Tardigrade

From Wikipedia, the free encyclopedia
Tardigrade
Temporal range: Cambrian–Recent[1]
The tardigrade Hypsibius dujardini
Scientific classification
Kingdom: Animalia
Superphylum: Ecdysozoa
(unranked): Panarthropoda
Unranked superphylum: Tactopoda
Phylum: Tardigrada
Spallanzani, 1777
Classes

Tardigrades (also known as waterbears or moss piglets)[2][3] are water-dwelling, segmented micro-animals, with eight legs.[2] They were first described by the German pastor J.A.E. Goeze in 1773. The name Tardigrada (meaning "slow stepper") was given three years later by the Italian biologist Lazzaro Spallanzani.[4]

Tardigrades are classified as extremophiles, organisms that can thrive in a physically or geochemically extreme condition that would be detrimental to most life on Earth.[5][6] For example, tardigrades can withstand temperatures from just above absolute zero to well above the boiling point of water, pressures about six times stronger than pressures found in the deepest ocean trenches, ionizing radiation at doses hundreds of times higher than the lethal dose for a person, and the vacuum of outer space. They can go without food or water for more than 10 years, drying out to the point where they are 3% or less water, only to rehydrate, forage, and reproduce.[7][8][9]

Usually, tardigrades are about 0.5 mm (0.020 in) long when they are fully grown.[2] They are short and plump with four pairs of legs, each with four to eight claws also known as "disks".[2] The animals are prevalent in mosses and lichens and feed on plant cells, algae, and small invertebrates. When collected, they may be viewed under a very-low-power microscope, making them accessible to students and amateur scientists.[10]

Tardigrades form the phylum Tardigrada, part of the superphylum Ecdysozoa. It is an ancient group, with fossils dating from 530 million years ago, in the Cambrian period.[11] The first tardigrades were discovered by Johann August Ephraim Goeze in 1773. Since 1778, over 1,150 tardigrade species have been found.

Description

Johann August Ephraim Goeze originally named the tardigrade kleiner Wasserbär (Bärtierchen today), meaning 'little water bear' in German. The name Tardigrada means "slow walker" and was given by Lazzaro Spallanzani in 1773.[12] The name water bear comes from the way they walk, reminiscent of a bear's gait. The biggest adults may reach a body length of 1.5 mm (0.059 in), the smallest below 0.1 mm. Newly hatched tardigrades may be smaller than 0.05 mm.

About 1,150 species of tardigrades have been described.[13][14] Tardigrades occur throughout the world, from the Himalayas[15] (above 6,000 m (20,000 ft)), to the deep sea (below 4,000 m (13,000 ft)) and from the polar regions to the equator.

The most convenient place to find tardigrades is on lichens and mosses. Other environments are dunes, beaches, soil, and marine or freshwater sediments, where they may occur quite frequently (up to 25,000 animals per liter). Tardigrades often can be found by soaking a piece of moss in spring water.[16]

Anatomy and morphology

Tardigrades have barrel-shaped bodies with four pairs of stubby, poorly articulated legs. Most range from 0.3 to 0.5 mm (0.012 to 0.020 in) in length, although the largest species may reach 1.2 mm (0.047 in). The body consists of a head, three body segments with a pair of legs each, and a caudal segment with a fourth pair of legs. The legs are without joints while the feet have four to eight claws each. The cuticle contains chitin and protein and is moulted periodically.

Tardigrades are eutelic, with all adult tardigrades of the same species having the same number of cells. Some species have as many as 40,000 cells in each adult, while others have far fewer.[17][18]

The body cavity consists of a haemocoel, but the only place where a true coelom can be found is around the gonad. There are no respiratory organs, with gas exchange able to occur across the whole of the body. Some tardigrades have three tubular glands associated with the rectum; these may be excretory organs similar to the Malpighian tubules of arthropods, although the details remain unclear.[19]

The tubular mouth is armed with stylets, which are used to pierce the plant cells, algae, or small invertebrates on which the tardigrades feed, releasing the body fluids or cell contents. The mouth opens into a triradiate, muscular, sucking pharynx. The stylets are lost when the animal moults, and a new pair is secreted from a pair of glands that lie on either side of the mouth. The pharynx connects to a short oesophagus, and then to an intestine that occupies much of the length of the body, which is the main site of digestion. The intestine opens, via a short rectum, to an anus located at the terminal end of the body. Some species only defecate when they molt, leaving the feces behind with the shed cuticle.[19]

The brain includes multiple lobes, mostly consisting of three bilaterally paired clusters of neurons.[20] The brain is attached to a large ganglion below the oesophagus, from which a double ventral nerve cord runs the length of the body. The cord possesses one ganglion per segment, each of which produces lateral nerve fibres that run into the limbs. Many species possess a pair of rhabdomeric pigment-cup eyes, and there are numerous sensory bristles on the head and body.[21]

Tardigrades all possess a buccopharyngeal apparatus, which, along with the claws, is used to differentiate among species.

Reproduction

Although some species are parthenogenetic, both males and females are usually present, each with a single gonad located above the intestine. Two ducts run from the testis in males, opening through a single pore in front of the anus. In contrast, females have a single duct opening either just above the anus or directly into the rectum, which thus forms a cloaca.[19]

Tardigrades are oviparous, and fertilization is usually external. Mating occurs during the molt with the eggs being laid inside the shed cuticle of the female and then covered with sperm. A few species have internal fertilization, with mating occurring before the female fully sheds her cuticle. In most cases, the eggs are left inside the shed cuticle to develop, but some attach them to nearby substrate.[19]

The eggs hatch after no more than 14 days, with the young already possessing their full complement of adult cells. Growth to the adult size therefore occurs by enlargement of the individual cells (hypertrophy), rather than by cell division. Tardigrades may moult up to 12 times.[19]

Ecology and life history

Most tardigrades are phytophagous (plant eaters) or bacteriophagous (bacteria eaters), but some are predatory (e.g., Milnesium tardigradum).[22][23]

Physiology

Scientists have reported tardigrades in hot springs, on top of the Himalayas, under layers of solid ice, and in ocean sediments. Many species can be found in milder environments such as lakes, ponds, and meadows, while others can be found in stone walls and roofs. Tardigrades are most common in moist environments, but can stay active wherever they can retain at least some moisture.

Tardigrades are one of the few groups of species that are capable of reversibly suspending their metabolism and going into a state of cryptobiosis. Several species regularly survive in a dehydrated state for nearly 10 years. Depending on the environment, they may enter this state via anhydrobiosis, cryobiosis, osmobiosis, or anoxybiosis. While in this state, their metabolism lowers to less than 0.01% of normal and their water content can drop to 1% of normal. Their ability to remain desiccated for such a long period is largely dependent on the high levels of the nonreducing sugar trehalose, which protects their membranes. In this cryptobiotic state, the tardigrade is known as a tun.[24]

Tardigrades are able to survive in extreme environments that would kill almost any other animal. The following are extremes states tardigrades can survive:

  • Temperature – tardigrades can survive being heated for a few minutes to 151 °C (304 °F),[25] or being chilled for days at −200 °C (-328 °F),.[25] Some can even survive cooling to −273 °C (~1 degree above absolute zero or -458 °F)[26] for a few minutes.
  • Pressure – they can withstand the extremely low pressure of a vacuum and also very high pressures, more than 1,200 times atmospheric pressure. Tardigrades can survive the vacuum of open space and solar radiation combined for at least 10 days.[27] Some species can also withstand pressure of 6,000 atmospheres, which is nearly six times the pressure of water in the deepest ocean trench, the Mariana trench.[17]
  • Dehydration – the longest that living tardigrades have been shown to survive in a dry state is nearly 10 years,[9][28] although there is one report of a leg movement, not generally considered "survival",[29] in a 120-year-old specimen from dried moss.[30] When exposed to extremely low temperatures, their body composition goes from 85% water to only 3%. As water expands upon freezing, dehydration ensures the tardigrades do not get ripped apart by the freezing ice.[31]
  • Radiation – tardigrades can withstand 1,000 times more radiation than other animals,[32] median lethal doses of 5,000 Gy (of gamma rays) and 6,200 Gy (of heavy ions) in hydrated animals (5 to 10 Gy could be fatal to a human).[33] The only explanation found in earlier experiments for this ability was that their lowered water state provides fewer reactants for the ionizing radiation.[34] However, subsequent research found that tardigrades, when hydrated, still remain highly resistant to shortwave UV radiation in comparison to other animals, and that one factor for this is their ability to efficiently repair damage to their DNA resulting from that exposure.[35]
Irradiation of tardigrade eggs collected directly from a natural substrate (moss) showed a clear dose-related response, with a steep decline in hatchability at doses up to 4 kGy above which no eggs hatched.[36] The eggs were more tolerant to radiation late in development. No eggs irradiated at the early developmental stage hatched, and only one egg at middle stage hatched, while eggs irradiated in the late stage hatched at a rate indistinguishable from controls.[36]
  • Environmental toxins – tardigrades can undergo chemobiosis, a cryptobiotic response to high levels of environmental toxins. However, as of 2001, these laboratory results have yet to be verified.[29][30]
  • Outer space – tardigrades are the first known animal to survive in space. On September 2007, dehydrated tardigrades were taken into low Earth orbit on the FOTON-M3 mission carrying the BIOPAN astrobiology payload. For 10 days, groups of tardigrades were exposed to the hard vacuum of outer space, or vacuum and solar UV radiation.[37][38] After being rehydrated back on Earth, over 68% of the subjects protected from high-energy UV radiation revived within 30 minutes following rehydration, but subsequent mortality was high; many of these produced viable embryos.[27][39] In contrast, dehydrated samples exposed to the combined effect of vacuum and full solar UV radiation had significantly reduced survival, with only three subjects of Milnesium tardigradum surviving.[27] In May 2011, Italian scientists sent tardigrades into space along with other extremophiles on STS-134, the final flight of Space Shuttle Endeavour.[40][41][42] Their conclusion was that microgravity and cosmic radiation "did not significantly affect survival of tardigrades in flight, confirming that tardigrades represent a useful animal for space research."[43] In November 2011, they were among the organisms to be sent by the US-based Planetary Society on the Russian Fobos-Grunt mission's Living Interplanetary Flight Experiment to Phobos; however, the launch failed.

Evolutionary relationships and history

Illustration of Echiniscus sp. from 1861

A number of morphological and molecular studies have sought to resolve the relationship of tardigrades to other lineages of ecdysozoan animals. Two plausible placements have been recovered: tardigrades most closely related to Arthropoda ± Onychophora (a common result of morphological studies) or tardigrades most closely related to nematodes (found in some molecular analyses).

The latter hypothesis has been rejected by recent microRNA and expressed sequence tag analyses.[44] Apparently, the grouping of tardigrades with nematodes found in a number of molecular studies is a long branch attraction artifact. Within the arthropod group (called panarthropoda and comprising onychophora, tardigrades and euarthropoda), three patterns of relationship are possible: tardigrades sister to onychophora plus arthropods (the lobopodia hypothesis); onychophora sister to tardigrades plus arthropods (the tactopoda hypothesis); and onychophora sister to tardigrades.[45] Recent analyses indicate that the panarthropoda group is monophyletic, and that tardigrades are a sister group of lobopodia, the lineage consisting of arthropods and Onychophora.[44][46]

Panarthropoda

Water bears (Tardigrada)


Lobopoda

Velvet worms (Onychophora)



Arthropods (Arthropoda)




The minute sizes of tardigrades and their membranous integuments make their fossilization both difficult to detect and highly unlikely. The only known fossil specimens comprise some from mid-Cambrian deposits in Siberia and a few rare specimens from Cretaceous amber.[47]

The Siberian tardigrades differ from living tardigrades in several ways. They have three pairs of legs rather than four; they have a simplified head morphology; and they have no posterior head appendages. But they share their columnar cuticle construction with modern tardigrades.[48] It is considered that they probably represent a stem group of living tardigrades.[47]

The rare specimens in Cretaceous amber comprise Milnesium swolenskyi, from New Jersey, the oldest, whose claws and mouthparts are indistinguishable from the living M. tardigradum; and two specimens from western Canada, some 15–20 million years younger than M. swolenskyi. Of the two latter, one has been given its own genus and family, Beorn leggi (the genus named by Cooper after the character Beorn from The Hobbit by J. R. R. Tolkien and the species named after his student William M. Legg); however, it bears a strong resemblance to many living specimens in the family Hypsibiidae.[47][49]

Aysheaia from the middle Cambrian Burgess shale has been proposed as a sister-taxon to an arthropod-tardigrade clade.[50]

Tardigrades have been proposed to be among the closest living relatives of the Burgess Shale oddity Opabinia.[51]

Genomes and genome sequencing

Tardigrade genomes vary in size, from about 75 to 800 megabase pairs of DNA.[52] The genome of a tardigrade species, Hypsibius dujardini, is being sequenced at the Broad Institute.[53]

The genome of R. varieornatus has already been sequenced.[54]

Hypsibius dujardini has a compact genome and a generation time of about two weeks, and it can be cultured indefinitely and cryopreserved.[55]

See also

References

  1. Budd, G.E. (2001). "Tardigrades as 'stem-group arthropods': the evidence from the Cambrian fauna". Zool. Anz 240 (3–4): 265–279. doi:10.1078/0044-5231-00034. 
  2. 2.0 2.1 2.2 2.3 Miller William. "Tardigrades". American Scientist. Retrieved 2 December 2013. 
  3. Copley, Jon (1999-10-23). "Indestructible". New Scientist (2209). Retrieved 2010-02-06 
  4. Bordenstein, Sarah. "Tardigrades (Water Bears)". Microbial Life Educational Resources. National Science Digital Library. Retrieved 2014-01-24. 
  5. Rampelotto, P. H. (2010). Resistance of microorganisms to extreme environmental conditions and its contrbution to Astrobiology. Sustainability, 2, 1602–1623.
  6. Rothschild, L.J.; Mancinelli, R.L. (2001). "Life in extreme environments". Nature 409 (6823): 1092–1101. doi:10.1038/35059215. PMID 11234023. 
  7. Brennand, Emma (2011-05-17). "Tardigrades: Water bears in space". BBC. Retrieved 2013-05-31. 
  8. Crowe, John H.; Carpenter, John F.; Crowe, Lois M. (October 1998). "The role of vitrification in anhydrobiosis". Annual Review of Physiology 60. pp. 73–103. doi:10.1146/annurev.physiol.60.1.73. PMID 9558455 
  9. 9.0 9.1 Guidetti, R. & Jönsson, K.I. (2002). "Long-term anhydrobiotic survival in semi-terrestrial micrometazoans". Journal of Zoology 257 (2): 181–187. doi:10.1017/S095283690200078X. 
  10. Shaw, Michael W. "How to Find Tardigrades". tardigrades.us. Retrieved 2013-01-14. 
  11. "Tardigrada (water bears, tardigrades)". biodiversity explorer. Retrieved 2013-05-31. 
  12. Bordenstein, Sarah (December 17, 2008). "Tardigrades (Water Bears)". Carleton College. Retrieved September 16, 2012. 
  13. Zhang, Z.-Q. (2011). "Animal biodiversity: An introduction to higher-level classification and taxonomic richness". Zootaxa 3148: 7–12. 
  14. Degma, P., Bertolani, R. & Guidetti, R. 2009–2011. Actual checklist of Tardigrada species. Ver. 18: 27-04-2011. http://www.tardigrada.modena.unimo.it/miscellanea/Actual%20checklist%20of%20Tardigrada.pdf
  15. Hogan, C. Michael. 2010. "Extremophile". eds. E.Monosson and C.Cleveland. Encyclopedia of Earth. National Council for Science and the Environment, washington DC
  16. Goldstein, B. and Blaxter, M. (2002). "Quick Guide: Tardigrades". Current Biology 12 (14): R475. doi:10.1016/S0960-9822(02)00959-4. 
  17. 17.0 17.1 Seki, Kunihiro; Toyoshima, Masato (1998-10-29). "Preserving tardigrades under pressure". Nature 395 (6705): 853–854. doi:10.1038/27576 
  18. Kinchin, Ian M. (1994) The Biology of Tardigrades, Ashgate Publishing
  19. 19.0 19.1 19.2 19.3 19.4 Barnes, Robert D. (1982). Invertebrate Zoology. Philadelphia, PA: Holt-Saunders International. pp. 877–880. ISBN 0-03-056747-5. 
  20. Zantke, Juliane; Wolff, Carsten; Scholtz, Gerhard (2008). "Three-dimensional reconstruction of the central nervous system of Macrobiotus hufelandi (Eutardigrada, Parachela): implications for the phylogenetic position of Tardigrada". Zoomorphology 127 (1): 21–26. doi:10.1007/s00435-007-0045-1. 
  21. Greven, H. (Dec 2007). "Comments on the eyes of tardigrades". Arthropod structure & development 36 (4): 401–407. doi:10.1016/j.asd.2007.06.003. ISSN 1467-8039. PMID 18089118. 
  22. Morgan, Clive I. (1977). "Population Dynamics of two Species of Tardigrada, Macrobiotus hufelandii (Schultze) and Echiniscus (Echiniscus) testudo (Doyere), in Roof Moss from Swansea". The Journal of Animal Ecology (British Ecological Society) 46 (1): 263–279. doi:10.2307/3960. JSTOR 3960. 
  23. Lindahl, K. (2008-03-15). "Tardigrade Facts". 
  24. Piper, Ross (2007), Extraordinary Animals: An Encyclopedia of Curious and Unusual Animals, Greenwood Press.
  25. 25.0 25.1 Horikawa, Daiki D. (2012). Alexander V. Altenbach, Joan M. Bernhard & Joseph Seckbach, ed. Anoxia Evidence for Eukaryote Survival and Paleontological Strategies. (21 ed.). Springer Netherlands. pp. 205–217. ISBN 978-94-007-1895-1. Retrieved 21 January 2012. 
  26. Becquerel P. (1950). "La suspension de la vie au dessous de 1/20 K absolu par demagnetization adiabatique de l'alun de fer dans le vide les plus eléve". C. R. Hebd. Séances Acad. Sci. Paris (in French) 231: 261–263. 
  27. 27.0 27.1 27.2 Jönsson, K. Ingemar; Rabbow, Elke; Schill, Ralph O.; Harms-Ringdahl, Mats and Rettberg, Petra. (9 September 2008). "Tardigrades survive exposure to space in low Earth orbit". Current Biology 18 (17): R729–R731. doi:10.1016/j.cub.2008.06.048. Retrieved 2013-08-05. 
  28. Crowe, John H.; Carpenter, John F.; Crowe, Lois M. (October 1998). "The role of vitrification in anhydrobiosis". Annual Review of Physiology 60. pp. 73–103. doi:10.1146/annurev.physiol.60.1.73. PMID 9558455 
  29. 29.0 29.1 Jönsson, K. Ingemar & R. Bertolani (2001). "Facts and fiction about long-term survival in tardigrades". Journal of Zoology 255: 121–123. doi:10.1017/S0952836901001169. 
  30. 30.0 30.1 Franceschi, T. (1948). "Anabiosi nei tardigradi". Bolletino dei Musei e degli Istituti Biologici dell'Università di Genova 22: 47–49. 
  31. Michael Kent (2000), Advanced Biology, Oxford University Press.
  32. Radiation tolerance in the tardigrade Milnesium tardigradum
  33. Horikawa DD, Sakashita T, Katagiri C, Watanabe M, Kikawada T, Nakahara Y, Hamada N, Wada S, Funayama T, Higashi S, Kobayashi Y, Okuda T, Kuwabara M. (2006). "Radiation tolerance in the tardigrade Milnesium tardigradum". International Journal of Radiation Biology 82 (12): 843–8. doi:10.1080/09553000600972956. PMID 17178624. 
  34. Horikawa, Daiki D.; Sakashita, Tetsuya, Katagiri, Chihiro, Watanabe, Masahiko, Kikawada, Takahiro, Nakahara, Yuichi, Hamada, Nobuyuki, Wada, Seiichi, Funayama, Tomoo, Higashi, Seigo, Kobayashi, Yasuhiko, Okuda, Takashi, Kuwabara, Mikinori (1 January 2006). "Radiation tolerance in the tardigrade". International Journal of Radiation Biology 82 (12): 843–848. doi:10.1080/09553000600972956. PMID 17178624. 
  35. Horikawa, Daiki D. UV Radiation Tolerance of Tardigrades. NASA.com. Retrieved 15 January 2013. 
  36. 36.0 36.1 Jönsson, Ingemar; Beltran-Pardo, Eliana; Haghdoost, Siamak; Wojcik, Andrzej; Bermúdez-Cruz, Rosa Maria; Bernal Villegas, Jaime E.; Harms-Ringdahl, Mats (2013). "Tolerance to gamma-irradiation in eggs of the tardigrade Richtersius coronifer depends on stage of development". Journal of Limnology 71 (12th International Symposium on Tardigrada). Retrieved 2013-08-05. 
  37. "Creature Survives Naked in Space". Space.com. 8 September 2008. Retrieved 2011-12-22. 
  38. Mustain, Andrea (22 December 2011). "Weird wildlife: The real land animals of Antarctica". MSNBC. Retrieved 2011-12-22. 
  39. Courtland, Rachel (2008-09-08). "'Water bears' are first animal to survive space vacuum". New Scientist. Retrieved 2011-05-22. 
  40. NASA Staff (2011-05-17). "BIOKon In Space (BIOKIS)". NASA. Retrieved 2011-05-24. 
  41. Brennard, Emma (2011-05-17). "Tardigrades: Water bears in space". BBC. Retrieved 2011-05-24. 
  42. "Tardigrades: Water bears in space". BBC Nature. 2011-05-17. 
  43. Rebecchi, L., et. al. "Two Tardigrade Species On Board the STS-134 Space Flight" in "International Symposium on Tardigrada, 23-26 July 2012". p. 89. Retrieved 2013-01-14. 
  44. 44.0 44.1 Campbell, Lahcen; Omar Rota-Stabellia, Gregory D. Edgecombeb, Trevor Marchioroc, Stuart J. Longhorna, Maximilian J. Telfordd, Hervé Philippee, Lorena Rebecchic, Kevin J. Petersonf and Davide Pisania (2011). "MicroRNAs and phylogenomics resolve the relationships of Tardigrada and suggest that velvet worms are the sister group of Arthropoda". PNAS Early Edition 108 (38): 15920–4. doi:10.1073/pnas.1105499108. PMC 3179045. PMID 21896763. 
  45. Telford, Maximilian; Sarah J Bourlat, Andrew Economou, Daniel Papillon and Omar Rota-Stabelli (April 2008). "The evolution of the Ecdysozoa". Phil. Trans. R. Soc. B 363 (1496): 1529–1537. doi:10.1098/rstb.2007.2243. PMC 2614232. PMID 18192181. Retrieved 2013-09-09. 
  46. "Sequencing of Tardigrade Genome" (PDF). The Royal Society. 2003. Retrieved 2013-05-31. 
  47. 47.0 47.1 47.2 Grimaldi, David A.; Engel, Michael S. (2005). Evolution of the Insects. Cambridge University Press. pp. 96–97. ISBN 0-521-82149-5. 
  48. Budd, G. (2001). "Tardigrades as 'Stem-Group Arthropods': The Evidence from the Cambrian Fauna". Zoologischer Anzeiger - A Journal of Comparative Zoology 240 (3–4): 265–279. doi:10.1078/0044-5231-00034. ISSN 0044-5231. 
  49. Cooper, Kenneth W. (1964). "The first fossil tardigrade: Beorn leggi, from Cretaceous Amber". Psyche – Journal of Entomology 71 (2): 41. doi:10.1155/1964/48418. 
  50. Fortey, Richard A.; Thomas, Richard H. (2001). Arthropod Relationships. Chapman & Hall. p. 383. ISBN 0412754207. 
  51. Budd, G.E. (1996). "The morphology of Opabinia regalis and the reconstruction of the arthropod stem-group". Lethaia 29 (1): 1–14. doi:10.1111/j.1502-3931.1996.tb01831.x. 
  52. "Genome Size of Tardigrades". 
  53. Entrez. "Genome Projects for Hypsibius dujardini". 
  54. Horikawa D. et al. (2013). "Analysis of DNA Repair and Protection in the Tardigrade Ramazzottius varieornatus and Hypsibius dujardini after Exposure to UVC Radiation.". PLoS ONE (8(6): e64793.). doi:10.1371/journal.pone.0064793. 
  55. Gabriel, W. et al.; McNuff, Robert; Patel, Sapna K.; Gregory, T. Ryan; Jeck, William R.; Jones, Corbin D.; Goldstein, Bob (2007). "The tardigrade Hypsibius dujardini, a new model for studying the evolution of development". Developmental Biology 312 (2): 545–559. doi:10.1016/j.ydbio.2007.09.055. PMID 17996863. 

External links


This article is issued from Wikipedia. The text is available under the Creative Commons Attribution/Share Alike; additional terms may apply for the media files.