The tuco-tuco is a neotropical rodent in the family Ctenomyidae. The tuco-tucos belong to the only living genus of the Ctenomyidae family, Ctenomys, but they include approximately 60 different species. The common name, "tuco-tuco" comes from the "tuc-tuc" sound they make while they dig their burrows.
The relationships among the species are debated by taxonomists. It has been described that they are in a state of "taxonomic chaos," but banded karyotypes have been used to help make progress on their taxonomic study. Their closest relatives are degus and other octodontids. All species of tuco-tucos are found in South America from Peru and central Brazil southward. The tuco-tucos of South America have an ecological role equivalent to that of the pocket gophers of North America.
Tuco-tucos have heavily built cylindrical bodies with short legs and their pelage ranges in color from black to light grey. Their skin is loosely applied, possibly to slide about the tunnels they create. They have long fore feet for burrowing, and bristled hind feet for grooming. They also have large heads, small ears, and hairy tails. Their bodies range in size from Script error: No such module "convert". in length, and they can weigh as little as 100 grams (C. pundti) to more than 1000 grams (C. conover).
Members of the genus Ctenomys are widely distributed, but over 50 of the species are found in the southern half of South America. They can be seen in many areas from the southern portion of Peru and southern Brazil to the Tierra del Fuego at the southernmost tip of South America, through parts of Chile and a majority of Uruguay, Paraguay, Bolivia, and Argentina. Their ranges occur from coastal grasslands to mountain slopes, including the Andean Puna at over 4000 meters, and depend on factors such as soil type, ambient temperature, and primary productivity. The only sympatric distribution of this genus occurs between C. australis and C. talarum in a coastal dune region.
Tuco-tucos live in excavated burrows and spend a majority (up to 90%) of their lives underground. It is estimated that they represent about 45% of all the underground rodents of the world. Their burrows maintain a fairly constant temperature and humidity level that is independent of the geographic region. In order to excavate the soil, they have many morphological adaptations, including their body shape, reduced eyes, and strong limbs. Their olfaction is increased and is used to help orient themselves during digging and establishing a territory. The two techniques they use for digging are scratch-digging and skull-tooth digging. A combination of the two methods are often used. Their claws and forelimbs are used primarily for scratch-digging, and their skull and incisor teeth are used secondarily for skull-tooth digging.
Tuco-tucos are diurnal and alternate periods of activity and periods of rest throughout the day.
They primarily search for food by digging passageways. Due to the high energy cost of foraging for food, their diet is rather broad.
Very little is known about the courtship of the tuco-tucos, as it takes place underground inside their burrows. It is known that the male takes an aggressive posture and exchanges chemical or acoustic signals with the female.
Among their most notable features is that various members of the genus exhibit differing levels of genetic variability and sociality. Most of these species are solitary animals, however some are semisocial or social, with a tendency for the most social species (e.g. C. sociabilis) to have the least genetic variation.
While the processes behind its diversification are unknown, it has been suggested that they are among the most diversely speciated genus of mammals, largely due to chromosomal rearrangements and rapid speciation since their appearance in the late Pliocene or early Pleistocene era. Their chromosomal diversity is so impressive because their diploid numbers range from 10 to 70.
The species in this genus are at risk of predation by humans because they are viewed as agricultural pests.
- Anderson's cujuchi (C. andersoni)
- Argentine tuco-tuco (C. argentinus)
- Azara's tuco-tuco (C. azarae)
- Berg's tuco-tuco (C. bergi)
- Bolivian tuco-tuco (C. boliviensis)
- Bonetto's tuco-tuco (C. bonettoi)
- Brazilian tuco-tuco (C. brasiliensis)
- Budin's tuco-tuco (C. budini)
- Catamarca tuco-tuco (C. knighti)
- Chacoan tuco-tuco (C. dorsalis)
- Colburn's tuco-tuco (C. colburni)
- Collared tuco-tuco (C. torquatus)
- Conover's tuco-tuco (C. conoveri)
- Coyhaique tuco-tuco (C. coyhaiquensis)
- D'Orbigny's tuco-tuco (C. dorbignyi)
- Emily's tuco-tuco (C. emilianus)
- Erika’s tuco-tuco (C. erikacuellarae)
- Famatina tuco-tuco (C. famosus)
- Flamarion's tuco-tuco (C. flamarioni)
- Foch's tuco-tuco (C. fochi)
- Forest tuco-tuco (C. sylvanus)
- Furtive tuco-tuco (C. occultus)
- Goodfellow's tuco-tuco (C. goodfellowi)
- Goya tuco-tuco (C. perrensi)
- Haig's tuco-tuco (C. haigi)
- Highland tuco-tuco (C. opimus)
- Jujuy tuco-tuco (C. juris)
- Lago Blanco tuco-tuco (C. fodax)
- Lami tuco-tuco (C. lami)
- Lessa's tuco-tuco (C. lessai)
- Lewis's tuco-tuco (C. lewisi)
- Magellanic tuco-tuco (C. magellanicus)
- Maule tuco-tuco (C. maulinus)
- Mendoza tuco-tuco (C. mendocinus)
- Mottled tuco-tuco (C. latro)
- Natterer's tuco-tuco (C. nattereri)
- Pearson's tuco-tuco (C. pearsoni)
- Peruvian tuco-tuco (C. peruanus)
- Pilar tuco-tuco (C. pilarensis)
- Porteous's tuco-tuco (C. porteousi)
- Pundt's tuco-tuco (C. pundti)
- Puntilla tuco-tuco (C. coludo)
- Reddish tuco-tuco (C. frater)
- Reig's tuco-tuco (C. osvaldoreigi)
- Rio Negro tuco-tuco (C. rionegrensis)
- Robust tuco-tuco (C. tuconax)
- Roig's tuco-tuco (C. roigi)
- Salta tuco-tuco (C. saltarius)
- San Juan tuco-tuco (C. johannis)
- San Luis tuco-tuco (C. pontifex)
- Scaglia's tuco-tuco (C. scagliai)
- Sierra Tontal tuco-tuco (C. tulduco)
- Silky tuco-tuco (C. sericeus)
- Social tuco-tuco (C. sociabilis)
- Southern tuco-tuco (C. australis)
- Steinbach's tuco-tuco (C. steinbachi)
- Strong tuco-tuco (C. validus)
- Talas tuco-tuco (C. talarum)
- Tawny tuco-tuco (C. fulvus)
- Tiny tuco-tuco (C. minutus)
- Tucuman tuco-tuco (C. tucumanus)
- Vipos tuco-tuco (C. viperinus)
- White-toothed tuco-tuco (C. leucodon)
- Yates' tuco-tuco (C. yatesi)
- Yolanda's tuco-tuco (C. yolandae)
- Woods, C. A.; Kilpatrick, C. W. (2005). "Genus Ctenomys". In Wilson, D. E.; Reeder, D. M. Mammal Species of the World (3rd ed.). Johns Hopkins University Press. pp. 1560–1570. ISBN 978-0-8018-8221-0. OCLC 62265494.
- Parada, A., G. D’Elia, C.J. Bidau, and E.P. Lessa. 2011. Species Groups and the Evolutionary Diversification of Tuco-Tucos, genus Ctenomys (Rodentia: Ctenomyidae). Journal of Mammalogy 92(3): 671-682.
- Anonymous. 2013. "Southern Tuco-tuco (Ctenomys australis)." ARKive. 04 Oct. 2013. http://www.arkive.org/southern-tuco-tuco/ctenomys-australis/
- Lessa, E. 1998. The Molecular Phylogenetics of Tuco-Tucos (genus Ctenomys, Rodentia: Octodontidae) Suggests an Early Burst of Speciation. Molecular Phylogenetics and Evolution 9(1): 88-99.
- Bishop, Ian (1984). Macdonald, D., ed. The Encyclopedia of Mammals. New York: Facts on File. pp. 702–703. ISBN 0-87196-871-1.
- Luna, F. and C. Antinuchi. 2007. Energy and Distribution in Subterranean Rodents: Sympatry between Two Species of the Genus Ctenomys. Comparative Biochemistry and Physiology - Part A: Molecular & Integrative Physiology 147(4): 948-954.
- Cutrera, A.P., M.S. Mora, C.D. Antenucci, and A.I. Vassallo. 2010. Intra- and Interspecific Variation in Home-range Size in Sympatric Tuco-Tucos, Ctenomys australis and C. talarum. Journal of Mammalogy 91(6): 1,425-1,434
- Castillo, A.H., M.N. Cortinas, and E.P. Lessa. 2005. Rapid Diversification of South American Tuco-Tucos (Ctenomys: Rodentia: Ctenomyidae): Contrasting Mitochondrial and Nuclear Intron Sequences. Journal of Mammalogy 86(1): 170-179.
- Medina, A.I., D.A. Marti, and C.J. Bidau. 2007. Subterranean Rodents of the Genus Ctenomys (Caviomorpha: Ctenomyidae) Follow the Converse to Bergmann’s Rule. Journal of Biogeography 34: 1,439-1,454.
- Steiner-Souza, F., T.R.O. De Freitas, and P. Cordeiro-Estrela. 2010. Inferring Adaptation within Shape Diversity of the Humerus of Subterranean Rodent Ctenomys. Biological Journal of the Linnean Society 100(2): 353-367.
- Vassallo, A.I., and A.I. Echeverría. 2009. Evolution of Brain Size in a Highly Diversifying Lineage of Subterranean Rodent Genus Ctenomys (Caviomorpha: Ctenomyidae). Brain, Behavior and Evolution 73(2): 138-149.
- Comparatore, V.M., M.S. Cid, and C. Busch. 1995. Dietary Preferences of Two Sympatric Subterranean Rodent Populations in Argentina. Revista Chileana de Historia Natural 68: 197-206.
- Lacey, E.A. and J.R. Wieczorek. 2003. The ecology of sociality in rodents: a ctenomyid perspective. Journal of Mammalogy 84: 1,198-1,211
- Lacey, E.A. 2001. Microsatellite variation in solitary and social tuco-tucos: molecular properties and population dynamics. Heredity 86: 628-637
- Fernandes, F., G. Fernández-Stolz, C. Lopes, and T. De Freitas. 2007. The Conservation Status of the Tuco-Tucos, Genus Ctenomys (Rodentia: Ctenomyidae), in Southern Brazil. Brazilian Journal of Biology 67(4): 839-847.
- Gardner, S.L., J. Salazar-Bravo, and J.A. Cook. 2014. New Species of Ctenomys Blainville 1826 (Rodentia: Ctenomyidae) from the Lowlands and Central Valleys of Bolivia. Special Publications / Museum of Texas Tech University (June 17, 2014), number 62.
|40x40px||Wikispecies has information related to: Ctenomys|
|40x40px||Wikimedia Commons has media related to Ctenomys.|