Carphodactylidae
Carphodactylidae | |
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Barking gecko (Underwoodisaurus milii) | |
Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Animalia |
Phylum: | Chordata |
Class: | Reptilia |
Order: | Squamata |
Superfamily: | Pygopodoidea |
Family: | Carphodactylidae Kluge, 1967 |
Genera | |
Seven, see text. |
The Carphodactylidae, informally known as the southern padless geckos,[1] are a family of geckos, lizards in the infraorder Gekkota. The family consists of 32 described species in 7 genera, all of which are endemic to Australia. They belong to the superfamily Pygopodoidea (or Diplodactyloidea), an ancient group of east Gondwanan geckos now only found in Australasia. Despite their well-developed limbs, molecular phylogenies have demonstrated that Carphodactylidae is the sister group to Pygopodidae, a highly specialized family of legless lizards.[2][3]
Carphodactylids, despite being the most species-poor family of geckos, are still diverse in habits. Many have unusual, specialized tails with reduced rates of autotomy. They lack adhesive toepads and instead cling to bark or substrate with sharply curved claws and a limited array of lamellae. Carphodactylids are relatively large by gecko standards; most are nocturnal and all are oviparous, with a typical clutch size of two eggs. Unlike most Australian geckos, species diversity is concentrated in humid forests along the northeastern edge of Australia. Nevertheless, some genera are diverse in arid regions as well.[2][4][1][3][5]
Genera
The following genera are considered members of the Carphodactylidae:[6][2][7]
Genus | Image | Type species | Taxon author | Common name | Species |
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Carphodactylus | C. laevis |
C. laevis Günther, 1897 | Günther, 1897 | Chameleon gecko | 1 |
Nephrurus | N. laevissimus |
N. asper Günther, 1876 | Günther, 1876 | Knob-tailed geckos | 10 |
Orraya | O. occultus (Couper, Covacevich, & Moritz, 1993) | Couper, Covacevich, Schneider & Hoskin, 2000 | Long-necked northern leaf-tailed gecko | 1 | |
Phyllurus | P. nepthys |
P. platurus (Shaw, 1790) | Schinz, 1822 | Australian leaf-tailed geckos | 10 |
Saltuarius | S. swaini |
S. cornutus (Ogilby, 1892) | Couper, Covacevich, & Moritz, 1993 | Australian leaf-tailed geckos | 7 |
Underwoodisaurus | U. milii |
U. milii (Bory de Saint-Vincent, 1825) | Wermuth, 1965 | Thick-tailed or barking geckos | 2 |
Uvidicolus | U. sphyrurus (Ogilby, 1892) | Oliver & Bauer, 2011 | Border thick-tailed gecko | 1 |
Classification
Historical usage (Carphodactylini)
Members of the family now known as Carphodactylidae were first grouped together in Kluge (1967)’s reconfiguration of gecko systematics. He named a tribe, Carphodactylini, which included Carphodactylus, Nephrurus, and Phyllurus ("padless carphodactylins") as close relatives in a subgroup. The tribe also included Pseudothecadactylus and all New Zealand and New Caledonian geckos ("padded carphodactylins") in another subgroup. Carphodactylini was diagnosed by a large patch of preanal pores formed by multiple rows, though these pores were noted as vestigial in Nephrurus and absent in Phyllurus.[8]
Under Kluge’s classification scheme, Carphodactylini was the sister group to Diplodactylini, which contained other Australian legged geckos. Both tribes formed the subfamily Diplodactylinae within the family Pygopodidae, alongside the legless lizards of the subfamily Pygopodinae. "Padless carphodactylins" (particularly Carphodactylus) were considered the most primitive and generalized members of Carphodactylini, and by extension Diplodactylinae.[8] A morphological phylogenetic analysis by Bauer (1990) generally supported Kluge’s classification scheme, though the ingroup relations of carphodactylins was very different.[9]
Summary of Kluge's classification scheme:[8][9]
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Results of Bauer, 1990:[9]
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However, the monophyly and structure of Carphodactylini (as defined by morphological traits) started to become unclear once molecular phylogenies were developed. King (1987) found that Nephrurus and Phyllurus apparently retained an ancestral chromosome structure, but that Carphodactylus, "padded carphodactylins", and several species of Oedura (a supposed diplodactylin) shared a derived structure, necessitating a major revision of Kluge’s structure.[10] However, there is much debate over whether chromosomes are useful for inferring gecko systematics.[9][11][12] Donnellan et al. (1999) estimated gecko relationships using C-mos, a nuclear gene conserved throughout squamates. Their results considered Carphodactylini to be a paraphyletic assemblage, with Rhacodactylus and Pseudothecadactylus incrementally closer to diplodactylins (including Oedura).[13]
Simplified results of Donnellan et al., 1999, focusing on Australasian geckos:[13]
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Modern usage (Carphodactylidae)
Carphodactylidae, in its present-day usage, was codified by Han et al. (2004). They expanded on the study of Donnellan et al. (1999), and found that Carphodactylini and Diplodactylinae, as previously used, were polyphyletic. "Padless carphodactylins" formed a clade sister to pygopodines, while "padded carphodactylins" formed a grade of geckos basal to diplodactylins. This prompted several renames of major clades. The clade of "padless carphodactylins" was given the new family Carphodactylidae, while the family Diplodactylidae was erected to encompass traditional diplodactylins and "padded carphodactylins". The family Pygopodidae was basically restricted to the legless pygopodines, and subsequent studies would rename the Australasian radiation to Pygopodoidea or Diplodactyloidea.[6]
Simplified results of Han et al., 2004, using new names as defined in the study:[6]
Gekkota |
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Although placing carphodactylids sister to pygopodids was an unusual result, nearly all subsequent molecular phylogenies have supported it.[2][3] Shared morphological traits are scant, but the two families both have an unusually complex squamosal with its lower end wrapping around the rear branch of the parietal.[14] Oliver & Bauer (2011) looked into carphodactylid ingroup relationships in more depth using an analysis based on C-mos along with RAG1 (a nuclear gene) and ND2 (a mitochondrial gene). They had difficulty with resolving the base of Carphodactylidae, but strongly supported the erection of a new genus, Uvidicolus.[2] Skipwith et al. (2019) found a different result while running phylogenetic analyses on 4268 ultra-conserved elements (UCEs) in diplodactyloid geckos. Their analysis placed Orraya as the earliest-diverging carphodactylid, suggesting that the ancestral habit for the family may have been similar to the cryptic leaf-tailed genera (Orraya, Phyllurus, Saltuarius).[3]
Simplified results of the combined nuclear and mitochondrial analysis of Oliver & Bauer, 2011:[2] |
Simplified results of Skipwith et al., 2019:[3]
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References
- ^ a b Cogger, Harold G. (2014). Reptiles and Amphibians of Australia (7 ed.). Clayton South VIC: CSIRO Publishing.
- ^ a b c d e f Oliver PM, Bauer AM (2011). "Systematics and evolution of the Australian knob-tail geckos (Nephrurus, Carphodactylidae, Gekkota): plesiomorphic grades and biome shifts through the Miocene". Molecular Phylogenetics and Evolution 59 (3): 664-674. ISSN 1055-7903 doi:10.1016/j.ympev.2011.03.018
- ^ a b c d e Skipwith, Phillip L.; Bi, Ke; Oliver, Paul M. (2019-11-01). "Relicts and radiations: Phylogenomics of an Australasian lizard clade with east Gondwanan origins (Gekkota: Diplodactyloidea)". Molecular Phylogenetics and Evolution. 140 (106589): 106589. doi:10.1016/j.ympev.2019.106589. ISSN 1055-7903. PMID 31425788.
- ^ Vitt, Laurie J.; Caldwell, Janalee P. (2014). Herpetology: An Introductory Biology of Amphibians and Reptiles. Elsevier. ISBN 9780123869203.
- ^ Rodda, Gordon H. (2020). Lizards of the World : Natural History and Taxon Accounts. Baltimore: Johns Hopkins University Press. ISBN 9781421438238.
- ^ a b c Han D, Zhou K, Bauer AM (2004). "Phylogenetic relationships among gekkotan lizards inferred from c-mos nuclear DNA sequences and a new classification of the Gekkota". Biological Journal of the Linnean Society 83: 353– 368. doi:10.1111/j.1095-8312.2004.00393.x
- ^ "Search results | The Reptile Database". reptile-database.reptarium.cz. Retrieved 2021-06-20.
- ^ a b c Kluge, A.G. (1967). "Systematics, phylogeny, and zoogeography of the lizard genus Diplodactylus Gray (Gekkonidae)". Australian Journal of Zoology. 15 (5): 1007–1108. doi:10.1071/ZO9671007.
- ^ a b c d Bauer, Aaron M. (1990). "Phylogenetic systematics and biogeography of the Carphodactylini (Reptilia: Gekkonidae)". Bonner Zoologische Monographien. 30: 1–217.
- ^ King, M. (1987). "Chromosomal Evolution in the Diplodactylinae (Gekkonidae, Reptilia) .1. Evolutionary Relationships and Patterns of Change". Australian Journal of Zoology. 35 (5): 507–531. doi:10.1071/zo9870507. ISSN 1446-5698.
- ^ Kluge, Arnold G. (1994). "Principles of phylogenetic systematics and the informativeness of the karyotype in documenting Gekkotan lizard relationships". Herpetologica. 50 (2): 210–221. JSTOR 3893026.
- ^ King, Max (1994). "Unbuckling the Cladistic Straight Jacket: An Exercise in Elementary Cytogenetics and a Reply to Kluge (1994)". Herpetologica. 50 (2): 222–237. JSTOR 3893027.
- ^ a b DONNELLAN, STEPHEN C.; HUTCHINSON, MARK N.; SAINT, KATHLEEN M. (1999-05-01). "Molecular evidence for the phylogeny of Australian gekkonoid lizards". Biological Journal of the Linnean Society. 67 (1): 97–118. doi:10.1111/j.1095-8312.1999.tb01932.x. ISSN 0024-4066.
- ^ Daza, Juan D.; Bauer, Aaron M. (2012). "Temporal Bones of the Gekkota Support Molecular Relationships within the Pygopodoidea". Journal of Herpetology. 46 (3): 381–386. doi:10.1670/11-183. JSTOR 23326909. S2CID 84547300.