Elapidae

Elapidae

Elapidae

Family of venomous snakes

Quick Facts Scientific classification, Subfamilies and genera ...

Elapidae (/əˈlæpəd/, commonly known as elapids /ˈɛləpədz/; Ancient Greek: ἔλλοψ éllops "sea-fish")[6] is a family of snakes characterized by their permanently erect fangs at the front of the mouth. Most elapids are venomous, with the exception of the genus Emydocephalus. Many members of this family exhibit a threat display of rearing upwards while spreading out a neck flap. Elapids are endemic to tropical and subtropical regions around the world, with terrestrial forms in Asia, Australia, Africa, and the Americas and marine forms in the Pacific and Indian Oceans. Members of the family have a wide range of sizes, from the 18 cm (7.1 in) white-lipped snake to the 5.85 m (19 ft 2 in) king cobra. Most species have neurotoxic venom that is channeled by their hollow fangs, and some may contain other toxic components in various proportions. The family includes 55 genera with around 360 species and over 170 subspecies.

Description

Terrestrial elapids look similar to the Colubridae; almost all have long, slender bodies with smooth scales, a head covered with large shields (and not always distinct from the neck), and eyes with rounded pupils. Also like colubrids, their behavior is usually quite active and fast, with most of the females being oviparous (egg-layers). Exceptions to these generalizations occur; for example, certain adders (Acanthophis) have commonalities with the Viperidae family, such as shorter, stout bodies, rough/keeled scales, broad heads, cat-like pupils and ovoviviparous (internal hatchings with live births). Furthermore, they can also be sluggish, ambush predators with partially fragmented head shields, similar to rattlesnakes or Gaboon vipers.

Sea snakes (the Hydrophiinae), sometimes considered to be a separate family, have adapted to a marine way of life in different ways and to various degrees. All have evolved paddle-like tails for swimming and the ability to excrete salt. Most also have laterally compressed bodies, their ventral scales are much reduced in size, their nostrils are located dorsally (no internasal scales), and they give birth to live young (viviparity). The reduction in ventral scaling has greatly diminished their terrestrial mobility, but aids in swimming.

Members of this family have a wide range of sizes. Drysdalia species are small serpents typically 50 cm (20 in) and down to 18 cm (7.1 in) in length. Cobras, mambas, and taipans are mid- to large sized snakes which can reach 2 m (6 ft 7 in) or above. The king cobra is the world's longest venomous snake with a maximum length of 5.85 m (19.2 ft) and an average mass of 6 kg (13 lb).[7]

Dentition

The lateral view of a king cobra's skull showing fangs

All elapids have a pair of proteroglyphous fangs to inject venom from glands located towards the rear of the upper jaw (except for the genus Emydocephalus, in which fangs are present as a vestigial feature but without venom production, as they have specialized toward a fish egg diet, making them the only non-venomous elapids). The fangs, which are enlarged and hollow, are the first two teeth on each maxillary bone. Usually only one fang is in place on each side at any time. The maxilla is intermediate in both length and mobility between typical colubrids (long, less mobile) and viperids (very short, highly mobile). When the mouth is closed, the fangs fit into grooved slots in the buccal floor and usually below the front edge of the eye and are angled backwards; some elapids (Acanthophis, taipan, mamba, and king cobra) have long fangs on quite mobile maxillae and can make fast strikes. A few species are capable of spraying their venom from forward-facing holes in their fangs for defense, as exemplified by spitting cobras.

Behavior

Most elapids are terrestrial, while some are strongly arboreal (African Pseudohaje and Dendroaspis, Australian Hoplocephalus). Many species are more or less specialized burrowers (e.g. Ogmodon, Parapistocalamus, Simoselaps, Toxicocalamus, and Vermicella) in either humid or arid environments. Some species have very generalised diets (euryphagy), but many taxa have narrow prey preferences (stenophagy) and correlated morphological specializations, for example feeding almost exclusively on other serpents (especially the king cobra and kraits). Elapids may display a series of warning signs if provoked, either obviously or subtly. Cobras and mambas lift their inferior body parts, expand hoods, and hiss if threatened; kraits often curl up before hiding their heads down their bodies.

In general, sea snakes are able to respire through their skin. Experiments with the yellow-bellied sea snake, Hydrophis platurus, have shown that this species can satisfy about 20% of its oxygen requirements in this manner, allowing for prolonged dives. The sea kraits (Laticauda spp.) are the sea snakes least adapted to aquatic life. Their bodies are less compressed laterally, and they have thicker bodies and ventral scaling. Because of this, they are capable of some land movement. They spend much of their time on land, where they lay their eggs and digest prey.

Distribution

Terrestrial elapids are found worldwide in tropical and subtropical regions, mostly in the Southern Hemisphere. Most prefer humid tropical environments, though there are many that can still be found in arid environments. Sea snakes occur mainly in the Indian Ocean and the south-west Pacific. They occupy coastal waters and shallows, and are common in coral reefs. However, the range of Hydrophis platurus extends across the Pacific to the coasts of Central and South America.[8]

Venom

Venoms of species in the Elapidae are mainly neurotoxic for immobilizing prey and defense. The main group of toxins are PLA2 and three-finger toxins (3FTx). Other toxic components in some species comprise cardiotoxins and cytotoxins, which cause heart dysfunctions and cellular damage, respectively. Cobra venom also contains hemotoxins which clot or solidify blood. Most members are venomous to varying extents, and some are considered among the world's most venomous snakes based upon their murine LD50 values, such as the taipans.[9] Large species, mambas and cobras included, are dangerous for their capability of injecting high quantities of venom upon single envenomation and/or striking at a high position proximal to the victim's brain, which is vulnerable to neurotoxicity. Antivenom is promptly required to be administered if bitten by any elapids. Specific antivenoms are the only cure to treat elapidae bites. There are commercial monovalent and polyvalent antivenoms for cobras, mambas, and some other important elapids. Recently, experimental antivenoms based on recombinant toxins have shown that it is feasible to create antivenoms with a wide spectrum of coverage.[10]

The venom of spitting cobras is more cytotoxic rather than neurotoxic. It damages local cells, especially those in eyes, which are deliberately targeted by the snakes. The venom may cause intense pain on contact with the eye and may lead to blindness. It is not lethal on skin if no wound provides any chance for the toxins to enter the bloodstream.[11]

Taxonomy

The table below lists out all of the elapid genera and no subfamilies. In the past, many subfamilies were recognized, or have been suggested for the Elapidae, including the Elapinae, Hydrophiinae (sea snakes), Micrurinae (coral snakes), Acanthophiinae (Australian elapids), and the Laticaudinae (sea kraits). Currently, none are universally recognized. Molecular evidence via techniques like karyotyping, protein electrophoretic analyses, immunological distance and DNA sequencing, suggests reciprocal monophyly of two groups: African, Asian, and New World Elapinae versus Australasian and marine Hydrophiinae. The Australian terrestrial elapids are technically 'hydrophiines', although they are not sea snakes. It is believed that the Laticauda and the 'true sea snakes' evolved separately from Australasian land snakes. Asian cobras, coral snakes, and American coral snakes also appear to be monophyletic, while African cobras do not.[12][13]

The type genus for the Elapidae was originally Elaps, but the group was moved to another family. In contrast to what is typical of botany, the family Elapidae was not renamed. In the meantime, Elaps was renamed Homoroselaps and moved back to the Elapidae. However, Nagy et al. (2005) regard it as a sister taxon to Atractaspis, which should have been assigned to the Atractaspididae.

More information Genus, Taxon author ...

* Not including the nominate subspecies

Conservation

With the dangers the taxa presents given their venomous nature it is very difficult for activists and conservationists alike to get species on protection lists such as the IUCN red-list and CITES Apenndix lists. Some of the protected species are:

This however does not touch the number of elapidae that are under threat, for instance 9% of elapid sea snakes are threatened with another 6% near-threatened.[19] A rather large road block that stands in the way of more species being put under protection is lack of knowledge of the taxa; many known species have little research done on their behaviors or actual population as they live in very remote areas or live in habitats that are so vast its nearly impossible to conduct population studies, like the sea snakes.

See also

Explanatory notes

  1. The elapids in the past were considered to have two subfamilies–the Elapinae made of terrestrial species and Hydrophiinae made of the marine species.[1] In 1997, Slowinski, Knight and Rooney found in their phylogenetic analysis using amino acid sequences from venom proteins, that the Australasian terrestrial species nested within Hydrophiinae. This led to removing the Australasian terrestrial species and placing them in the Hydrophiinae.[2][1] This has been support in subsequent recent genomic analyses, though these same studies also found the subfamily Elapinae to be paraphyletic in respect to the Hydrophiinae.[3][4][5] These studies have found coral snakes, cobras and mambas, kraits, and African gartersnakes forming successive outgroups to Hydrophiinae.[4][5] Since there are available clade names for these groups (with the exception of Elapsoidea), it is ideal to bring back the subfamilies Calliophiinae, Micrurinae, Najinae, and Bungarinae.

References

  1. [1]
    Mattison C (2007). The New Encyclopedia of Snakes. Princeton, New Jersey: Princeton University Press. 272 pp. ISBN 978-0-691-13295-2.
  2. [2]
    Slowinski, Joseph B.; Knight, Alec; Rooney, Alejandro P. (1997). "Inferring species trees from gene trees: a phylogenetic analysis of the Elapidae (Serpentes) based on the amino acid sequences of venom proteins". Molecular Phylogenetics and Evolution. 8 (3): 349–62. CiteSeerX 10.1.1.324.3013. doi:10.1006/mpev.1997.0434. PMID 9417893.
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    Pyron RA, Burbrink FT, Wiens JJ (2013). "A phylogeny and revised classification of Squamata, including 4161 species of lizards and snakes". BMC Evolutionary Biology. 13 (1): 93. Bibcode:2013BMCEE..13...93P. doi:10.1186/1471-2148-13-93. PMC 3682911. PMID 23627680.
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    Lee MS, Sanders KL, King B, Palci A (2016). "Diversification rates and phenotypic evolution in venomous snakes (Elapidae)". Royal Society Open Science. 3 (1): 150277. Bibcode:2016RSOS....350277L. doi:10.1098/rsos.150277. PMC 4736917. PMID 26909162.
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    Figueroa A, McKelvy AD, Grismer LL, Bell CD, Lailvaux SP (2016). "A Species-Level Phylogeny of Extant Snakes with Description of a New Colubrid Subfamily and Genus". PLOS ONE. 11 (9): e0161070. Bibcode:2016PLoSO..1161070F. doi:10.1371/journal.pone.0161070. PMC 5014348. PMID 27603205.
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    "Definition of 'elapid'". dictionary.com. Archived from the original on 2015-04-02. Retrieved 2009-07-13.
  7. [7]
    Chanhome L, Cox MJ, Vasaruchapong T, Chaiyabutr N, Sitprija V (June 2011). "Characterization of venomous snakes of Thailand". Asian Biomedicine. 5 (3): 311–28. doi:10.5372/1905-7415.0503.043 (inactive 31 January 2024).{{cite journal}}: CS1 maint: DOI inactive as of January 2024 (link)
  8. [8]
    Elapidae at the Reptarium.cz Reptile Database. Accessed 3 November 2008.
  9. [9]
    Thomas S, Griessel E (Dec 1999). "LD50 Scores for various snakes". Archived from the original on 1 February 2012.
  10. [10]
    de la Rosa G, Olvera F, Archundia IG, Lomonte B, Alagón A, Corzo G (August 2019). "Horse immunization with short-chain consensus α-neurotoxin generates antibodies against broad spectrum of elapid venomous species". Nature Communications. 10 (1): 3642. Bibcode:2019NatCo..10.3642D. doi:10.1038/s41467-019-11639-2. PMC 6692343. PMID 31409779.
  11. [11]
    Regional Office for Africa, World Health Organization (2010). "Guidelines for the Prevention and Clinical Management of Snakebite in Africa". Archived from the original on March 25, 2016. Retrieved July 9, 2021.
  12. [12]
    Slowinski JB, Keogh JS (April 2000). "Phylogenetic relationships of elapid snakes based on cytochrome b mtDNA sequences" (PDF). Molecular Phylogenetics and Evolution. 15 (1): 157–64. doi:10.1006/mpev.1999.0725. PMID 10764543. Archived (PDF) from the original on 2019-03-14. Retrieved 2019-10-14.
  13. [13]
    Williams D, Wüster W, Fry BG (December 2006). "The good, the bad and the ugly: Australian snake taxonomists and a history of the taxonomy of Australia's venomous snakes" (PDF). Toxicon. 48 (7): 919–30. doi:10.1016/j.toxicon.2006.07.016. PMID 16999982. Archived (PDF) from the original on 2012-10-10. Retrieved 2010-09-18.
  14. [14]
    "Elapidae". Integrated Taxonomic Information System. Retrieved 27 November 2006.
  15. [15]
    The Hydrophiidae Archived 2007-07-02 at the Wayback Machine at Cyberlizard's home pages Archived 2007-11-24 at the Wayback Machine. Accessed [12 August] [2007].
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    Scanlon J,Lee M, Archer M, 2002, Mid-Tertiary elapid snakes (Squamata, Colubroidea) from Riversleigh, northern Australia: early steps in a continent-wide adaptive radiation, Geobios 36 (2003) 573–601 Archived 2019-03-12 at the Wayback Machine.
  17. [17]
    Nilson G, Rastegar-Pouyani N (2007). "Walterinnesia aegyptia Lataste, 1887 (Ophidia: Elapidae) and the status of Naja morgani Mocquard, 1905". Russian Journal of Herpetology 14: 7-14.
  18. [18]
    Ugurtas IH, Papenfuss TJ, Orlov NL (2001). "New record of Walterinnesia aegyptia Lataste, 1887 (Ophidia: Elapidae: Bungarinae) in Turkey". Russian Journal of Herpetology 8 (3): 239-245.
  19. [19]
    Eifes, C.T. & Livingstone 2013.

Further reading

  • Goin CJ, Goin OB, Zug GR (1978). Introduction to Herpetology, Third Edition. San Francisco: W.H. Freeman and Company. xi + 378 pp. ISBN 0-7167-0020-4. (Family Elapidae, pp. 329–333).
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