research.
Feeding strategy
Phocids make use of at least four different feeding strategies: suction feeding, grip and tear feeding, filter feeding, and pierce feeding. Each of these feeding strategies is aided by a specialized skull, mandible, and tooth morphology. However, despite morphological specialization, most phocids are opportunistic and employ multiple strategies to capture and eat prey. For example, the leopard seal, Hydrurga leptonyx, uses grip and tear feeding to prey on penguins, suction feeding to consume small fish, and filter feeding to catch krill.[20]
See also
iconMammals portaliconAnimals portalMarine life portal
Marine mammals as food
References
Leonard Dewaele; Olivier Lambert; Stephen Louwye (2018). "A critical revision of the fossil record, stratigraphy and diversity of the Neogene seal genus Monotherium (Carnivora, Phocidae)". Royal Society Open Science. 5 (5): 171669. Bibcode:2018RSOS....571669D. doi:10.1098/rsos.171669. PMC 5990722. PMID 29892365.
Wozencraft, W. C. (2005). "Order Carnivora". In Wilson, D. E.; Reeder, D. M. (eds.). Mammal Species of the World: A Taxonomic and Geographic Reference (3rd ed.). Johns Hopkins University Press. ISBN 978-0-8018-8221-0. OCLC 62265494.
Dewaele, Leonard; Lambert, Olivier; Louwye, Stephen (2017-02-21). "On Prophoca and Leptophoca (Pinnipedia, Phocidae) from the Miocene of the North Atlantic realm: redescription, phylogenetic affinities and paleobiogeographic implications". PeerJ. 5: e3024. doi:10.7717/peerj.3024. PMC 5322758. PMID 28243538.
Paterson, Ryan S.; Rybczynski, Natalia; Kohno, Naoki; Maddin, Hillary C. (2020). "A Total Evidence Phylogenetic Analysis of Pinniped Phylogeny and the Possibility of Parallel Evolution Within a Monophyletic Framework". Frontiers in Ecology and Evolution. 7. doi:10.3389/fevo.2019.00457.
Fulton, Tara L.; Strobeck, Curtis (2010). "Multiple fossil calibrations, nuclear loci and mitochondrial genomes provide new insight into biogeography and divergence timing for true seals (Phocidae, Pinnipedia)". Journal of Biogeography. 37 (5): 814–829. Bibcode:2010JBiog..37..814F. doi:10.1111/j.1365-2699.2010.02271.x. S2CID 59436229.
Savage, RJG & Long, MR (1986). Mammal Evolution: an illustrated guide. New York: Facts on File. pp. 94–95. ISBN 978-0-8160-1194-0.
Rule, James P.; Adams, Justin W.; Marx, Felix G.; Evans, Alistair R.; Tennyson, Alan J. D.; Scofield, R. Paul; Fitzgerald, Erich M. G. (2020-11-11). "First monk seal from the Southern Hemisphere rewrites the evolutionary history of true seals". Proceedings of the Royal Society B: Biological Sciences. 287 (1938): 20202318. doi:10.1098/rspb.2020.2318. PMC 7735288. PMID 33171079.
Berta, Annalisa; Churchill, Morgan; Boessenecker, Robert W. (2018-05-30). "The Origin and Evolutionary Biology of Pinnipeds: Seals, Sea Lions, and Walruses". Annual Review of Earth and Planetary Sciences. 46 (1). Annual Reviews: 203–228. Bibcode:2018AREPS..46..203B. doi:10.1146/annurev-earth-082517-010009. ISSN 0084-6597. S2CID 135439365.
Árnason, Úlfur; Bodin, Kristina; Gullberg, Anette; Ledje, Christina; Suzette, Mouchaty (1995). "A molecular view of pinniped relationships with particular emphasis on the true seals". Journal of Molecular Evolution. 40 (1): 78–85. Bibcode:1995JMolE..40...78A. doi:10.1007/BF00166598. PMID 7714914. S2CID 7537924.
Arnason, Ulfur; Gullberg, Anette; Janke, Axel; Kullberg, Morgan; Lehman, Niles; Petrov, Evgeny A.; Väinölä, Risto (2006-11-01). "Pinniped phylogeny and a new hypothesis for their origin and dispersal". Molecular Phylogenetics and Evolution. 41 (2): 345–354. doi:10.1016/j.ympev.2006.05.022. PMID 16815048.
Fulton, Tara Lynn; Strobeck, Curtis (2010). "Multiple markers and multiple individuals refine true seal phylogeny and bring molecules and morphology back in line". Proceedings of the Royal Society B: Biological Sciences. 277 (1684): 1065–1070. doi:10.1098/rspb.2009.1783. PMC 2842760. PMID 19939841.
Scheel, Dirk-Martin; Slater, Graham J.; Kolokotronis, Sergios-Orestis; Potter, Charles W.; Rotstein, David S.; Tsangaras, Kyriakos; Greenwood, Alex D.; Helgen, Kristofer M. (2014). "Biogeography and taxonomy of extinct and endangered monk seals illuminated by ancient DNA and skull morphology". ZooKeys (409): 1–33. Bibcode:2014ZooK..409....1S. doi:10.3897/zookeys.409.6244. PMC 4042687. PMID 24899841.
Berta, Annalisa; Churchill, Morgan (2012). "Pinniped taxonomy: review of currently recognized species and subspecies, and evidence used for their description". Mammal Review. 42 (3): 207–234. doi:10.1111/j.1365-2907.2011.00193.x.
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"Saimaa Ringed Seal". Retrieved 22 December 2018.
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