Iberian ribbed newt

Iberian ribbed newt
Pleurodeles waltl in an aquarium.
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Amphibia
Order: Urodela
Family: Salamandridae
Genus: Pleurodeles
Species: P. waltl
Binomial name
Pleurodeles waltl
Michahelles, 1830
Distribution in the Iberian peninsula and the Maghreb
Synonyms

'Pleurodeles waltlii (incorrect spelling)

The Iberian ribbed newt or Spanish ribbed newt (Pleurodeles waltl) is a newt endemic to the central and southern Iberian Peninsula and Morocco.[2] It is known for its sharp ribs which can puncture through its sides, and as such is also called the sharp-ribbed newt.

Description

The Iberian ribbed newt has tubercles running down each side. Through these, its sharp ribs can puncture. The ribs act as a defense mechanism, causing little harm to the newt. This mechanism could be considered as a primitive and rudimentary system of inoculation,[3] but is completely harmless to humans.[4] At the same time as pushing its ribs out the newt begins to secrete poison from special glands on its body. The poison coated ribs create a highly effective stinging mechanism, injecting toxins through the thin skin in predator’s mouths. The newt’s effective immune system and collagen coated ribs mean the pierced skin quickly regrows without infection.[5]

In the wild, this amphibian grows up to 30 cm (12 in), but rarely more than 20 cm (7.9 in) in captivity. Its color is dark gray dorsally, and lighter gray on its ventral side, with rust-colored small spots where its ribs can protrude. This newt has a flat, spade-shaped head and a long tail, which is about half its body length. Males are more slender and usually smaller than females. The larvae have bushy external gills and usually paler color patterns than the adults.

P. waltl is more aquatic-dwelling than many other European tailed amphibians. Though they are quite able to walk on land, most rarely leave the water, living usually in ponds, cisterns, and ancient village wells that were common in Portugal and Spain in the past. They prefer cool, quiet, and deep waters, where they feed on insects, worms, and tadpoles.

Sex determination

Sex determination is regulated by sex chromosomes, but can be overridden by temperature. Females have both sex chromosomes (Z and W), while males have two copies of the Z chromosome (ZZ). However, when ZW larvae are reared at 32°C (90°F) during particular stages of development (stage 42 to stage 54), they differentiate into functional neomales. Hormones play an important role during the sex determination process, and the newts can be manipulated to change sex by adding hormones or hormone-inhibitors to the water in which they are reared.[6]

Aromatase, an estrogen-synthesizing enzyme which acts as a steroid hormone, plays a key role in sex determination in many nonmammalian vertebrates, including the Iberian ribbed newt.[6] It is found in higher levels in the gonad–mesonephros complexes in ZW larvae than in their ZZ counterparts, although not in heat-treated ZW larvae. The increase occurs near the final stages of which their sex can be determined by temperature (stage 52).

Conservation

The IUCN has listed the Iberian ribbed newt as Near Threatened since its 2006 Red List. It received this listing because its wild populations appear to be in significant decline due to widespread habitat loss and the effects of invasive species, thus making the species close to qualifying for Vulnerable. Previously, in 2004, the species had been listed as Least Concern, the lowest ranking. This species is generally threatened through loss of aquatic habitats through drainage, agrochemical pollution, the impacts of livestock (in North African dayas), eutrophication, domestic and industrial contamination, golf courses, and infrastructure development. It has largely disappeared from coastal areas in Iberia and Morocco close to concentrations of tourism and highly populated areas such as Madrid's outskirts. Introduced fish such as the largemouth bass and crayfish (Procambarus clarkii) are known to prey on the eggs and larvae of this species, and are implicated in its decline. Mortality on roads has been reported to be a serious threat to some populations.[1]

Space experiments

A bion satellite, like the Bion 7 spacecraft which first carried the Iberian ribbed newt into space in 1985

Pleurodeles waltl has been studied in space on at least six missions. The first Iberian ribbed newts in space may have been in 1985 on board Bion 7.[7] The ten newts shared their journey with two rhesus macaques and ten rats, in an otherwise crewless Soviet Kosmos satellite. In 1992, Bion 10[8][9] also carried the newts on board, as did Bion 11[10] in 1996.

P. waltl research was continued later in 1996 by French-led experiments on the Mir space station (Mir Cassiopée expedition[11]), with follow-up studies in 1998 (Mir Pégase expedition) and 1999 (Mir Perseus expedition). Foton-M2[12] also carried the Iberian ribbed newt in 2005.

Iberian ribbed newts in an aquarium (on Earth)

The newts were chosen because they are a good model organism for the study of microgravity.[13] They are a good model organism because of the female's ability to retain live sperm in her cloaca for up to five months, allowing her to be inseminated on Earth, and later (in space) have fertilisation induced through hormonal stimulation. Another advantage to this species is their development is slow, so all the key stages of ontogenesis can be observed, from the oocyte to swimming tailbud embryos or larvae.

Studies looked at the newts' ability to regenerate (which was faster in space overall, and up to two times as fast in early stages,[14]) as well as the stages of development and reproduction in space.[15]

On the ground, studies of hypergravity (up to 3g) on P. waltl fertilisation have also been conducted,[16] as well as on the fertility of the space-born newts once they arrived back on Earth (they were fertile, and without problems).[17]

Other amphibian species to travel in space include the newt species Lissotriton vulgaris and Cynops pyrrhogaster, and the African clawed frog, the Japanese tree frog, Rana pipiens, Rana catesbeiana, and Rana temporaria.

See also

References

  1. 1 2 Pedro Beja, Jaime Bosch, Miguel Tejedo, Paul Edgar, David Donaire-Barroso, Miguel Lizana, Iñigo Martínez-Solano, Alfredo Salvador, Mario García-París, Ernesto Recuero Gil, Tahar Slimani , El Hassan El Mouden, Philippe Geniez, Tahar Slimani (2004). "Pleurodeles waltl". IUCN Red List of Threatened Species. Version 2014.3. International Union for Conservation of Nature. Retrieved 11 March 2015.
  2. Frost, Darrel R. (2014). "Pleurodeles waltl Michahelles, 1830". Amphibian Species of the World: an Online Reference. Version 6.0. American Museum of Natural History. Retrieved 11 March 2015.
  3. Bruna Azara, C. 1995. Animales venenosos. Vertebrados terrestres venenosos peligrosos para el ser humano en España. Bol. SEA, 11: 32-40.
  4. Bruna Azara, C. 1995. Animales venenosos. Vertebrados terrestres venenosos peligrosos para el ser humano en España. Bol. SEA, 11: 32-40 .
  5. http://cabinetoffreshwatercuriosities.com/2010/11/11/spanish-ribbed-newt/ Spanish ribbed newt - Pleurodeles waltl, The BioFresh Cabinet of Freshwater Curiosities
  6. 1 2 Kuntz, Sandra; Amand Chesnel; Stéphane Flament; Dominique Chardard (2004). "Cerebral and gonadal aromatase expressions are differently affected during sex differentiation of Pleurodeles waltl". Journal of Molecular Endocrinology 33: 717–727. doi:10.1677/jme.1.01588.
  7. Mitashov, V.; et al. Lens and limb regeneration in newt during and after 13-day long spaceflight
  8. Grinfeld, S.; et al. Tissue regeneration in space (spinal cord, muscle and bone) in the amphibian Pleurodeles waltl. Life Sciences Research in Space, ESA SP-366. European Space Agency, 1994., p.181
  9. Experience Triton on BION-10: Study of peptidase-1 expression in embarked Pleurodeles females and detection of genetic abnormalities in their progeny
  10. Grigoryan, E. N, et al. Urodelean amphibians in studies on microgravity: effects upon organ and tissue regeneration. Advances in Space Research, Volume 30, Issue 4, p. 757-764.
  11. http://www.blackwell-synergy.com/doi/abs/10.1046/j.1440-169x.2001.00575.x
  12. Domaratskaya et al., Studies on hemopoietic tissue of ribbed newt, Pleurodeles waltl, after the flight on board Russian satellite "Foton-M2" in 2005
  13. Gualandris-Parisot L, et al. Adv Space Res. 2001;28(4):569-78. Pleurodeles waltl, amphibian, Urodele, is a suitable biological model for embryological and physiological space experiments on a vertebrate.
  14. Grigoryan EN, Mitashov VI, Anton HJ. Urodelean amphibians in studies on microgravity: effects upon organ and tissue regeneration. Adv Space Res. 2002;30(4):757-64.
  15. Dournon C & Houillon C 1985 Thermosensibilité de la différenciation sexuelle chez l’Amphibien Urodè le, Pleurodeles waltlii Michah. Conditions pour obtenir l’inversion du phénotype sexuel de toutes les femelles génétiques sous l’action de la température d’élevage. Reproduction Nutrition Développement 25 671–688.
  16. Aimar C, et al. (2000). "Microgravity and hypergravity effects on fertilization of the salamander Pleurodeles waltl (urodele amphibian)". Biology of Reproduction 63 (2): 551–558. doi:10.1095/biolreprod63.2.551.
  17. Dournon C, Durand D, Tankosic C, Membre H, Gualandris-Parisot L, Bautz A (2001). "Effects of microgravity on the larval development, metamorphosis and reproduction of the urodele amphibian Pleurodeles waltl". Development, Growth & Differentiation 43 (3): 315–326. doi:10.1046/j.1440-169x.2001.00575.x.

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