Lizard
Lizards Fossil range: Early Jurassic – Holocene, 199–0 Ma Possible Late Triassic record |
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Central bearded dragon, Pogona vitticeps
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Sauria Macartney, 1802 |
Lizards are a widespread group of squamate reptiles, with over 6,000 species,[1] ranging across all continents except Antarctica, as well as most oceanic island chains. The group, traditionally recognized as the suborder Lacertilia, is defined as all extant members of the Lepidosauria (reptiles with overlapping scales) that are neither sphenodonts (i.e., tuatara) nor snakes – they form an evolutionary grade.[2] While the snakes are recognized as falling phylogenetically within the Toxicofera clade from which they evolved, the sphenodonts are the sister group to the squamates, the larger monophyletic group, which includes both the lizards and the snakes.
Contents
Biology
Lizards typically have feet and external ears, while snakes lack both of these characteristics. However, because they are defined negatively as excluding snakes, lizards have no unique distinguishing characteristic as a group.[citation needed] Lizards and snakes share a movable quadrate bone, distinguishing them from the sphenodonts, which have more primitive and solid diapsid skulls. Many lizards can detach their tails to escape from predators, an act called autotomy. Vision, including color vision, is particularly well developed in most lizards, and most communicate with body language or bright colors on their bodies, as well as with pheromones. Lizards are the most speciose clade among extant non-avian reptiles, comprising about 60% of all living species.
The adult length of species within the suborder ranges from a few centimeters for chameleons such as Brookesia micra and geckos such as Sphaerodactylus ariasae to nearly 3 m (9.8 ft) in the case of the largest living varanid lizard, the Komodo dragon. Some extinct varanids reached great size: The giant monitor Megalania is estimated to have reached up to 7 m (23 ft) long; while the extinct aquatic mosasaurs reached 17 m (56 ft).
The name Sauria was coined by James Macartney (1802);[3] it was the Latinisation of the French name Sauriens, coined by Alexandre Brongniart (1800) for an order of reptiles in the classification proposed by the author, containing lizards and crocodilians,[4] later discovered not to be each other's closest relatives. Later authors used the term "Sauria" in a more restricted sense, i.e. as a synonym of Lacertilia, a suborder of Squamata that includes all lizards but excludes snakes. This classification is rarely used today because Sauria so-defined is a paraphyletic group. It was defined as a clade by Jacques Gauthier, Arnold G. Kluge and Timothy Rowe (1988) as the group containing the most recent common ancestor of archosaurs and lepidosaurs (the groups containing crocodiles and lizards, as per Mcartney's original definition) and all its descendants.[5] A different definition was formulated by Michael deBraga and Olivier Rieppel (1997), who defined Sauria as the clade containing the most recent common ancestor of Choristodera, Archosauromorpha, Lepidosauromorpha and all their descendants.[6] However, neither of these uses have gained wide acceptance among researchers specializing in lizards.
Physiology
Sight is very important for most lizards, both for locating prey and for communication, and, as such, many lizards have highly acute color vision. Most lizards rely heavily on body language, using specific postures, gestures, and movements to define territory, resolve disputes, and entice mates. Some species of lizards also use bright colors, such as the iridescent patches on the belly of Sceloporus. These colors would be highly visible to predators, so are often hidden on the underside or between scales and only revealed when necessary.
The particular innovation in this respect is the dewlap, a brightly colored patch of skin on the throat, usually hidden between scales. When a display is needed, a lizard can erect the hyoid bone of its throat, resulting in a large vertical flap of brightly colored skin beneath the head which can be then used for communication. Anoles are particularly famous for this display, with each species having specific colors, including patterns only visible under ultraviolet (UV) light, as many lizards can see UV light.[7]
Shedding and regenerating tails
Lizard tails are often a different and dramatically more vivid color than the rest of the body so as to encourage potential predators to strike for the tail first.
Many lizard species (including geckos, skinks, and others) are capable of shedding part of their tails through a process called autotomy. This is an example of the pars pro toto principle, sacrificing "a part for the whole", and is employed by lizards to allow them to escape when captured by the tail by a predator. The detached tail writhes and wiggles, creating a deceptive sense of continued struggle, distracting the predator's attention from the fleeing prey animal.
The lizard will partially regenerate its tail over a period of weeks. A 2014 research identified 326 genes involved in the regeneration of lizard tails.[8] The new section will contain cartilage rather than bone, and the skin may be distinctly discolored compared to the rest of the body.
Reproduction
Most lizards are oviparous (egg laying), though in some species the eggs are retained until the live young emerge. Parthenogenesis in squamata (that is, asexual reproduction) occurs in about 50 species of lizards,[9][10] and it is believed that female's ability to do this in the absence of males is widespread among lizards.
Evolution and relationships
Sexual selection in lizards shows evidence of female mate choice, favouring males who display fitness indicators, such as fewer ectoparasites.[11]
The retention of the basic 'reptilian' amniote body form by lizards makes it tempting to assume any similar animal, alive or extinct, is also a lizard. However, this is not the case, and lizards as squamates are part of a well-defined group.
The earliest amniotes were superficially lizard-like, but had solid, box-like skulls, with openings only for eyes and nostrils, termed the anapsid condition. Turtles retain, or have re-evolved, this skull form. Early anapsids later gave rise to two new groups with additional holes in their skulls to make room for and anchor larger jaw muscles. The synapsids, with a single fenestra, gave rise to the large, but generally lizard-like pelycosaurs, which includes Dimetrodon, a group that gave rise to the therapsids, including the cynodonts, from which mammals would evolve.
The modern Sphenodon retains the basic lepidosaur skull, distinguishing it from true lizards in spite of superficial similarities. Squamates, including snakes and all true lizards, further lightened the skull by eliminating the lower margin of the lower skull opening.
The earliest known fossil remains of a lizard belong to the iguanian species Tikiguania estesi, found in the Tiki Formation of India, which dates to the Carnian stage of the Triassic period, about 220 million years ago.[12] However, doubt has been raised over the age of Tikiguania because it is almost indistinguishable from modern agamid lizards. The Tikiguania remains may instead be late Tertiary or Quaternary in age, having been washed into much older Triassic sediments.[13] Lizards are most closely related to a group called Rhynchocephalia, which includes the tuatara. Rhynchocephalians first appeared in the Late Triassic, so it can be inferred that the lizard-rhynchocephalian divergence occurred at this time and that the earliest lizards appeared in the Triassic.[13]
Mitochondrial phylogenetics suggest that the first lizards evolved in the late Permian. Most evolutionary relationships within the squamates are not yet completely worked out, with the relationship of snakes to other groups being the most problematic. On the basis of morphological data, iguanid lizards were thought to have diverged from other squamates very early on, but recent molecular phylogenies, both from mitochondrial and nuclear DNA, do not support this.[14] Because snakes have a faster molecular clock than other squamates,[14] and few early snake and snake ancestor fossils have been found,[15] resolving the relationship between snakes and other squamate groups is difficult.
In just a couple of decades, 5-inch lizards have developed an utterly new gut structure, larger heads, and a compact bite, according to researchers.[16]
Lizard diversification
Lacertilia comprises four generally recognized infraorders, Iguania, Gekkota, Amphisbaenia and Autarchoglossa, with the "blind skinks" in the family Dibamidae having an uncertain position. While traditionally excluded from the lizards, the snakes are usually classified as a clade with a similar subordinal rank.[17]
Iguania
The suborder Iguania, found in Africa, southern Asia, Australia, the New World and the islands of the west Pacific, forms the sister group to the rest of squamata. The various species are largely arboreal, and have primitively fleshy, non-prehensile tongues, some even have scales, but this condition is obviously highly modified in the chameleons. This clade includes the following families:
- Family Agamidae – agamid lizards, Old World arboreal lizards
- Family Chamaeleonidae – chameleons
- Family Corytophanidae – helmet lizards
- Family Crotaphytidae – collared lizards, leopard lizards
- Family Hoplocercidae – dwarf and spiny-tail iguanas
- Family Iguanidae – American arboreal lizards, chuckwallas, iguanas, iguanids
- Family Opluridae – Malagasy iguanas
- Family Phrynosomatidae – North American spiny lizards
- Family Polychrotidae – anoles and kin
- Family Tropiduridae – tropidurid lizards
Gekkota
Active hunters, the Gekkota comprises three families, the distinctive cosmopolitan geckos and the legless, flap-footed lizards of Australia and New Guinea. Like snakes, the flap-footed lizards and most geckos lack eyelids. Unlike snakes, they use their tongues to clean their often highly developed eyes. While gecko feet have unique surfaces that allow them to cling to glass and run on ceilings,[18] the flap-foot has lost its limbs. The three families of this suborder are:
- Family Eublepharinae – 'eyelid' geckos
- Family Gekkonidae – geckos
- Family Pygopodidae – flap-footed lizards
Relationship with humans
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Most lizard species are harmless to humans. Only the largest lizard species, the Komodo dragon, which reaches 3.3 m (11 ft) in length and weighs up to 166 kg (365 lb), has been known to stalk, attack, and, on occasion, kill humans. An eight-year-old Indonesian boy died from blood loss after an attack in 2007.[19] The venoms of the Gila monster and beaded lizard are not usually deadly, but they can inflict extremely painful bites due to powerful jaws.
Numerous species of lizard are kept as pets, including bearded dragons, iguanas, anoles, and geckos (such as the popular leopard gecko). Some lizards have an affinity for humans, but many are suspicious or skittish around them. Lizards that bite humans are very rare. Lizards are predominantly insectivorous, but some eat fruit, or vegetables. Live crickets and worms are the most typical foods for pet lizards, though the crested gecko (not a friendly lizard to humans) can feed entirely on fruit.
Lizard symbolism plays important, though rarely predominant, roles in some cultures (e.g., Tarrotarro in Australian Aboriginal mythology). The Moche people of ancient Peru worshipped animals and often depicted lizards in their art.[20] According to a popular legend in Maharashtra, a common Indian monitor, with ropes attached, was used to scale the walls of the Sinhagad fort in the Battle of Sinhagad.[21]
Green iguanas are eaten in Central America, where they are sometimes referred to as "chicken of the tree" after their habit of resting in trees and their supposed chicken-like taste,[22] and spiny-tailed lizards are eaten in Africa. In North Africa, Uromastyx species are considered dhaab or 'fish of the desert' and eaten by nomadic tribes.[23]
Classification
Suborder Lacertilia (Sauria) – (lizards)
- Family †Bavarisauridae
- Family †Eichstaettisauridae
- Infraorder Iguania
- Family Agamidae
- Family †Arretosauridae
- Family †Euposauridae
- Family Corytophanidae (casquehead lizards)
- Family Iguanidae (iguanas and spinytail iguanas)
- Family Phrynosomatidae (earless, spiny, tree, side-blotched and horned lizards)
- Family Polychrotidae (anoles)
- Family Leiosauridae (see Polychrotinae)
- Family Tropiduridae (neotropical ground lizards)
- Family Liolaemidae (see Tropidurinae)
- Family Leiocephalidae (see Tropidurinae)
- Family Crotaphytidae (collared and leopard lizards)
- Family Opluridae (Madagascar iguanids)
- Family Hoplocercidae (wood lizards, clubtails)
- Family †Priscagamidae
- Family †Isodontosauridae
- Family Agamidae (agamas, frilled lizards)
- Family Chamaeleonidae (chameleons)
- Infraorder Gekkota
- Family Gekkonidae (geckos)
- Family Pygopodidae (legless lizards)
- Family Dibamidae (blind lizards)
- Infraorder Scincomorpha
- Family †Paramacellodidae
- Family †Slavoiidae
- Family Scincidae (skinks)
- Family Cordylidae (spinytail lizards)
- Family Gerrhosauridae (plated lizards)
- Family Xantusiidae (night lizards)
- Family Lacertidae (wall lizards or true lizards)
- Family †Mongolochamopidae
- Family †Adamisauridae
- Family Teiidae (tegus and whiptails)
- Family Gymnophthalmidae (spectacled lizards)
- Infraorder Diploglossa
- Family Anguidae (glass lizards)
- Family Anniellidae (American legless lizards)
- Family Xenosauridae (knob-scaled lizards)
- Infraorder Platynota (Varanoidea)
- Family Varanidae (monitor lizards)
- Family Lanthanotidae (earless monitor lizards)
- Family Helodermatidae (Gila monsters and beaded lizards)
- Family †Mosasauridae (marine lizards)
Notes
- ^ Reptile Database. Retrieved on 2012-04-22
- ^ Gibbons, J. Whitfield; Gibbons, Whit (1983). Their Blood Runs Cold: Adventures With Reptiles and Amphibians. Alabama: University of Alabama Press. p. 164. ISBN 978-0-8173-0135-4.
- ^ James Macartney: Table III in: George Cuvier (1802) "Lectures on Comparative Anatomy" (translated by William Ross under the inspection of James Macartney). Vol I. London, Oriental Press, Wilson and Co.
- ^ Alexandre Brongniart (1800) "Essai d’une classification naturelle des reptiles. 1ère partie: Etablissement des ordres." Bulletin de la Science. Société Philomathique de Paris 2 (35): 81-82
- ^ Gauthier, J. A.; Kluge, A. G.; Rowe, T. (June 1988). "Amniote phylogeny and the importance of fossils". Cladistics. John Wiley & Sons. 4 (2): 105–209. doi:10.1111/j.1096-0031.1988.tb00514.x.
- ^ Debraga, M. & Rieppel, O. (1997). "Reptile phylogeny and the interrelationships of turtles". Zoological Journal of the Linnean Society. 120 (3): 281–354. doi:10.1111/j.1096-3642.1997.tb01280.x.
- ^ "Reptile Lighting Information". reptilesmagazine. Retrieved 31 August 2015.
- ^ Scientists discover how lizards regrow tails, The Independent, August 20, 2014
- ^ Macculloch, Ross; Robert Murphy; Larissa Kupriyanova; Ilya Darevsky (January 1997). "The Caucasian rock lizard Lacerta rostombekovi: a monoclonal parthenogenetic vertebrate". Biochemical Systematics and Ecology. 25 (1): 33–37. doi:10.1016/S0305-1978(96)00085-3. Retrieved 19 April 2014.
- ^ Vitt, Laurie J., and Janalee P. Caldwell. Herpetology: an introductory biology of amphibians and reptiles. Academic Press, 2013.
- ^ Charles, G.; Ord, T. (2012). "Factors Leading to the Evolution Maintenance of a Male Ornament in Territorial Species". Behavioral Ecology and Sociobiology. 11: 127–31.
- ^ Datta, P.M. & Ray, S. (2006). "Earliest lizards from the Late Triassic (Carnian) of India". Journal of Vertebrate Paleontology. 26 (4): 795–800. doi:10.1671/0272-4634(2006)26[795:ELFTLT]2.0.CO;2.
- ^ a b Hutchinson, M.N.; Skinner, A.; Lee, M.S.Y. (2012). "Tikiguania and the antiquity of squamate reptiles (lizards and snakes)". Biology Letters. 8 (4): 665–9. doi:10.1098/rsbl.2011.1216. PMC 3391445. PMID 22279152.
- ^ a b Kumazawa, Yoshinori (2007). "Mitochondrial genomes from major lizard families suggest their phylogenetic relationships and ancient radiations". Gene. 388 (1–2): 19–26. doi:10.1016/j.gene.2006.09.026. PMID 17118581.
- ^ "Lizards & Snakes Alive!". American Museum of Natural History. Retrieved 2007-12-25.
- ^ "Lizards Rapidly Evolve After Introduction to Island". news.nationalgeographic.com. Retrieved 2016-08-03.
- ^ Squamata Oppel, 1811. the Integrated Taxonomic Information System. ITIS.org
- ^ Santos, Daniel; Spenko, Matthew; Parness, Aaron; Kim, Sangbae; Cutkosky, Mark (2007). "Directional adhesion for climbing: theoretical and practical considerations". Journal of Adhesion Science and Technology. 21 (12–13): 1317–1341. doi:10.1163/156856107782328399.
Gecko "feet and toes are a hierarchical system of complex structures consisting of lamellae, setae,and spatulae. The distinguishing characteristics of the gecko adhesion system have been described [as] (1) anisotropic attachment, (2) high pulloff force to preload ratio, (3) low detachment force, (4) material independence, (5) self-cleaning, (6) anti-self sticking and (7) non-sticky default state. ... The gecko’s adhesive structures are made from ß-keratin (modulus of elasticity [approx.] 2 GPa). Such a stiff material is not inherently sticky; however, because of the gecko adhesive’s hierarchical nature and extremely small distal features (spatulae are [approx.] 200 nm in size), the gecko’s foot is able to intimately conform to the surface and generate significant attraction using van der Waals forces.
- ^ Komodo dragon kills boy in Indonesia – World news – Asia-Pacific – msnbc.com. MSNBC. Retrieved on 2011-11-07.
- ^ Berrin, Katherine & Larco Museum. The Spirit of Ancient Peru:Treasures from the Museo Arqueológico Rafael Larco Herrera. New York: Thames and Hudson, 1997.
- ^ Auffenberg, Walter (1994). The Bengal Monitor. University Press of Florida. p. 494. ISBN 0-8130-1295-3.
- ^ Referencias culturales - todo iguanas verdes
- ^ Grzimek, Bernhard. Grzimek’s Animal Life Encyclopedia (Second Edition) Vol 7 – Reptiles. (2003) Thomson – Gale. Farmington Hills, Minnesota. Vol Editor – Neil Schlager. ISBN 0-7876-5783-2 (for vol.7). p. 48
References
- Behler, John L.; King, F. Wayne (1979). The Audubon Society Field Guide to Reptiles and Amphibians of North America. New York: Alfred A. Knopf. p. 581. ISBN 0-394-50824-6.
- Capula, Massimo; Behler, John L. (1989). Simon & Schuster's Guide to Reptiles and Amphibians of the World. New York: Simon & Schuster. ISBN 0-671-69098-1.
- Cogger, Harold; Zweifel, Richard (1992). Reptiles & Amphibians. Sydney: Weldon Owen. ISBN 0-8317-2786-1.
- Conant, Roger; Collins, Joseph (1991). A Field Guide to Reptiles and Amphibians Eastern/Central North America. Boston, Massachusetts: Houghton Mifflin Company. ISBN 0-395-58389-6.
- Ditmars, Raymond L (1933). Reptiles of the World: The Crocodilians, Lizards, Snakes, Turtles and Tortoises of the Eastern and Western Hemispheres. New York: Macmillan. p. 321.
- Freiberg, Dr. Marcos; Walls, Jerry (1984). The World of Venomous Animals. New Jersey: TFH Publications. ISBN 0-87666-567-9.
- Gibbons, J. Whitfield (1983). Their Blood Runs Cold: Adventures With Reptiles and Amphibians. Alabama: University of Alabama Press. p. 164. ISBN 978-0-8173-0135-4.
- Rosenfeld, Arthur (1987). Exotic Pets. New York: Simon & Schuster. p. 293. ISBN 0671636901.
Further reading
- Pianka, Eric R.; Vitt, Laurie J. (2006). Lizards: Windows to the Evolution of Diversity. Berkeley, Calif.: Univ. of California Press. ISBN 9780520248472.
External links
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