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Caecilians; Fossil range: 170–0 Ma PreЄ Є O S D C P T J K Pg N Lower Jurassic – Recent
	"Caecilian"
Scientific classification
Kingdom:	Animalia;
Phylum:	Chordata;
Class:	Amphibia;
Order:	Gymnophiona; Müller, 1832
Families
	Rhinatrematidae; Ichthyophiidae; Uraeotyphlidae; Scolecomorphidae; Typhlonectidae; Caeciliidae

This article is about an order of amphibians. For the bishop of Carthage, see Caecilianus.

The caecilians (pronounced /siːˈsɪliən/) are an order (Gymnophiona) of amphibians that superficially resemble earthworms or snakes. They mostly live hidden in the ground, which makes them the least explored order of amphibians, and widely unknown.

[edit] Anatomy

Caecilians completely lack limbs, making the smaller species resemble worms, while the larger species with lengths up to 1.5 m (4 ft 11 in) resemble snakes. The tail is short or absent, and the cloaca is near the end of the body.

Their skin is smooth and usually dark-matte, but some species have colorful skins. Inside the skin are calcite scales. Because of these scales, the caecilians were once thought to be related to the fossil Stegocephalia, but they are now believed to be a secondary development, and the two groups are most likely unrelated.

The skin also has numerous ring-shaped folds, or annuli, that partially encircle the body, giving them a segmented appearance. Like other living amphibians, the skin contains glands that secrete a toxin to discourage predators.^[1] The skin secretions of Siphonops paulensis have been shown to have hemolytic properties.^[2]

Caecilians' vision is limited to dark-light perception, and their anatomy is highly adapted for a burrowing lifestyle. They have a strong skull, with a pointed snout used to force their way through soil or mud. In most species, the number of bones in the skull are reduced and fused together, and the mouth is recessed under the head. Their muscles are adapted to pushing their way through the ground, with the skeleton and deep muscles acting as a piston inside the skin and outer muscles. This allows the animal to anchor its hind end in position, and force the head forwards, and then pull the rest of the body up to reach it in waves. In water or very loose mud, caecilians instead swim in an eel-like fashion.^[1] Caecilians in the family Typhlonectidae are aquatic as well as being the largest of their kind. The representatives of this family have a fleshy fin running along the rear section of their body, which enhances propulsion in water.^[3]

All but the most primitive caecilians have two sets of muscles for closing the jaw, compared with the single pair found in all other vertebrates. These are more highly developed in the most efficient burrowers among the caecilians, and appear to help keep the skull and jaw rigid.^[1]

Owing to their underground life, the eyes are small and covered by skin for protection, which has led to the misconception that they are blind. This is not strictly true, although their sight is limited to simple dark-light perception. All caecilians possess a pair of tentacles, located between their eyes and nostrils. These are probably used for a second olfactory capability, in addition to the normal sense of smell based in the nose.^[1]

Except for one lungless species — Atretochoana eiselti, only known from two specimens collected in South America — all caecilians have lungs, but also use the skin or the mouth for oxygen absorption. Often the left lung is much smaller than the right one, an adaptation to body shape that is also found in snakes.

[edit] Distribution

Caecilians are found in wet tropical regions of South-East Asia, India and Sri Lanka, parts of East and West Africa, the Seychelles islands in the Indian Ocean and in northern and eastern South America. In Africa caecilians are found from Guinea Bissau (Geotrypetes) to Southern Malawi (Scolecomorphus), with an unconfirmed record from eastern Zimbabwe. They have not been recorded from the extensive areas of tropical forest in central Africa. In South America they extends through subtropical eastern Brazil well into temperate northern Argentina. They can be seen as far south as Buenos Aires, when they are carried by the flood waters of the Parana river coming from farther north. The northernmost distribution is of the species Ichthyophis sikkimensis of Northern India. Ichthyophis is also found in South China and North Vietnam. In South-East Asia, they do not cross the Wallace-Line, and they are not found in Australia or the islands in between.

[edit] Reproduction

Maternal care in Ichthyophis

Caecilians are the only order of amphibians which only use internal insemination (although the tailed frog in the U.S. does use a penis like tail for internal insemination in its fast flowing water environment) . The male caecilians have a penis-like organ, the phallodeum, which is inserted into the cloaca of the female for 2 to 3 hours. About 25% of the species are oviparous (egg-laying); the eggs are guarded by the female. For some species the young caecilians are already metamorphosed when they hatch; others hatch as larvae. The larvae are not fully aquatic, but spend the daytime in the soil near the water.^[1]

75% of the species are viviparous, meaning that they give birth to already developed offspring. The fetus is fed inside the female with cells of the oviduct, which they eat with special scraping teeth.

The egg laying species Boulengerula taitanus feeds its young by developing an outer layer of skin, high in fat and other nutrients, which the young peel off with similar teeth. This allows them to grow by up to ten times their own weight in a week. The skin is consumed every three days, the time it takes for a new layer to grow, and the young have only been observed to eat it at night. It was previously thought that the juveniles subsisted on a liquid secretion from their mother.^[4]

Some larvae, such as those of Typhlonectes, are born with enormous external gills which are shed almost immediately. Ichthyophis is oviparous and known to show maternal care, with the mother guarding the eggs until they hatch.

[edit] Diet

The diet of caecilians is not well-known. Their young feed by "tearing strips of fatty skin from their mothers."^[5] Mature caecilians seem to feed mostly on insects and other invertebrates found in the habitat of the respective species. The stomach contents of 14 specimens of Afrocaecilia taitana consisted of mostly undefinable organic material and plant remains. Where identifiable remains were most abundant, they were found to be termite heads.^[6] While it was suggested^[specify] that the undefinable organic material shows that the caecilians eat detritus, others believe these are in fact the remains of earthworms. Caecilians in captivity can be easily fed with earthworms, and worms are also common in the habitat of many caecilian species.

[edit] Etymology

The name caecilian derives from the Latin word caecus = blind, referring to the small or sometimes non-existing eyes. The name dates back to the taxonomic name of the first species described by Carolus Linnaeus, which he gave the name Caecilia tentaculata. The taxonomic name of the order derives from the Greek words γυμνος (gymnos, naked) and οφις (ophis, snake), as the caecilians were originally thought to be related to snakes.

[edit] Taxonomy

Caecilian from the San Antonio Zoo

Until recently caecilians were divided into 6 families. In 2006 Daryl Frost of the American Museum of Natural History [1], along with 18 co-authors from around the world, published a major revision of amphibian classification^[7]. Based on parsimony analysis of DNA sequence data, Frost and co-authors found that some named groups of caecilians were nested within other such groups and should be subsumed into these, resulting in the current concept of three scientific families of caecilians. Although the taxonomic changes suggested in this work are somewhat controversial ^[8]^[9] this controversy does not involve the changes to caecilian classification, which largely corroborated results from previous studies. Many described species are identified on the basis of a single specimen. It is almost certain that not all species have been described yet and also that some currently accepted species may be lumped together in future reclassifications.

Beaked Caecilians (Rhinatrematidae) - 2 genera, 9 species, South America
Fish Caecilians (Ichthyophiidae) - 3 genera, 44 species, Indo-Burma and Sundaland(including species formerly placed in Uraeotyphlidae)
Common Caecilians (Caeciliidae) - 33 genera, 118 species, Africa, South America, Indo-Burma and Seychelles (including species formerly placed in Scolecomorphidae and Typhlonectidae)

[edit] Evolution

Little is known of the evolutionary history of the caecilians, which have left almost no fossil record. The first fossil, a vertebra dated to the Paleocene, wasn't discovered until 1972.^[10] The earliest fossil known comes from the Jurassic period; its primitive genus, Eocaecilia, had small limbs and well-developed eyes.^[11] What few fossils exist suggest that caecilians have changed little in millions of years.^{[citation needed]}. In their 2008 description of the fossil batrachian Gerobatrachus in 2008^[12] Anderson and co-authors suggested that caecilians arose from the Lepospondyl group of ancestral tetrapods, and may be more closely related to amniotes than to frogs and salamanders, which arose from Temnospondyl ancestors. Divergent origins of caecilians and other living amphibians may help explain the discrepancy between fossil dates for the origins of modern amphibia, which suggest Permian origins, and the much earlier dates, in the Carboniferous, predicted by molecular clock studies of DNA sequences. Most morphological and molecular studies of living amphibians, however, support common ancestry for caecilians, frogs and salamanders.

[edit] References

Specific references:

^ ^a ^b ^c ^d ^e ^f Nussbaum, Ronald A. (1998). Cogger, H.G. & Zweifel, R.G.. ed. Encyclopedia of Reptiles and Amphibians. San Diego: Academic Press. pp. 52–59. ISBN 0-12-178560-2.
^ Elisabeth N. Ferroni Schwartz, Carlos A. Schwartz, Antonio Sebben (1998). "Occurrence of hemolytic activity in the skin secretion of the caecilian Siphonops paulensis". Natural Toxins 6 (5): 179–182. doi:10.1002/(SICI)1522-7189(199809/10)6:5<179::AID-NT20>3.0.CO;2-M.
^ Piper, Ross (2007). Extraordinary Animals: An Encyclopedia of Curious and Unusual Animals. Greenwood Press.
^ Kupfer, Alex; Muller, Hendrik; Antoniazzi, Marta M.; Jared, Carlos; Greven, Hartmut; Nussbaum, Ronald A.; Wilkinson, Mark (2006). "Parental investment by skin feeding in a caecilian amphibian". Nature 440 (7086): 926–929. doi:10.1038/nature04403.
^ At home with Attenborough, a 9 January 2008 blog entry from the Nature Network
^ Hebrard, J.J.; G.M.O. Maloiy, D.M.I. Al-Liangana (1992). "Notes on the habitat and diet of Afrocaecilia taitana". J. Herpetol. 26: 513–515. doi:10.2307/1565136.
^ Frost et al. (2006) The Amphibian Tree of Life. Bulletin of the American Museum of Natural History 297: 1-370 + appendices
^ Wiens (2007) Review: The Amphibian Tree of Life. Quarterly Review of Biology 82:55-56
^ Frost et al. (2008) Is The Amphibian Tree of Life really fatally flawed? Cladistics 24:385-395
^ Estes, Richard; Marvalee H. Wake (22 September 1972). "The First Fossil Record of Caecilian Amphibians". Nature. doi:10.1038/239228b0. http://www.nature.com/nature/journal/v239/n5369/abs/239228b0.html. Retrieved 2009-08-18. "For the caecilians, however, no authentic fossils have been recognized, until now. We describe here a single diagnostic vertebra from the Palaeocene of Brazil."
^ Jenkins, Parish A., Jr.; Denis M. Walsh (16 September 1993). "An Early Jurassic caecilian with limbs". Nature. doi:10.1038/365246a0. http://www.nature.com/nature/journal/v365/n6443/abs/365246a0.html. Retrieved 2009-08-18. "We report here the discovery of an extensive series of Early Jurassic caecilians which extends the fossil record of the group and reveals numerous features, including limbs, that are unknown among modern species."
^ Anderson et al. (2008) A stem batrachian from the Early Permian of Texas and the origin of frogs and salamanders. Nature 453 [doi:10.1038/nature06865]

General references:

"Caecilia". Encyclopædia Britannica (11th ed.). 1911.
Werner Himstedt, Die Blindwühlen, ISBN 3-89432-434-1 (German)
San Mauro, Diego; David J. Gower, Oommen V. Oommen, Mark Wilkinson and Rafael Zardoya (November 2004). "Phylogeny of caecilian amphibians (Gymnophiona) based on complete mitochondrial genomes and nuclear RAG1". Molecular Phylogenetics and Evolution 33: 413–427. doi:10.1016/j.ympev.2004.05.014.
San Mauro, Diego; Miguel Vences, Marina Alcobendas, Rafael Zardoya and Axel Meyer (May 2005). "Initial diversification of living amphibians predated the breakup of Pangaea". American Naturalist 165: 590–599. doi:10.1086/429523.
San Mauro, Diego; David J. Gower, Tim Massingham, Mark Wilkinson, Rafael Zardoya and James A. Cotton (August 2009). "Experimental design in caecilian systematics: phylogenetic information of mitochondrial genomes and nuclear rag1". Systematic Biology 58: 425-438. http://sysbio.oxfordjournals.org/cgi/reprint/58/4/425.

[edit] External links

Wikispecies has information related to: Gymnophiona

Wikimedia Commons has media related to: Gymnophiona

New Scientist article on Boulengerula taitanus

[EoR-0] ^ ^a ^b ^c ^d ^e ^f Nussbaum, Ronald A. (1998). Cogger, H.G. & Zweifel, R.G.. ed. Encyclopedia of Reptiles and Amphibians. San Diego: Academic Press. pp. 52–59. ISBN 0-12-178560-2.

[1] Elisabeth N. Ferroni Schwartz, Carlos A. Schwartz, Antonio Sebben (1998). "Occurrence of hemolytic activity in the skin secretion of the caecilian Siphonops paulensis". Natural Toxins 6 (5): 179–182. doi:10.1002/(SICI)1522-7189(199809/10)6:5<179::AID-NT20>3.0.CO;2-M.

[2] Piper, Ross (2007). Extraordinary Animals: An Encyclopedia of Curious and Unusual Animals. Greenwood Press.

[3] Kupfer, Alex; Muller, Hendrik; Antoniazzi, Marta M.; Jared, Carlos; Greven, Hartmut; Nussbaum, Ronald A.; Wilkinson, Mark (2006). "Parental investment by skin feeding in a caecilian amphibian". Nature 440 (7086): 926–929. doi:10.1038/nature04403.

[4] At home with Attenborough, a 9 January 2008 blog entry from the Nature Network

[5] Hebrard, J.J.; G.M.O. Maloiy, D.M.I. Al-Liangana (1992). "Notes on the habitat and diet of Afrocaecilia taitana". J. Herpetol. 26: 513–515. doi:10.2307/1565136.

[6] Frost et al. (2006) The Amphibian Tree of Life. Bulletin of the American Museum of Natural History 297: 1-370 + appendices

[7] Wiens (2007) Review: The Amphibian Tree of Life. Quarterly Review of Biology 82:55-56

[8] Frost et al. (2008) Is The Amphibian Tree of Life really fatally flawed? Cladistics 24:385-395

[9] Estes, Richard; Marvalee H. Wake (22 September 1972). "The First Fossil Record of Caecilian Amphibians". Nature. doi:10.1038/239228b0. http://www.nature.com/nature/journal/v239/n5369/abs/239228b0.html. Retrieved 2009-08-18. "For the caecilians, however, no authentic fossils have been recognized, until now. We describe here a single diagnostic vertebra from the Palaeocene of Brazil."

[10] Jenkins, Parish A., Jr.; Denis M. Walsh (16 September 1993). "An Early Jurassic caecilian with limbs". Nature. doi:10.1038/365246a0. http://www.nature.com/nature/journal/v365/n6443/abs/365246a0.html. Retrieved 2009-08-18. "We report here the discovery of an extensive series of Early Jurassic caecilians which extends the fossil record of the group and reveals numerous features, including limbs, that are unknown among modern species."

[11] Anderson et al. (2008) A stem batrachian from the Early Permian of Texas and the origin of frogs and salamanders. Nature 453 [doi:10.1038/nature06865]

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