dcsimg

Distribution

provided by ReptileDB
Continent: Australia
Distribution: Australia (North Territory, Queensland, South Australia, West Australia) caudicinctus: Pilbara region and offshore islands, West Australia graafi: far eastern interiorof West Australia mensarum: Murchison and East Murchison Goldfields, West Australia infans: Mt. Margaret Goldfield, West Australia slateri: ranges of S North Territory macropus: Arnhem Land, North Territory.
Type locality: Nickol (as Nicol) Bay, West Australia
Type locality: Mermaid Strait, W. A. (as Nova Hollandia borealis, Meermaidstraat) [Amphibolurus imbricatus]
Type locality: Mt. Eveline, in 26° 10 S, 127° 06 E, West Australia [graafi]
Type locality: Deeba Rock-Hole, 25 mi NE of Laverton, in 28° 22 S, 122° 35 E, West Australia [infans]
Type locality: 5 mi S of Meekatharra, in 26° 40 S, 118° 27 E, West Australia [mensarum]
Type locality: 4. 5 mi SSE of Oenpelli, North Territory [macropus]
Type locality: Hermannsburg, in 23'58 S, 132° 46 E, North Territory [slateri]
license
cc-by-nc-sa-3.0
copyright
Peter Uetz
original
visit source
partner site
ReptileDB

Ctenophorus caudicinctus

provided by wikipedia EN

Ctenophorus caudicinctus, commonly known as the ring-tailed dragon or ring-tailed bicycle-dragon is a native species of agamid lizard occurring in rocky ranges and outcrops of Australia.[4][5] Ctenophorus caudicinctus is most commonly found in the Pilbara region and offshore islands of Western Australia.[6] The ctenophorus has 28 known species in the northern, southern, and western parts of Australia. It is recognized to be the most speciose group of Australian agamids.[7]

Description

Ctenophorus caudicinctus are recognized for their bright colours, their survival tactics, and sexual dimorphism. Males display brighter colours than females to make themselves more attractive to a mate. The colour of the lizard is also impacted by their age, season, and temperature of their body.[8] The ring-tailed dragon is about 25–35 cm long and is differentiated from other lizards by the line of spines that curves beneath the eyes. The pattern of the ctenophorus caudicinctus can range from a pale beige to dark orange. They have distinctive banding around the tail and a white to yellow underbelly. They have a short crest of nuchal spines that varies in colour.[9][10]

Etymology

Ctenephorus is the largest group of lizards in Australia. Ctenephorus means comb-bearing dragons and caudicinctus means ring-tailed. Many of these species have been grouped by similar morphology and have been given informal names derived from mythological creatures.[10]

Range of where ctenophorus caudicinctus can be found in Western Australia

Anatomy

Excretion

The environment in Western Australia where Ctenophorus Caudicinctus is commonly found is arid and dry.[11] Ctneophorus caudicinctus and many other lizards in dry tropics, do not produce hyperosmotic urine. The wall of the colon absorbs water and salts so that the body can retain water to prevent dehydration.[12]

Sensory characteristics

Ctenophorus caudicinctus has vestibular hearing.[13] The hair cells located in the neuroepithelial structures in the inner ear acts as receptors. They convert mechanical energy by the displacement of their surroundings into electrochemical energy.[14] The displacement of their surroundings are caused by sound waves and they use the balance of their head to perceive their surroundings.[15]

Maintenance of water

Ctenophorus caudicinctus has scale hinges that overlap each other and it creates an enclosed spaced between the scales. The scale hinges are flexible and able to stretch due to its thin layer of β-keratin in the hinge joint. These scale hinges create a smooth surface texture.[16] The water flows into the mouth and over the scales not between the scales. The purpose of this is to promote cutaneous water transport to the body. It allows water to be absorbed into the deeper layers of the body through capillary action and hinge joint channels.[17]

Osmoregulation

In spring where there is no breeding, ctenophorus caudicinctus has more sodium and potassium in their plasma and lower water influx and efflux. However, in autumn there is an increase in water metabolism. There are higher water influx and efflux but less sodium and potassium in their body. Their total body water is higher in autumn than in spring. This is due to the mating season and heavy rainfall in autumn.[18] Sodium and potassium content is important because it shows the rehydration or dehydration of any lizard. The nasal salt gland contributes to the potassium excretion for rehydration. Therefore, in autumn ctenophorus caudicinctus is more hydrated than in spring. Osmoregulation is important in lizards because of hormonal control, maintaining bodily functions and survival.[19]

Autotomy

Most lizards can regrow their tail and they can lose it voluntarily. However, most agamid lizards, including the ctenophorus caudicinctus do not lose their tail. Their tail is very thick compared to other lizards that can regrow their tail.[20] Therefore, it is hard to regenerate if they lose their tail. In addition, ctenophorus caudicinctus uses their tail for balance when they bipedal.[21]

Evolution

Ctenophorus caudicinctus is part of a large genus that shares similar phenotypes. But are still distinct from each other. Ctenophorus is a type of convergent evolution that both the ecological and biological factors that cause the evolution of a species to repeat.[22]

The ctenophorus genera have an evolution rate of approximately 1.3% divergence between lineages per million years of evolutionary separation. This rate of evolution is common in vertebrates because of their rapid reproduction, survival tactics, and natural selection.[23] The ctenophorus has two lineages that arose during the late Miocene and Pliocene. Which caused a separation of species to be separately distributed to Northern and southern parts of Australia. The ancestorial ecology of ctenophorus has features similar to the current day ctenophorus species of rock sheltering, shrub sheltering, and digging. These features are derived from a burrowing ancestor.[24] Through the geographic separation of the original dragons and different climates, the ctenophorus caudicinctus developed their own characteristics for survival.[25]

Plasticity also plays a role in the evolution of the ctenophorus caudicinctus. The ctenophorus can develop phenotypes depending on the environment that they face and have similar morphologies.[25][26] Ctenophorus caudicinctus has a larger head than other species. They have favourable limb and snout length for hunting resulting in bigger and flatter heads. Along with pressure from predators, they gained relatively long limbs to move more quickly. To manage the heat, the ctenophorus caudicinctus is lighter in colour to absorb less heat.[27]

Adaptation

The morphology of ctenophorus caudicinctus is highly impacted by their habitat. It lives in rocky ranges, whilst other species live in burrows, with no burrows, and vegetation. Therefore, the bone structure of this species adapts to its surroundings and defers from other species of the ctenophorus. Ctenophorus caudicinctus has a longer and narrower spout to catch its prey and a more flattened body to fit through horizontal spaces.[28]

Behaviour

Thermoregulation

Ctenophorus caudicinctus with pale beige body and spotting.

Thermoregulation behaviour is important for ctenophorus caudicinctus to carry out daily activities. The availability of proper thermal radiation is limited to species like ctenophorus caudicinctus because of extreme seasons.[29] Ctenophorus caudicinctus body temperature in shade is 34.2 7 °C. They start their day on the ground and move higher throughout the day. Then return to the ground at the end of the day. Their body temperatures are mostly kept cool because of higher atmospheres and less absorbance of the sun. If the weather isn't appropriate, ctenophorus caudicinctus can use psychological changes to be active during the day. It can increase their absorbance or loss of heat up to 77–87.7% through changing the colour of their skin. This would help ctenophorus caudicinctus during lower climates like spring and winter to increase their body temperature. Vise-versa, they can lower their body temperatures in hotter seasons.[24]

Retreat

Ctenophorus caudicinctus has highspeed locomotion and retreats to rocks. They have bipedalism and quadrupedalism types of retreat. Ctenophorus caudicinctus is able to be bipedal due to their morphology. Ctneophorus caudicinctus has a narrow body, long hindlimbs, short forelimbs and a long tail. These are adaptations to bipedalism.[30]

Communication

Ctenophorus caudicinctus communicates with animals and things around them through motion-based signalling. Their motion-based signalling is heavily impacted by their surroundings.[31] They can identify things through the sound, seismic, and colours. They choose to not move to blend into their surroundings to hide from predators. Therefore, their running speed is not as fast as other species in their genera. One of the ways ctenophores caudicinctus communicates with other species is being territorial and use of motor patterns to recognize other species. There are many other lizard species in their habitat that are in their genera. Therefore, the ctenophores caudicinctus' unique behaviour allows them to be able to differentiate their kind from others.[32]

Ecology

Habitat

Ctenophorus caudicinctus is found in places with low vegetation, rocky and arid. Ctenophorus caudicinctus is highly territorial.[32] They are mostly found in Hameresly ranges in Western Australia, the Pilbara, MacDonnell, James and Musgrave Ranges.[33]

Diet

Owing to the ctenophorus caudicinctus being a diurnal and saxicolous lizard species living in rocky areas, the species is insectivorous. They consume mostly arthropods, termites and ants. Occasionally they will eat some vegetative material. Termites can be found in large numbers in one spot. Ctenophorus caudicinctus needs to be wary about ant eating lizards. They eat the skin of the ants.[34] Therefore, the tail is about 170-204% snout-vent length to capture the insects in small, flat, and horizontal spaces. Ctenophorus caudicinctus primarily waits for their prey in sheltered rocks and burrows.[25] Ctenophorus caudicinctus are ambush predators. They catch their predators with strategy, rather than attacking.[35]

Effects of extreme weathers

Ctenophorus caudicinctus does not dig burrows and lives in an arid area. Therefore, it is more difficult to find shelter. Extreme weather conditions such as lightning and heavy storms that can cause fires, often kill them. Periods of limited rainfall can also be the cause of death for lizards. Too much heat causes them to be dehydrated or burns them. The lack of shade and shelter exposes ctneophorus caudicinctus to these harsh environments.[36]

Predators

Ctenophorus caudicinctus is high in abundance and has very few predators. Therefore, they are not an endangered species. Their main predators are snakes, dugites and pythons.[37]

Parasites

Ctenophorus caudicinctus has a symbiotic relationship with skrjabinoptera phrynosoma.[38] It is stomach parasite and their hosts are commonly lizards.[39]

Reproduction

Red-brown coloured ctenophorus caudicinctus

The ring tailed dragon's reproductive cycle favours conditions that are best for their survival and growth. Thus, reproductive cycles vary over the years due to rainfall and the availability of food.[8] Most commonly, ctenophorus caudicinctus breeds during spring, September to October. Then in the following months of winter, there is winter rainfall. This rainfall is important as it stimulates insect abundance to provide abundant food for ctenophorus caudicinctus. Adequate food helps with fertilization, spermatogenesis, and healthy reproduction.[40] For males, the main season for spermiogenesis is from February to August as this when they generate the maximum amount of sperm and conditions are optimal for breeding. However, some males do not mate until they are matured. They would hold it in until the next mating season.[41] Ctenophorus caudicinctus is oviparous.[42] The number of offspring is lesser than the number of eggs produced because of a lack of maternal protection.[43]

Physical attributes in mating

Physical attributes also impact how males and females mate. Males have bigger heads to assert dominance and win intrasexual competitions. In addition, colour plays an important role.[8] During mating season, males change colour adopting yellow markings on the flanks, and a dark chest patch. The yellow colour emphasizes the banding on their tails. However, they lose their original camouflage and this makes them easier to be caught by predators.[44] Bright colours and the pattern of their body makes the males more attractive. Most females have a single coloured pattern over their body, whereas males have more complex colour patterns.[45]

Brain structure and sexual selection

Ctenophorus caudicinctus has two regions in the brain that regulate sexual behaviour. These regions are the medial preoptic nucleus (MPON), which controls male reproductive behaviour, and the ventromedial hypothalamic nucleus (VMN), which controls the female reproductive behaviour and is involved in male aggression. Males have larger MPON and smaller VMN. In females they have similar MPON and VMN. The volumes of both these vertebraes are correlated to their brain volume and differ from one lizard to another.[46]

Conservation status

It is highly abundant and has no conservation significance. Ctenophorus caudicinctus are assessed as being of the least concern in the Nature Conservation Act 1992 (NCA).[47]

Subspecies

Ctenophorus caudicinctus has two subspecies:[48][49]

The subspecies of Ctenophorus caudicinctus all have the same band pattern and vary in the number of spotting and colour. Some are brighter more vibrant colours like green and red. However, Ctenophorus caudicinctus is composed of brown and dark red colours to blend into the rocky habitat.[50]

References

  1. ^ a b Melville, J.; Wilson, S.; Doughty, P.; Teale, R. (2017). "Ctenophorus caudicinctus". IUCN Red List of Threatened Species. 2017: e.T83410085A83453673. doi:10.2305/IUCN.UK.2017-3.RLTS.T83410085A83453673.en. Retrieved 20 November 2021.
  2. ^ a b "Ctenophorus caudicinctus (Günther, 1875)". Atlas of Living Australia. Retrieved 2 August 2018.
  3. ^ "Ctenophorus caudicinctus (Günther, 1875)". The Reptile Database. Retrieved 2 August 2018.
  4. ^ Australia, Atlas of Living. "Species: Ctenophorus caudicinctus (Ring-Tailed Dragon)". bie.ala.org.au. Retrieved 14 May 2021.
  5. ^ Assessment), Paul Doughty (SRLI Reptile; Wilson, Steve; Melville, Jane; Teale, Roy (22 February 2017). "IUCN Red List of Threatened Species: Ctenophorus caudicinctus". IUCN Red List of Threatened Species. Retrieved 14 May 2021.
  6. ^ Wilson, Steve (2013). A complete guide to reptiles of Australia (Fourth ed.). Chatswood, NSW, Australia. ISBN 978-1-921517-28-0. OCLC 846806238.
  7. ^ Campbell, Iain; Woods, Sam (2013). Wildlife of Australia. Princeton University Press. ISBN 978-0-691-15353-7. JSTOR j.ctt2854p5.
  8. ^ a b c Bradshaw, S.D.; Saint^Girons, H.; Bradshaw, F.J. (June 1991). "Patterns of breeding in two species of agamid lizards in the arid subtropical pilbara region of Western Australia". General and Comparative Endocrinology. 82 (3): 407–424. doi:10.1016/0016-6480(91)90316-X. PMID 1879656.
  9. ^ Stilson, Kelsey T.; Bell, Christopher J.; Mead, Jim I. (28 July 2017). "Patterns of Variation in the Cranial Osteology of Three Species of Endemic Australian Lizards (Ctenophorus: Squamata: Agamidae): Implications for the Fossil Record and Morphological Analyses made with Limited Sample Sizes". Journal of Herpetology. 51 (3): 316–329. doi:10.1670/16-152. ISSN 0022-1511.
  10. ^ a b "Western ring-tailed dragon (Ctenophorus caudicinctus) at the Australian Reptile Online Database | AROD.com.au". arod.com.au. Retrieved 14 May 2021.
  11. ^ Society, National Geographic (19 October 2011). "desert". National Geographic Society. Retrieved 14 May 2021.
  12. ^ "FAMILY AGAMIDAE", The Reptile Ear, Princeton University Press, pp. 298–323, 29 January 2019, doi:10.2307/j.ctvbcd2f0.12, ISBN 978-0-691-19666-4
  13. ^ "Vestibulo-auditory system". ebi.ac.uk. Retrieved 14 May 2021.
  14. ^ "Auditory and Vestibular Systems", The Human Nervous System, Totowa, NJ: Humana Press, pp. 285–303, 2005, doi:10.1007/978-1-59259-730-7_16, ISBN 978-1-58829-039-7, retrieved 14 May 2021
  15. ^ Carr, Catherine E.; Code, Rebecca A. (2000), Dooling, Robert J.; Fay, Richard R.; Popper, Arthur N. (eds.), "The Central Auditory System of Reptiles and Birds", Comparative Hearing: Birds and Reptiles, New York, NY: Springer New York, vol. 13, pp. 197–248, doi:10.1007/978-1-4612-1182-2_5, ISBN 978-1-4612-7036-2, retrieved 14 May 2021
  16. ^ "Fauna of Australia". Nature. 163 (4150): 758. May 1949. Bibcode:1949Natur.163U.758.. doi:10.1038/163758e0. ISSN 0028-0836.
  17. ^ Sherbrooke, Wade C.; Scardino, Andrew J.; de Nys, Rocky; Schwarzkopf, Lin (August 2007). "Functional morphology of scale hinges used to transport water: convergent drinking adaptations in desert lizards (Moloch horridus and Phrynosoma cornutum)". Zoomorphology. 126 (2): 89–102. doi:10.1007/s00435-007-0031-7. ISSN 0720-213X. S2CID 21403217.
  18. ^ Bradshaw, S. D. (1997). Homeostasis in desert reptiles. Berlin: Springer Verlag. ISBN 3-540-59264-4. OCLC 35586631.
  19. ^ Bradshaw, S.D. (February 1975). "Osmoregulation and pituitary-adrenal function in desert reptiles". General and Comparative Endocrinology. 25 (2): 230–248. doi:10.1016/0016-6480(75)90194-X. PMID 168125.
  20. ^ Lundelius, Ernest L.; Turnbull, William D. (1989). "The mammalian fauna of Madura Cave, Western Australia". Fieldiana Geology. New Series. No. 17. Chicago: Field Museum of Natural History. doi:10.5962/bhl.title.3384.
  21. ^ Clemente, Christofer J.; Withers, Philip C.; Thompson, Graham; Lloyd, David (1 July 2008). "Why go bipedal? Locomotion and morphology in Australian agamid lizards". Journal of Experimental Biology. 211 (13): 2058–2065. doi:10.1242/jeb.018044. ISSN 1477-9145. PMID 18552294.
  22. ^ Levy, Esther; Kennington, W. Jason; Tomkins, Joseph L.; LeBas, Natasha R. (1 October 2012). Steinke, Dirk (ed.). "Phylogeography and Population Genetic Structure of the Ornate Dragon Lizard, Ctenophorus ornatus". PLOS ONE. 7 (10): e46351. Bibcode:2012PLoSO...746351L. doi:10.1371/journal.pone.0046351. ISSN 1932-6203. PMC 3462208. PMID 23049697.
  23. ^ Collar, D. C.; Schulte, J. A.; O'Meara, B. C.; Losos, J. B. (May 2010). "Habitat use affects morphological diversification in dragon lizards". Journal of Evolutionary Biology. 23 (5): 1033–1049. doi:10.1111/j.1420-9101.2010.01971.x. PMC 2878605. PMID 20345808.
  24. ^ a b Melville, Jane; Schulte, James A.; Larson, Allan (2001). "A molecular phylogenetic study of ecological diversification in the Australian lizard genusCtenophorus". Journal of Experimental Zoology. 291 (4): 339–353. doi:10.1002/jez.1133. ISSN 0022-104X. PMID 11754013.
  25. ^ a b c Melville, Jane; Harmon, Luke J; Losos, Jonathan B (7 March 2006). "Intercontinental community convergence of ecology and morphology in desert lizards". Proceedings of the Royal Society B: Biological Sciences. 273 (1586): 557–563. doi:10.1098/rspb.2005.3328. ISSN 0962-8452. PMC 1560059. PMID 16537126.
  26. ^ Journal of Experimental Zoology Part B: Molecular and Developmental Evolution. 332 (6). 2 May 2019. doi:10.1002/jezb.b.v332.6. ISSN 1552-5007. {{cite journal}}: Missing or empty |title= (help)
  27. ^ Feiner, Nathalie; Jackson, Illiam SC; Munch, Kirke L; Radersma, Reinder; Uller, Tobias (13 August 2020). "Plasticity and evolutionary convergence in the locomotor skeleton of Greater Antillean Anolis lizards". eLife. 9: e57468. doi:10.7554/eLife.57468. ISSN 2050-084X. PMC 7508556. PMID 32788040.
  28. ^ Thompson, Graham; Withers, Philip (2005). "The relationship between size-free body shape and choice of retreat for Western Australian Ctenophorus (Agamidae) dragon lizards". Amphibia-Reptilia. 26 (1): 65–72. doi:10.1163/1568538053693323. ISSN 0173-5373.
  29. ^ Smith, Kathleen R.; Cadena, Viviana; Endler, John A.; Porter, Warren P.; Kearney, Michael R.; Stuart-Fox, Devi (15 June 2016). "Colour change on different body regions provides thermal and signalling advantages in bearded dragon lizards". Proceedings of the Royal Society B: Biological Sciences. 283 (1832): 20160626. doi:10.1098/rspb.2016.0626. ISSN 0962-8452. PMC 4920320.
  30. ^ Clemente, Christofer J.; Withers, Philip C.; Thompson, Graham; Lloyd, David (1 July 2008). "Why go bipedal? Locomotion and morphology in Australian agamid lizards". Journal of Experimental Biology. 211 (13): 2058–2065. doi:10.1242/jeb.018044. ISSN 1477-9145. PMID 18552294.
  31. ^ Witter, Geoffrey. "FAUNA of Australia" (PDF). 26: 26–30. {{cite journal}}: Cite journal requires |journal= (help)
  32. ^ a b Ramos, Jose A.; Peters, Richard A. (August 2017). "Motion-based signaling in sympatric species of Australian agamid lizards". Journal of Comparative Physiology A. 203 (8): 661–671. doi:10.1007/s00359-017-1185-5. ISSN 0340-7594. PMID 28573349. S2CID 43838080.
  33. ^ Wilson, Steve (2012). Australian lizards : a natural history. Collingwood, Vic.: CSIRO Pub. ISBN 978-0-643-10641-3. OCLC 794058548.
  34. ^ Pianka, Eric R.; Pianka, Helen D. (2 March 1970). "The Ecology of Moloch horridus (Lacertilia: Agamidae) in Western Australia". Copeia. 1970 (1): 90. doi:10.2307/1441978. JSTOR 1441978.
  35. ^ "Encyclopedia of Life". eol.org. Retrieved 14 May 2021.
  36. ^ Light, Paul; Dawson, William R.; Shoemaker, Vaughan H.; Main, A. R. (22 March 1966). "Observations on the Thermal Relations of Western Australian Lizards". Copeia. 1966 (1): 97. doi:10.2307/1440766. JSTOR 1440766.
  37. ^ "Herpetological Review". Society for the Study of Amphibians and Reptiles. 8 November 2016. Retrieved 14 May 2021.
  38. ^ "Taxonomy browser (Ctenophorus caudicinctus)". ncbi.nlm.nih.gov. Retrieved 14 May 2021.
  39. ^ Zoological Society of London. (1833). Proceedings of the Zoological Society of London. London: Academic Press, [etc.]
  40. ^ On the ecology of Australia's arid zone. H. Lambers. Cham, Switzerland. 2018. ISBN 978-3-319-93943-8. OCLC 1049568222.{{cite book}}: CS1 maint: others (link)
  41. ^ Goldberg, Stephen (1 January 2009). "Male cycle of the military sand-dragon Ctenophorus isolepis, from Western Australia". Herpetofauna. 39: 43–45 – via ResearchGate.
  42. ^ "Ctenophorus caudicinctus". The Reptile Database. Retrieved 14 May 2021.
  43. ^ "Oviparity | biology". Encyclopædia Britannica. Retrieved 14 May 2021.
  44. ^ "Spinelesswonders". spinelesswonders.smugmug.com. Retrieved 14 May 2021.
  45. ^ Chen, I-Ping; Stuart-Fox, Devi; Hugall, Andrew F.; Symonds, Matthew R. E. (November 2012). "Sexual Selection and the Evolution of Complex Color Patterns in Dragon Lizards". Evolution. 66 (11): 3605–3614. doi:10.1111/j.1558-5646.2012.01698.x. PMID 23106722. S2CID 14242593.
  46. ^ Hoops, D.; Ullmann, J. F. P.; Janke, A. L.; Vidal-Garcia, M.; Stait-Gardner, T.; Dwihapsari, Y.; Merkling, T.; Price, W. S.; Endler, J. A.; Whiting, M. J.; Keogh, J. S. (February 2017). "Sexual selection predicts brain structure in dragon lizards". Journal of Evolutionary Biology. 30 (2): 244–256. doi:10.1111/jeb.12984. ISSN 1420-9101. PMID 27696584.
  47. ^ Department of Environment and Science (20 October 2014). "Species profile | Environment, land and water". apps.des.qld.gov.au. The State of Queensland. Retrieved 14 May 2021.
  48. ^ Cogger, H. (2000) Reptiles and Amphibians of Australia, Reed New Holland, Sydney, New South Wales, ISBN 1876334339
  49. ^ Wilson, S., Swan, G. (2013) A Complete Guide to Reptiles of Australia, New Holland Publishers, Sydney, New South Wales, ISBN 9781921517280
  50. ^ Melville, Jane; Haines, Margaret L.; Hale, Joshua; Chapple, Stephanie; Ritchie, Euan G. (2016). "Concordance in phylogeography and ecological niche modelling identify dispersal corridors for reptiles in arid Australia". Journal of Biogeography. 43 (9): 1844–1855. doi:10.1111/jbi.12739. ISSN 1365-2699.
license
cc-by-sa-3.0
copyright
Wikipedia authors and editors
original
visit source
partner site
wikipedia EN

Ctenophorus caudicinctus: Brief Summary

provided by wikipedia EN

Ctenophorus caudicinctus, commonly known as the ring-tailed dragon or ring-tailed bicycle-dragon is a native species of agamid lizard occurring in rocky ranges and outcrops of Australia. Ctenophorus caudicinctus is most commonly found in the Pilbara region and offshore islands of Western Australia. The ctenophorus has 28 known species in the northern, southern, and western parts of Australia. It is recognized to be the most speciose group of Australian agamids.

license
cc-by-sa-3.0
copyright
Wikipedia authors and editors
original
visit source
partner site
wikipedia EN