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Sea snake

January 31, 2023

"Sea snakes" redirects here. For other snake groups adapted to marine and brackish environments, see List of marine snakes. For the rock band, see Sea Snakes.
For sea snakes in mythology and cryptozoology, see Sea serpent.

Sea snakes, or coral reef snakes, are elapid snakes that inhabit marine environments for most or all of their lives. They belong to two subfamilies, Hydrophiinae and Laticaudinae. Hydrophiinae also includes Australasian terrestrial snakes, whereas Laticaudinae only includes the sea kraits (Laticauda), of which three species are found exclusively in freshwater. If these three freshwater species are excluded, there are 69 species of sea snakes divided between seven genera.[2]

Sea snake
Temporal range: Oligocene – Recent[1]
Yellow-bellied sea snake (Hydrophis platurus) on a beach in Costa Rica
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Reptilia
Order: Squamata
Suborder: Serpentes
Family: Elapidae
Subfamily: Hydrophiinae
Range of sea snakes shown in lime green, except the widespread, pelagic yellow-bellied sea snake

Most sea snakes are venomous, except the genus Emydocephalus, which feeds almost exclusively on fish eggs.[3] Sea snakes are extensively adapted to a fully aquatic life and are unable to move on land, except for the sea kraits, which have limited land movement. They are found in warm coastal waters from the Indian Ocean to the Pacific and are closely related to venomous terrestrial snakes in Australia.[4]

All sea snakes have paddle-like tails and many have laterally compressed bodies that give them an eel-like appearance. Unlike fish, they do not have gills and must surface regularly to breathe. Along with whales, they are among the most completely aquatic of all extant air-breathing vertebrates.[5] Among this group are species with some of the most potent venoms of all snakes. Some have gentle dispositions and bite only when provoked, while others are much more aggressive.

Description

The majority of adult sea snakes species grow to between 120 and 150 cm (4 and 5 ft) in length,[6] with the largest, Hydrophis spiralis, reaching a maximum of 3 m (10 ft).[7] Their eyes are relatively small with a round pupil[8] and most have nostrils located dorsally.[9] The skulls do not differ significantly from those of terrestrial elapids, although their dentition is relatively primitive with short fangs and (with the exception of Emydocephalus) as many as 18 smaller teeth behind them on the maxilla.[5]

 
Yellow-lipped sea krait, Laticauda colubrina

Most sea snakes are completely aquatic and have adapted to sea environments in many ways, the most characteristic of which is a paddle-like tail that has improved their swimming ability.[10] To a varying degree, the bodies of many species are laterally compressed, especially in the pelagic species. This has often caused the ventral scales to become reduced in size, even difficult to distinguish from the adjoining scales. Their lack of ventral scales means they have become virtually helpless on land, but as they live out their entire lifecycles at sea, they have no need to leave the water.[6][9]

The only genus that has retained the enlarged ventral scales is the sea kraits, Laticauda, with only five species. These snakes are considered to be more primitive, as they still spend much of their time on land, where their ventral scales afford them the necessary grip.[6][9] Laticauda species are also the only sea snakes with internasal scales; that is, their nostrils are not located dorsally.[10]

Since a snake's tongue can fulfill its olfactory function more easily under water, its action is short compared to that of terrestrial snake species. Only the forked tips protrude from the mouth through a divided notch in the middle of the rostral scale.[5] The nostrils have valves consisting of a specialized spongy tissue to exclude water, and the windpipe can be drawn up to where the short nasal passage opens into the roof of the mouth. This is an important adaptation for an animal that must surface to breathe, but may have its head partially submerged when doing so. The lung has become very large and extends almost the entire length of the body, although the rear portion is thought to have developed to aid buoyancy rather than to exchange gases. The extended lung possibly also serves to store air for dives.[6][9]

Most species of sea snakes are able to respire through the top of their skin. This is unusual for reptiles, because their skin is thick and scaly, but experiments with the black-and-yellow sea snake, Hydrophis platurus (a pelagic species), have shown this species can satisfy about 25% of its oxygen requirements in this manner, which allows for prolonged dives.[11]

 
Blue-lipped sea krait, Laticauda laticaudata

Like other land animals that have adapted to life in a marine environment, sea snakes ingest considerably more salt than their terrestrial relatives through their diets, and when seawater is inadvertently swallowed. Because of this, a more effective means of regulating the salt concentration of their blood is required. In sea snakes, the posterior sublingual glands, located under and around the tongue sheath, allow them to expel salt with their tongue action.[5][9]

Scalation among sea snakes is highly variable. As opposed to terrestrial snake species that have imbricate scales to protect against abrasion, the scales of most pelagic sea snakes do not overlap. Reef-dwelling species, such as Aipysurus, do have imbricate scales to protect against the sharp coral. The scales themselves may be smooth, keeled, spiny, or granular, the latter often looking like warts. Pelamis has body scales that are "peg-like", while those on its tail are juxtaposed hexagonal plates.[9]

Sensory abilities

Vision, chemoreception (tongue-flicking), and hearing are important senses for terrestrial snakes, but these stimuli become distorted in water.[12][13] The poor visibility, chemical dilution, and limitation of ground-borne vibrations under water suggest that sea snakes and sea kraits may have unique sensory abilities to compensate for the relative lack of other sensory cues.[14]

Relatively little is known about sea snake vision. A study of photoreceptors in the retina of spine-bellied, Lapemis curtus, and horned, Acalyptophis peronii, sea snakes found three classes of opsins all from cone cells.[15] Despite the absence of rod cells in sea snake eyes, Simeos et al. found the rhodopsin (rh1), the opsin of the rods, still expressed[16] suggesting that in sea snakes some cones may be transmuted rods. Behavioural observations indicate that vision has a limited role for catching prey and mate selection, but sound vibrations and chemoreception may be important.[17][18] One study identified small sensory organs on the head of Lapemis curtus[19] similar to the mechanoreceptors in alligators and aquatic snake Acrochodus that are used to sense the movement of fish prey.[20] Westhoff et al. recorded auditory brain responses to vibration underwater in Lapemis curtus,[21] which are sensitive enough to detect movement in prey, but were not as sensitive as fish lateral line systems. Similarly, vision appears to be of limited importance for finding mates. Shine experimented with applying skin secretions (pheromones) to snake-like objects to see if male turtle-headed sea snakes, Emydocephalus annulatus, are attracted to female pheromones. Shine found that although vision may be useful over short distances (less than 1 m [3 ft]), pheromones are more important once the male comes in physical contact with an object.[22]

The olive sea snake, Aipysurus laevis, has been found to have photoreceptors in the skin of its tail, allowing it to detect light and presumably ensuring it is completely hidden, including its tail, inside coral holes during the day. While other species have not been tested, A. laevis possibly is not unique among sea snakes in this respect.[23]

Other unique senses, such as electromagnetic reception and pressure detection,[24] have been proposed for sea snakes, but scientific studies have yet to be performed to test these senses.[14]

Distribution and habitat

Sea snakes are mostly confined to the warm tropical waters of the Indian Ocean and the western Pacific Ocean,[6] with a few species found well out into Oceania.[25] The geographic range of one species, Pelamis platurus, is wider than that of any other reptile species, except for a few species of sea turtles.[5] It extends from the east coast of Africa, from Djibouti in the north to Cape Town in the south,[26] across the Indian Ocean, the Pacific, south as far as the northern coast of New Zealand,[25][27] all the way to the western coast of the Americas, where it occurs from northern Peru in the south (including the Galápagos Islands) to the Gulf of California in the north. Isolated specimens have been found as far north as San Diego and Oxnard in the United States.[28]

Sea snakes do not occur in the Atlantic Ocean.[9] Pelamis possibly would be found there were it not for the cold currents off Namibia and western South Africa that keep it from crossing into the eastern South Atlantic, or south of 5°S latitude along the South American west coast. Sea snakes do not occur in the Red Sea, believed to be due to its increased salinity, so no danger exists of them crossing through the Suez Canal. A lack of salinity is also thought to be the reason why Pelamis has not crossed into the Caribbean via the Panama Canal.[5]

Despite their marine adaptations, most sea snakes prefer shallow waters near land, around islands, and especially somewhat sheltered waters, as well as near estuaries.[6][10] They may swim up rivers and have been reported as far as 160 km (100 mi) from the sea.[10] Others, such as P. platurus, are pelagic and are found in drift lines, slicks of floating debris brought together by surface currents.[29] Some sea snakes inhabit mangrove swamps and similar brackishwater habitats, and two landlocked freshwater forms are found: Hydrophis semperi occurs in Lake Taal in the Philippines, and Laticauda crockeri in Lake Te Nggano on Rennell Island in the Solomon Islands.[9]

Behavior

Sea snakes are generally reluctant to bite,[6][7] and are usually considered to be mild-tempered, although variation is seen among species and individuals.[25] Some species, such as P. platurus, which feed by simply gulping down their prey, are more likely to bite when provoked because they seem to use their venom more for defense. Others, such as Laticauda spp., use their venom for prey immobilization. Sea snakes are often handled without concern by local fishermen who unravel and toss them back into the water barehanded, usually without getting bitten, when the snakes frequently become entangled in fishing nets.[6][9] Species reported as much more aggressive include Aipysurus laevis, Astrotia stokesii, Enhydrina schistosa, Enhydrina zweifeli, and Hydrophis ornatus.[10]

 
Olive sea snake, Aipysurus laevis

On land, their movements become very erratic. They crawl awkwardly in these situations and can become quite aggressive, striking wildly at anything that moves, although they are unable to coil and strike in the manner of terrestrial snakes.[7][8]

Sea snakes appear to be active both day and night. In the morning, and sometimes late in the afternoon, they can be seen at the surface basking in the sunlight, and they dive when disturbed.[6] They have been reported swimming at depths over 90 m (300 ft), and can remain submerged for as long as a few hours, possibly depending on temperature and degree of activity.[7][25]

Sea snakes have been sighted in huge numbers. For example, in 1932, a steamer in the Strait of Malacca, off the coast of Malaysia, reported sighting "millions" of Astrotia stokesii, a relative of Pelamis; these reportedly formed a line of snakes 3 m (10 ft) wide and 100 km (60 mi) long.[29] The cause of this phenomenon is unknown, although it likely has to do with reproduction.[5] They can sometimes be seen swimming in schools of several hundred, and many dead specimens have been found on beaches after typhoons.[8]

Ecology

They feed on small fish and occasionally young octopus. They are often associated with the sea snake barnacle (Platylepas ophiophila), which attaches to their skin.[30]

Reproduction

Except for a single genus, all sea snakes are ovoviviparous; the young are born alive in the water where they live their entire lives.[9] In some species, the young are quite large, up to half as long as the mother.[7] The one exception is the genus Laticauda, which is oviparous; its five species all lay their eggs on land.[9]

Venom

Like their relatives in the family Elapidae, the majority of the sea snakes are highly venomous, but rarely inject it when biting, so such damage to humans seems nonexistent or trivial.[10] For example, Hydrophis platurus has a venom more potent than any terrestrial snake species in Costa Rica based on LD50, but despite its abundance in the waters off its western coast, few human fatalities have been reported.[11] The death of a trawler fisherman in Australian waters during 2018 was reported to be the region's first sea snake fatality since a pearl diver was killed in 1935.[31]

Bites in which envenomation does occur are usually painless and may not even be noticed when contact is made. Teeth may remain in the wound. Usually, little or no swelling occurs, and rarely are any nearby lymph nodes affected. The most important symptoms are rhabdomyolysis (rapid breakdown of skeletal muscle tissue) and paralysis. Early symptoms include headache, a thick-feeling tongue, thirst, sweating, and vomiting. The venom is very slow acting and symptoms that happen from little as 30 minutes to several hours after the bite include generalized aching, stiffness, and tenderness of muscles all over the body. Passive stretching of the muscles is also painful, and trismus, which is similar to tetanus, is common. This is followed later on by symptoms typical of other elapid envenomations, a progressive flaccid paralysis, starting with ptosis and paralysis of voluntary muscles. Paralysis of muscles involved in swallowing and respiration can be fatal.[32]

Vick et al (1975) estimated that the LD50 of three sea snake venoms (H. platurus, L. semifasciata and L. laticaudata) for a 70 kg human range from 7.7 to 21 mg. Data from the only sea snake venom conducted in monkeys at that time suggested that primates were slightly more resistant to the venom effects on a dose response basis than mice. In this regard, recall the recent report by Ishikawa et al (1985) indicating a substantially lower binding affinity between sea snake neurotoxin and human and chimpanzee AChR's compared to that in other animals. In humans, the venom targets appear mainly to be the cell walls of voluntary (skeletal) muscles and distal tubular portions of the kidney including the loop of Henle, the second convoluted tubule and the collecting tubules. Sitprija et al (1973) found evidence of tubular necrosis throughout all portions of the renal tubules in two patients severely envenomated by sea snakes. Sea snake venoms in humans are thus more often myotoxic and/or nephrotoxic rather than neurotoxic.[33]

Taxonomy

Cladogram
Elapidae

Cobra

Hydrophiinae
sea kraits

Laticauda

Notechis

other sea snakes

Emydocephalus

Aipysurus

Hydrelaps

Hydrophis

Cladogram showing the basic evolutionary relationships among sea snakes, sea kraits and other venomous terrestrial snakes. Sea kraits diverged earlier from the rest of Australasian elapids, in contrast other sea snakes are more closely related to Australasian elapids then they are to sea kraits.

Sea snakes were at first regarded as a unified and separate family, the Hydrophiidae, that later came to comprise two subfamilies: the Hydrophiinae, or true/aquatic sea snakes (now 6 genera with 64 species), and the more primitive Laticaudinae, or sea kraits (one genus, Laticauda, with eight species). Eventually, as just how closely related the sea snakes are to the elapids became clear, the taxonomic situation became less well-defined. Some taxonomists responded by moving the sea snakes to the Elapidae. Most taxonomists now place the sea snakes in the elapid subfamilies Hydrophiinae and Laticaudinae, although the latter may be omitted if Laticauda is included in the Hydrophiinae. Unlike the traditional Hydrophiinae, the Hydrophiinae as currently seen also includes Australasian terrestrial elapids.[34][2][8][9][4]

Genus[2] Taxon authority[34] Species[2] Subsp.[34][a] Common name[35] Geographic range[35]
Aipysurus Lacépède, 1804 9 1 olive sea snakes Timor Sea, South China Sea, Gulf of Thailand, and coasts of Australia (Northern Territory, Queensland, Western Australia), New Caledonia, Loyalty Islands, southern New Guinea, Indonesia, western Malaysia and Vietnam
Emydocephalus Krefft, 1869 3 0 turtlehead sea snakes the coasts of Timor (Indonesian Sea), New Caledonia, Australia (Northern Territory, Queensland, Western Australia), and in the Southeast Asian sea along the coasts of China, Taiwan, Japan, and the Ryukyu Islands
Ephalophis M.A. Smith, 1931 1 0 Grey's mudsnake northwestern Australia
Hydrelaps Boulenger, 1896 1 0 Port Darwin mudsnake northern Australia, southern New Guinea
Hydrophis Latreille in Sonnini & Latreille, 1801 49 3 sea snakes Indo-Australian and Southeast Asian waters.[36]
Laticauda Laurenti, 1768 8 0 sea kraits Southeast Asian and Indo-Australian waters
Parahydrophis Burger & Natsuno, 1974 1 0 northern mangrove sea snake northern Australia, southern New Guinea
  1. ^ Not counting the nominate subspecies

Molecular studies

Molecular data studies suggest all three monotypic semiaquatic genera (Ephalophis, Parahydrophis and Hydrelaps) are early diverging lineages.[37]

Captivity

At best, sea snakes make difficult captives. Ditmars (1933) described them as nervous and delicate captives that usually refuse to eat, preferring only to hide in the darkest corner of the tank.[8] Over 50 years later, Mehrtens wrote in 1987 that although they were rarely displayed in Western zoological parks, some species were regularly on display in Japanese aquariums. The available food supply limits the number of species that can be kept in captivity, since some have diets that are too specialized. Also, some species appear intolerant of handling, or even being removed from the water. Regarding their requirements in captivity, the Laticauda species need to be able to exit the water somewhere at about 29 °C (84 °F), along with a submerged shelter. Species that have done relatively well in captivity include the ringed sea snake, Hydrophis cyanocinctus, which feeds on fish and eels in particular. Pelamis platurus has done especially well in captivity, accepting small fish, including goldfish. Housing them in round tanks, or in rectangular tanks with well-rounded corners, prevents snakes from damaging their snouts on the sides.[9]

Conservation status

Most sea snakes are not on the CITES protection lists.[10][38] One species, Laticauda crockeri, is classified as vulnerable. Several species of Aipysurus are listed with conservation status of greater concern, the Timor species A. fuscus is known to be endangered, and two others found in seas north of Australia, the leaf-scaled A. foliosquama and short-nosed A. apraefrontalis, are classified as critically endangered according to the IUCN Red List of Threatened Species.[39]

See also

References

  1. ^ Dudgeon, Christine L.; White, William T. (2012). "First record of potential Batesian mimicry in an elasmobranch: juvenile zebra sharks mimic banded sea snakes?". Marine and Freshwater Research. 63 (6): 545. doi:10.1071/MF11211. ISSN 1323-1650.
  2. ^ a b c d Uetz, P.; Freed, P.; Aguilar, R.; Hošek, J., eds. (2022). "Elapidae". The Reptile Database. Retrieved 2022-05-09.
  3. ^ Minton, S. A. (1983). "Lethal toxicity of venoms of snakes from the Coral Sea". Toxicon. 21 (6): 901–902. doi:10.1016/0041-0101(83)90082-x. PMID 6658813.
  4. ^ a b Hutchings, Pat (2008). The Great Barrier Reef: Biology, Environment and Management. Csiro Publishing. p. 345. ISBN 9780643099975. Sea snakes are true reptiles closely related to Australian venomous terrestrial snakes. Indeed, both groups are included in a single subfamily, Hydrophiinae, by most modern herpetologists.
  5. ^ a b c d e f g Parker HW, Grandison AGC. 1977. Snakes – a natural history. Second Edition. British Museum (Natural History) and Cornell University Press. 108 pp. 16 plates. LCCCN 76-54625. ISBN 0-8014-1095-9 (cloth), ISBN 0-8014-9164-9 (paper).
  6. ^ a b c d e f g h i Stidworthy J. 1974. Snakes of the World. Grosset & Dunlap Inc. 160 pp. ISBN 0-448-11856-4.
  7. ^ a b c d e Fichter GS. 1982. Poisonous Snakes. A First Book. Franklin Watts. 66 pp. ISBN 0-531-04349-5.
  8. ^ a b c d e Ditmars RL. 1933. Reptiles of the World. Revised Edition. The MacMillan Company. 329 pp. 89 plates.
  9. ^ a b c d e f g h i j k l m Mehrtens JM. 1987. Living Snakes of the World in Color. New York: Sterling Publishers. 480 pp. ISBN 0-8069-6460-X.
  10. ^ a b c d e f g Rasmussen, A.R. (2001). "Sea snakes" (PDF). In Kent E. Carpenter; Volker H. Niem (eds.). The living marine resources of the Western Central Pacific. FAO species identification guide for fishery purposes. Rome: Food and Agriculture Organization of the United Nations. pp. 3987–4008. Retrieved 7 August 2007.
  11. ^ a b Campbell JA, Lamar WW. 2004. The Venomous Reptiles of the Western Hemisphere. Comstock Publishing Associates, Ithaca and London. 870 pp. 1500 plates. ISBN 0-8014-4141-2.
  12. ^ Shine, R.; Phillips, B.; Waye, H.; LeMaster, M.; Mason, R. T. (2003-05-14). "Chemosensory cues allow courting male garter snakes to assess body length and body condition of potential mates". Behavioral Ecology and Sociobiology. 54 (2): 162–166. doi:10.1007/s00265-003-0620-5. ISSN 0340-5443. S2CID 22852516.
  13. ^ Young, Bruce A. (2003-09-01). "Snake bioacoustics: toward a richer understanding of the behavioral ecology of snakes". The Quarterly Review of Biology. 78 (3): 303–325. doi:10.1086/377052. ISSN 0033-5770. PMID 14528622. S2CID 22195556.
  14. ^ a b Sensory Evolution on the Threshold: Adaptations in Secondarily Aquatic Vertebrates (1 ed.). University of California Press. 2008-02-04. ISBN 9780520252783.
  15. ^ Hart, Nathan S.; Coimbra, João Paulo; Collin, Shaun P.; Westhoff, Guido (2012-04-15). "Photoreceptor types, visual pigments, and topographic specializations in the retinas of hydrophiid sea snakes". The Journal of Comparative Neurology. 520 (6): 1246–1261. doi:10.1002/cne.22784. ISSN 1096-9861. PMID 22020556. S2CID 8011090.
  16. ^ Simões, Bruno F.; Sampaio, Filipa L.; Loew, Ellis R.; Sanders, Kate L.; Fisher, Robert N.; Hart, Nathan S.; Hunt, David M.; Partridge, Julian C.; Gower, David J. (2016-01-27). "Multiple rod–cone and cone–rod photoreceptor transmutations in snakes: evidence from visual opsin gene expression". Proc. R. Soc. B. 283 (1823): 20152624. doi:10.1098/rspb.2015.2624. ISSN 0962-8452. PMC 4795032. PMID 26817768.
  17. ^ Heatwole, H; Cogger, H (1993). Fauna of Australia (PDF). Canberra, Australia: AGPS. p. 16.
  18. ^ Heatwole, Harold (1999-01-01). Sea Snakes. UNSW Press. ISBN 9780868407760.
  19. ^ Van Der Kooij, Jeroen; Povel, David (1996). "Scale Sensillae of the File Snake (Serpentes: Acrochordidae) and Some Other Aquatic and Burrowing Snakes". Netherlands Journal of Zoology. 47 (4): 443–456. doi:10.1163/156854297X00111. Retrieved 2016-04-02.
  20. ^ Soares, Daphne (2002-05-16). "Neurology: An ancient sensory organ in crocodilians". Nature. 417 (6886): 241–242. Bibcode:2002Natur.417..241S. doi:10.1038/417241a. ISSN 0028-0836. PMID 12015589. S2CID 1922782.
  21. ^ Westhoff, Guido; Fry, Bryan G.; Bleckmann, Horst (2005-01-01). "Sea snakes (Lapemis curtus) are sensitive to low-amplitude water motions". Zoology. 108 (3): 195–200. doi:10.1016/j.zool.2005.07.001. ISSN 0944-2006. PMID 16351967.
  22. ^ Shine, R. (2005-01-13). "All at sea: aquatic life modifies mate-recognition modalities in sea snakes (Emydocephalus annulatus, Hydrophiidae)". Behavioral Ecology and Sociobiology. 57 (6): 591–598. doi:10.1007/s00265-004-0897-z. ISSN 0340-5443. S2CID 34698605.
  23. ^ Zimmerman, K; Heatwole, H (1990). "Cutaneous Photoreception: A New Sensory Mechanism for Reptiles". Copeia. 1990 (3): 860–862. doi:10.2307/1446454. JSTOR 1446454.
  24. ^ Liu, Y.-L.; Lillywhite, H. B.; Tu, M.-C. (2010-07-03). "Sea snakes anticipate tropical cyclone". Marine Biology. 157 (11): 2369–2373. doi:10.1007/s00227-010-1501-x. ISSN 0025-3162. S2CID 85297798.
  25. ^ a b c d U.S. Navy. 1991. Poisonous Snakes of the World. US Govt. New York: Dover Publications Inc. 203 pp. ISBN 0-486-26629-X.
  26. ^ Spawls S, Branch B. 1995. The Dangerous Snakes of Africa. Ralph Curtis Books. Dubai: Oriental Press. 192 pp. ISBN 0-88359-029-8.
  27. ^ Slaughter RJ, Beasley DM, Lambie BS, Schep LJ (2009). "New Zealand's venomous creatures". New Zealand Medical Journal. 122 (1290): 83–97. PMID 19319171.
  28. ^ "Venomous Yellow-Bellied Sea Snake Washes Up on Coronado Beach".
  29. ^ a b The sea snakes are coming at NewScientist. Accessed 13 January 2009.
  30. ^ Vernberg, F. John (2014). Behavior and Ecology. Elsevier Science. p. 186. ISBN 978-0-323-16269-2.
  31. ^ Smith, Emily (8 October 2018). "Fisherman's deadly encounter with sea snake incredibly rare". ABC News.
  32. ^ Warrell DA. 2004. Snakebites in Central and South America: Epidemiology, Clinical Features, and Clinical Management. In Campbell JA, Lamar WW. 2004. The Venomous Reptiles of the Western Hemisphere. Comstock Publishing Associates, Ithaca and London. 870 pp. 1500 plates. ISBN 0-8014-4141-2.
  33. ^ Gopalakrishnakone, P. (1994). Sea Snake Toxinology. NUS Press. ISBN 978-9971-69-193-6.
  34. ^ a b c "Elapidae". Integrated Taxonomic Information System. Retrieved 7 August 2007.
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  37. ^ Sanders, KL; Lee, MS; Mumpuni, Bertozzi T; Rasmussen, AR (2012). "Multilocus phylogeny and recent rapid radiation of the viviparous sea snakes (Elapidae: Hydrophiinae)". Molecular Phylogenetics and Evolution. 66 (3): 575–591. doi:10.1016/j.ympev.2012.09.021. PMID 23026811.
  38. ^ Serpentes at CITES. Accessed 11 August 2007.
  39. ^ www.iucnredlist.org http://www.iucnredlist.org/apps/redlist/search. Retrieved 14 May 2011. {{cite web}}: Missing or empty |title= (help)

Further reading

  • Graham JB, Lowell WR, Rubinoff I, Motta J. 1987. Surface and subsurface swimming of the sea snake Pelamis platurus. J. exp. Biol. 127, 27-44. PDF at the [Journal of Experimental Biology]. Accessed 7 August 2007.
  • Rasmussen AR. 1997. Systematics of sea snakes; a critical review. Symp. Zool. Soc. London 70, 15-30.
  • Smith MA. 1926. Monograph of the sea snakes (Hydrophiidae). British Museum of Natural History, London.
  • Voris HK. 1977. A phylogeny of the sea snakes (Hydrophiidae). Fieldiana Zool. 70, 79-169.
  • Whitaker R. 1978. Common Indian Snakes: A Field Guide. Macmillan India Limited.

External links

  • Sea Snakes in Australia
  • Sea Snakes at Scubadoc's Diving Medicine Online. Accessed 6 August 2007.
  • Diving Gunung Api: Volcano Of The Sea Snakes - first hand account of scuba divers interacting with sea snakes at the Indonesian volcano Gunung Api, June 2009

January 31, 2023
snake, redirects, here, other, snake, groups, adapted, marine, brackish, environments, list, marine, snakes, rock, band, snakes, snakes, mythology, cryptozoology, serpent, coral, reef, snakes, elapid, snakes, that, inhabit, marine, environments, most, their, l. Sea snakes redirects here For other snake groups adapted to marine and brackish environments see List of marine snakes For the rock band see Sea Snakes For sea snakes in mythology and cryptozoology see Sea serpent Sea snakes or coral reef snakes are elapid snakes that inhabit marine environments for most or all of their lives They belong to two subfamilies Hydrophiinae and Laticaudinae Hydrophiinae also includes Australasian terrestrial snakes whereas Laticaudinae only includes the sea kraits Laticauda of which three species are found exclusively in freshwater If these three freshwater species are excluded there are 69 species of sea snakes divided between seven genera 2 Sea snakeTemporal range Oligocene Recent 1 PreꞒ Ꞓ O S D C P T J K Pg NYellow bellied sea snake Hydrophis platurus on a beach in Costa RicaScientific classificationKingdom AnimaliaPhylum ChordataClass ReptiliaOrder SquamataSuborder SerpentesFamily ElapidaeSubfamily HydrophiinaeRange of sea snakes shown in lime green except the widespread pelagic yellow bellied sea snakeMost sea snakes are venomous except the genus Emydocephalus which feeds almost exclusively on fish eggs 3 Sea snakes are extensively adapted to a fully aquatic life and are unable to move on land except for the sea kraits which have limited land movement They are found in warm coastal waters from the Indian Ocean to the Pacific and are closely related to venomous terrestrial snakes in Australia 4 All sea snakes have paddle like tails and many have laterally compressed bodies that give them an eel like appearance Unlike fish they do not have gills and must surface regularly to breathe Along with whales they are among the most completely aquatic of all extant air breathing vertebrates 5 Among this group are species with some of the most potent venoms of all snakes Some have gentle dispositions and bite only when provoked while others are much more aggressive Contents 1 Description 2 Sensory abilities 3 Distribution and habitat 4 Behavior 5 Ecology 6 Reproduction 7 Venom 8 Taxonomy 8 1 Molecular studies 9 Captivity 10 Conservation status 11 See also 12 References 13 Further reading 14 External linksDescription EditThe majority of adult sea snakes species grow to between 120 and 150 cm 4 and 5 ft in length 6 with the largest Hydrophis spiralis reaching a maximum of 3 m 10 ft 7 Their eyes are relatively small with a round pupil 8 and most have nostrils located dorsally 9 The skulls do not differ significantly from those of terrestrial elapids although their dentition is relatively primitive with short fangs and with the exception of Emydocephalus as many as 18 smaller teeth behind them on the maxilla 5 Yellow lipped sea krait Laticauda colubrina Most sea snakes are completely aquatic and have adapted to sea environments in many ways the most characteristic of which is a paddle like tail that has improved their swimming ability 10 To a varying degree the bodies of many species are laterally compressed especially in the pelagic species This has often caused the ventral scales to become reduced in size even difficult to distinguish from the adjoining scales Their lack of ventral scales means they have become virtually helpless on land but as they live out their entire lifecycles at sea they have no need to leave the water 6 9 The only genus that has retained the enlarged ventral scales is the sea kraits Laticauda with only five species These snakes are considered to be more primitive as they still spend much of their time on land where their ventral scales afford them the necessary grip 6 9 Laticauda species are also the only sea snakes with internasal scales that is their nostrils are not located dorsally 10 Since a snake s tongue can fulfill its olfactory function more easily under water its action is short compared to that of terrestrial snake species Only the forked tips protrude from the mouth through a divided notch in the middle of the rostral scale 5 The nostrils have valves consisting of a specialized spongy tissue to exclude water and the windpipe can be drawn up to where the short nasal passage opens into the roof of the mouth This is an important adaptation for an animal that must surface to breathe but may have its head partially submerged when doing so The lung has become very large and extends almost the entire length of the body although the rear portion is thought to have developed to aid buoyancy rather than to exchange gases The extended lung possibly also serves to store air for dives 6 9 Most species of sea snakes are able to respire through the top of their skin This is unusual for reptiles because their skin is thick and scaly but experiments with the black and yellow sea snake Hydrophis platurus a pelagic species have shown this species can satisfy about 25 of its oxygen requirements in this manner which allows for prolonged dives 11 Blue lipped sea krait Laticauda laticaudata Like other land animals that have adapted to life in a marine environment sea snakes ingest considerably more salt than their terrestrial relatives through their diets and when seawater is inadvertently swallowed Because of this a more effective means of regulating the salt concentration of their blood is required In sea snakes the posterior sublingual glands located under and around the tongue sheath allow them to expel salt with their tongue action 5 9 Scalation among sea snakes is highly variable As opposed to terrestrial snake species that have imbricate scales to protect against abrasion the scales of most pelagic sea snakes do not overlap Reef dwelling species such as Aipysurus do have imbricate scales to protect against the sharp coral The scales themselves may be smooth keeled spiny or granular the latter often looking like warts Pelamis has body scales that are peg like while those on its tail are juxtaposed hexagonal plates 9 Sensory abilities EditVision chemoreception tongue flicking and hearing are important senses for terrestrial snakes but these stimuli become distorted in water 12 13 The poor visibility chemical dilution and limitation of ground borne vibrations under water suggest that sea snakes and sea kraits may have unique sensory abilities to compensate for the relative lack of other sensory cues 14 Relatively little is known about sea snake vision A study of photoreceptors in the retina of spine bellied Lapemis curtus and horned Acalyptophis peronii sea snakes found three classes of opsins all from cone cells 15 Despite the absence of rod cells in sea snake eyes Simeos et al found the rhodopsin rh1 the opsin of the rods still expressed 16 suggesting that in sea snakes some cones may be transmuted rods Behavioural observations indicate that vision has a limited role for catching prey and mate selection but sound vibrations and chemoreception may be important 17 18 One study identified small sensory organs on the head of Lapemis curtus 19 similar to the mechanoreceptors in alligators and aquatic snake Acrochodus that are used to sense the movement of fish prey 20 Westhoff et al recorded auditory brain responses to vibration underwater in Lapemis curtus 21 which are sensitive enough to detect movement in prey but were not as sensitive as fish lateral line systems Similarly vision appears to be of limited importance for finding mates Shine experimented with applying skin secretions pheromones to snake like objects to see if male turtle headed sea snakes Emydocephalus annulatus are attracted to female pheromones Shine found that although vision may be useful over short distances less than 1 m 3 ft pheromones are more important once the male comes in physical contact with an object 22 The olive sea snake Aipysurus laevis has been found to have photoreceptors in the skin of its tail allowing it to detect light and presumably ensuring it is completely hidden including its tail inside coral holes during the day While other species have not been tested A laevis possibly is not unique among sea snakes in this respect 23 Other unique senses such as electromagnetic reception and pressure detection 24 have been proposed for sea snakes but scientific studies have yet to be performed to test these senses 14 Distribution and habitat EditSea snakes are mostly confined to the warm tropical waters of the Indian Ocean and the western Pacific Ocean 6 with a few species found well out into Oceania 25 The geographic range of one species Pelamis platurus is wider than that of any other reptile species except for a few species of sea turtles 5 It extends from the east coast of Africa from Djibouti in the north to Cape Town in the south 26 across the Indian Ocean the Pacific south as far as the northern coast of New Zealand 25 27 all the way to the western coast of the Americas where it occurs from northern Peru in the south including the Galapagos Islands to the Gulf of California in the north Isolated specimens have been found as far north as San Diego and Oxnard in the United States 28 Sea snakes do not occur in the Atlantic Ocean 9 Pelamis possibly would be found there were it not for the cold currents off Namibia and western South Africa that keep it from crossing into the eastern South Atlantic or south of 5 S latitude along the South American west coast Sea snakes do not occur in the Red Sea believed to be due to its increased salinity so no danger exists of them crossing through the Suez Canal A lack of salinity is also thought to be the reason why Pelamis has not crossed into the Caribbean via the Panama Canal 5 Despite their marine adaptations most sea snakes prefer shallow waters near land around islands and especially somewhat sheltered waters as well as near estuaries 6 10 They may swim up rivers and have been reported as far as 160 km 100 mi from the sea 10 Others such as P platurus are pelagic and are found in drift lines slicks of floating debris brought together by surface currents 29 Some sea snakes inhabit mangrove swamps and similar brackishwater habitats and two landlocked freshwater forms are found Hydrophis semperi occurs in Lake Taal in the Philippines and Laticauda crockeri in Lake Te Nggano on Rennell Island in the Solomon Islands 9 Behavior EditSea snakes are generally reluctant to bite 6 7 and are usually considered to be mild tempered although variation is seen among species and individuals 25 Some species such as P platurus which feed by simply gulping down their prey are more likely to bite when provoked because they seem to use their venom more for defense Others such as Laticauda spp use their venom for prey immobilization Sea snakes are often handled without concern by local fishermen who unravel and toss them back into the water barehanded usually without getting bitten when the snakes frequently become entangled in fishing nets 6 9 Species reported as much more aggressive include Aipysurus laevis Astrotia stokesii Enhydrina schistosa Enhydrina zweifeli and Hydrophis ornatus 10 Olive sea snake Aipysurus laevis On land their movements become very erratic They crawl awkwardly in these situations and can become quite aggressive striking wildly at anything that moves although they are unable to coil and strike in the manner of terrestrial snakes 7 8 Sea snakes appear to be active both day and night In the morning and sometimes late in the afternoon they can be seen at the surface basking in the sunlight and they dive when disturbed 6 They have been reported swimming at depths over 90 m 300 ft and can remain submerged for as long as a few hours possibly depending on temperature and degree of activity 7 25 Sea snakes have been sighted in huge numbers For example in 1932 a steamer in the Strait of Malacca off the coast of Malaysia reported sighting millions of Astrotia stokesii a relative of Pelamis these reportedly formed a line of snakes 3 m 10 ft wide and 100 km 60 mi long 29 The cause of this phenomenon is unknown although it likely has to do with reproduction 5 They can sometimes be seen swimming in schools of several hundred and many dead specimens have been found on beaches after typhoons 8 Ecology EditThey feed on small fish and occasionally young octopus They are often associated with the sea snake barnacle Platylepas ophiophila which attaches to their skin 30 Reproduction EditExcept for a single genus all sea snakes are ovoviviparous the young are born alive in the water where they live their entire lives 9 In some species the young are quite large up to half as long as the mother 7 The one exception is the genus Laticauda which is oviparous its five species all lay their eggs on land 9 Venom EditLike their relatives in the family Elapidae the majority of the sea snakes are highly venomous but rarely inject it when biting so such damage to humans seems nonexistent or trivial 10 For example Hydrophis platurus has a venom more potent than any terrestrial snake species in Costa Rica based on LD50 but despite its abundance in the waters off its western coast few human fatalities have been reported 11 The death of a trawler fisherman in Australian waters during 2018 was reported to be the region s first sea snake fatality since a pearl diver was killed in 1935 31 Bites in which envenomation does occur are usually painless and may not even be noticed when contact is made Teeth may remain in the wound Usually little or no swelling occurs and rarely are any nearby lymph nodes affected The most important symptoms are rhabdomyolysis rapid breakdown of skeletal muscle tissue and paralysis Early symptoms include headache a thick feeling tongue thirst sweating and vomiting The venom is very slow acting and symptoms that happen from little as 30 minutes to several hours after the bite include generalized aching stiffness and tenderness of muscles all over the body Passive stretching of the muscles is also painful and trismus which is similar to tetanus is common This is followed later on by symptoms typical of other elapid envenomations a progressive flaccid paralysis starting with ptosis and paralysis of voluntary muscles Paralysis of muscles involved in swallowing and respiration can be fatal 32 Vick et al 1975 estimated that the LD50 of three sea snake venoms H platurus L semifasciata and L laticaudata for a 70 kg human range from 7 7 to 21 mg Data from the only sea snake venom conducted in monkeys at that time suggested that primates were slightly more resistant to the venom effects on a dose response basis than mice In this regard recall the recent report by Ishikawa et al 1985 indicating a substantially lower binding affinity between sea snake neurotoxin and human and chimpanzee AChR s compared to that in other animals In humans the venom targets appear mainly to be the cell walls of voluntary skeletal muscles and distal tubular portions of the kidney including the loop of Henle the second convoluted tubule and the collecting tubules Sitprija et al 1973 found evidence of tubular necrosis throughout all portions of the renal tubules in two patients severely envenomated by sea snakes Sea snake venoms in humans are thus more often myotoxic and or nephrotoxic rather than neurotoxic 33 Taxonomy EditCladogramElapidae CobraHydrophiinae sea kraits LaticaudaNotechisother sea snakes EmydocephalusAipysurusHydrelapsHydrophisCladogram showing the basic evolutionary relationships among sea snakes sea kraits and other venomous terrestrial snakes Sea kraits diverged earlier from the rest of Australasian elapids in contrast other sea snakes are more closely related to Australasian elapids then they are to sea kraits Sea snakes were at first regarded as a unified and separate family the Hydrophiidae that later came to comprise two subfamilies the Hydrophiinae or true aquatic sea snakes now 6 genera with 64 species and the more primitive Laticaudinae or sea kraits one genus Laticauda with eight species Eventually as just how closely related the sea snakes are to the elapids became clear the taxonomic situation became less well defined Some taxonomists responded by moving the sea snakes to the Elapidae Most taxonomists now place the sea snakes in the elapid subfamilies Hydrophiinae and Laticaudinae although the latter may be omitted if Laticauda is included in the Hydrophiinae Unlike the traditional Hydrophiinae the Hydrophiinae as currently seen also includes Australasian terrestrial elapids 34 2 8 9 4 Genus 2 Taxon authority 34 Species 2 Subsp 34 a Common name 35 Geographic range 35 Aipysurus Lacepede 1804 9 1 olive sea snakes Timor Sea South China Sea Gulf of Thailand and coasts of Australia Northern Territory Queensland Western Australia New Caledonia Loyalty Islands southern New Guinea Indonesia western Malaysia and VietnamEmydocephalus Krefft 1869 3 0 turtlehead sea snakes the coasts of Timor Indonesian Sea New Caledonia Australia Northern Territory Queensland Western Australia and in the Southeast Asian sea along the coasts of China Taiwan Japan and the Ryukyu IslandsEphalophis M A Smith 1931 1 0 Grey s mudsnake northwestern AustraliaHydrelaps Boulenger 1896 1 0 Port Darwin mudsnake northern Australia southern New GuineaHydrophis Latreille in Sonnini amp Latreille 1801 49 3 sea snakes Indo Australian and Southeast Asian waters 36 Laticauda Laurenti 1768 8 0 sea kraits Southeast Asian and Indo Australian watersParahydrophis Burger amp Natsuno 1974 1 0 northern mangrove sea snake northern Australia southern New Guinea Not counting the nominate subspecies Molecular studies Edit Molecular data studies suggest all three monotypic semiaquatic genera Ephalophis Parahydrophis and Hydrelaps are early diverging lineages 37 Captivity Edit Hydrophis cyanocinctus At best sea snakes make difficult captives Ditmars 1933 described them as nervous and delicate captives that usually refuse to eat preferring only to hide in the darkest corner of the tank 8 Over 50 years later Mehrtens wrote in 1987 that although they were rarely displayed in Western zoological parks some species were regularly on display in Japanese aquariums The available food supply limits the number of species that can be kept in captivity since some have diets that are too specialized Also some species appear intolerant of handling or even being removed from the water Regarding their requirements in captivity the Laticauda species need to be able to exit the water somewhere at about 29 C 84 F along with a submerged shelter Species that have done relatively well in captivity include the ringed sea snake Hydrophis cyanocinctus which feeds on fish and eels in particular Pelamis platurus has done especially well in captivity accepting small fish including goldfish Housing them in round tanks or in rectangular tanks with well rounded corners prevents snakes from damaging their snouts on the sides 9 Conservation status EditMost sea snakes are not on the CITES protection lists 10 38 One species Laticauda crockeri is classified as vulnerable Several species of Aipysurus are listed with conservation status of greater concern the Timor species A fuscus is known to be endangered and two others found in seas north of Australia the leaf scaled A foliosquama and short nosed A apraefrontalis are classified as critically endangered according to the IUCN Red List of Threatened Species 39 See also EditList of marine reptiles Snakebite Sea serpentReferences Edit Dudgeon Christine L White William T 2012 First record of potential Batesian mimicry in an elasmobranch juvenile zebra sharks mimic banded sea snakes Marine and Freshwater Research 63 6 545 doi 10 1071 MF11211 ISSN 1323 1650 a b c d Uetz P Freed P Aguilar R Hosek J eds 2022 Elapidae The Reptile Database Retrieved 2022 05 09 Minton S A 1983 Lethal toxicity of venoms of snakes from the Coral Sea Toxicon 21 6 901 902 doi 10 1016 0041 0101 83 90082 x PMID 6658813 a b Hutchings Pat 2008 The Great Barrier Reef Biology Environment and Management Csiro Publishing p 345 ISBN 9780643099975 Sea snakes are true reptiles closely related to Australian venomous terrestrial snakes Indeed both groups are included in a single subfamily Hydrophiinae by most modern herpetologists a b c d e f g Parker HW Grandison AGC 1977 Snakes a natural history Second Edition British Museum Natural History and Cornell University Press 108 pp 16 plates LCCCN 76 54625 ISBN 0 8014 1095 9 cloth ISBN 0 8014 9164 9 paper a b c d e f g h i Stidworthy J 1974 Snakes of the World Grosset amp Dunlap Inc 160 pp ISBN 0 448 11856 4 a b c d e Fichter GS 1982 Poisonous Snakes A First Book Franklin Watts 66 pp ISBN 0 531 04349 5 a b c d e Ditmars RL 1933 Reptiles of the World Revised Edition The MacMillan Company 329 pp 89 plates a b c d e f g h i j k l m Mehrtens JM 1987 Living Snakes of the World in Color New York Sterling Publishers 480 pp ISBN 0 8069 6460 X a b c d e f g Rasmussen A R 2001 Sea snakes PDF In Kent E Carpenter Volker H Niem eds The living marine resources of the Western Central Pacific FAO species identification guide for fishery purposes Rome Food and Agriculture Organization of the United Nations pp 3987 4008 Retrieved 7 August 2007 a b Campbell JA Lamar WW 2004 The Venomous Reptiles of the Western Hemisphere Comstock Publishing Associates Ithaca and London 870 pp 1500 plates ISBN 0 8014 4141 2 Shine R Phillips B Waye H LeMaster M Mason R T 2003 05 14 Chemosensory cues allow courting male garter snakes to assess body length and body condition of potential mates Behavioral Ecology and Sociobiology 54 2 162 166 doi 10 1007 s00265 003 0620 5 ISSN 0340 5443 S2CID 22852516 Young Bruce A 2003 09 01 Snake bioacoustics toward a richer understanding of the behavioral ecology of snakes The Quarterly Review of Biology 78 3 303 325 doi 10 1086 377052 ISSN 0033 5770 PMID 14528622 S2CID 22195556 a b Sensory Evolution on the Threshold Adaptations in Secondarily Aquatic Vertebrates 1 ed University of California Press 2008 02 04 ISBN 9780520252783 Hart Nathan S Coimbra Joao Paulo Collin Shaun P Westhoff Guido 2012 04 15 Photoreceptor types visual pigments and topographic specializations in the retinas of hydrophiid sea snakes The Journal of Comparative Neurology 520 6 1246 1261 doi 10 1002 cne 22784 ISSN 1096 9861 PMID 22020556 S2CID 8011090 Simoes Bruno F Sampaio Filipa L Loew Ellis R Sanders Kate L Fisher Robert N Hart Nathan S Hunt David M Partridge Julian C Gower David J 2016 01 27 Multiple rod cone and cone rod photoreceptor transmutations in snakes evidence from visual opsin gene expression Proc R Soc B 283 1823 20152624 doi 10 1098 rspb 2015 2624 ISSN 0962 8452 PMC 4795032 PMID 26817768 Heatwole H Cogger H 1993 Fauna of Australia PDF Canberra Australia AGPS p 16 Heatwole Harold 1999 01 01 Sea Snakes UNSW Press ISBN 9780868407760 Van Der Kooij Jeroen Povel David 1996 Scale Sensillae of the File Snake Serpentes Acrochordidae and Some Other Aquatic and Burrowing Snakes Netherlands Journal of Zoology 47 4 443 456 doi 10 1163 156854297X00111 Retrieved 2016 04 02 Soares Daphne 2002 05 16 Neurology An ancient sensory organ in crocodilians Nature 417 6886 241 242 Bibcode 2002Natur 417 241S doi 10 1038 417241a ISSN 0028 0836 PMID 12015589 S2CID 1922782 Westhoff Guido Fry Bryan G Bleckmann Horst 2005 01 01 Sea snakes Lapemis curtus are sensitive to low amplitude water motions Zoology 108 3 195 200 doi 10 1016 j zool 2005 07 001 ISSN 0944 2006 PMID 16351967 Shine R 2005 01 13 All at sea aquatic life modifies mate recognition modalities in sea snakes Emydocephalus annulatus Hydrophiidae Behavioral Ecology and Sociobiology 57 6 591 598 doi 10 1007 s00265 004 0897 z ISSN 0340 5443 S2CID 34698605 Zimmerman K Heatwole H 1990 Cutaneous Photoreception A New Sensory Mechanism for Reptiles Copeia 1990 3 860 862 doi 10 2307 1446454 JSTOR 1446454 Liu Y L Lillywhite H B Tu M C 2010 07 03 Sea snakes anticipate tropical cyclone Marine Biology 157 11 2369 2373 doi 10 1007 s00227 010 1501 x ISSN 0025 3162 S2CID 85297798 a b c d U S Navy 1991 Poisonous Snakes of the World US Govt New York Dover Publications Inc 203 pp ISBN 0 486 26629 X Spawls S Branch B 1995 The Dangerous Snakes of Africa Ralph Curtis Books Dubai Oriental Press 192 pp ISBN 0 88359 029 8 Slaughter RJ Beasley DM Lambie BS Schep LJ 2009 New Zealand s venomous creatures New Zealand Medical Journal 122 1290 83 97 PMID 19319171 Venomous Yellow Bellied Sea Snake Washes Up on Coronado Beach a b The sea snakes are coming at NewScientist Accessed 13 January 2009 Vernberg F John 2014 Behavior and Ecology Elsevier Science p 186 ISBN 978 0 323 16269 2 Smith Emily 8 October 2018 Fisherman s deadly encounter with sea snake incredibly rare ABC News Warrell DA 2004 Snakebites in Central and South America Epidemiology Clinical Features and Clinical Management In Campbell JA Lamar WW 2004 The Venomous Reptiles of the Western Hemisphere Comstock Publishing Associates Ithaca and London 870 pp 1500 plates ISBN 0 8014 4141 2 Gopalakrishnakone P 1994 Sea Snake Toxinology NUS Press ISBN 978 9971 69 193 6 a b c Elapidae Integrated Taxonomic Information System Retrieved 7 August 2007 a b Elapidae Archived 2008 10 11 at the Wayback Machine at the New Reptile Database Accessed 12 August 2007 The Hydrophiidae at Cyberlizard s home pages Accessed 12 August 2007 Sanders KL Lee MS Mumpuni Bertozzi T Rasmussen AR 2012 Multilocus phylogeny and recent rapid radiation of the viviparous sea snakes Elapidae Hydrophiinae Molecular Phylogenetics and Evolution 66 3 575 591 doi 10 1016 j ympev 2012 09 021 PMID 23026811 Serpentes at CITES Accessed 11 August 2007 www iucnredlist org http www iucnredlist org apps redlist search Retrieved 14 May 2011 a href Template Cite web html title Template Cite web cite web a Missing or empty title help Further reading EditGraham JB Lowell WR Rubinoff I Motta J 1987 Surface and subsurface swimming of the sea snake Pelamis platurus J exp Biol 127 27 44 PDF at the Journal of Experimental Biology Accessed 7 August 2007 Rasmussen AR 1997 Systematics of sea snakes a critical review Symp Zool Soc London 70 15 30 Smith MA 1926 Monograph of the sea snakes Hydrophiidae British Museum of Natural History London Voris HK 1977 A phylogeny of the sea snakes Hydrophiidae Fieldiana Zool 70 79 169 Whitaker R 1978 Common Indian Snakes A Field Guide Macmillan India Limited External links EditSea Snakes in Australia Sea Snakes at Scubadoc s Diving Medicine Online Accessed 6 August 2007 Diving Gunung Api Volcano Of The Sea Snakes first hand account of scuba divers interacting with sea snakes at the Indonesian volcano Gunung Api June 2009 Retrieved from https en wikipedia org w index php title Sea snake amp oldid 1120770626, wikipedia, wiki, book, books, library,

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