Crustacean

Crustaceans (Crustacea /krʌˈstʃə/) form a large, diverse arthropod taxon which includes such animals as crabs, lobsters, crayfish, shrimps, prawns, krill, woodlice, and barnacles.[1] The crustacean group can be treated as a subphylum under the clade Mandibulata; because of recent molecular studies it is now well accepted that the crustacean group is paraphyletic, and comprises all animals in the clade Pancrustacea other than hexapods.[2] Some crustaceans are more closely related to insects and other hexapods than they are to certain other crustaceans.

Crustaceans
Temporal range: 511–0 Ma Cambrian to present
Abludomelita obtusata, an amphipod
Scientific classification
Kingdom: Animalia
Phylum: Arthropoda
Clade: Pancrustacea
Subphylum: Crustacea
Groups included

Thylacocephala? †
Branchiopoda

Phyllopoda
Sarsostraca

Remipedia
Cephalocarida
Maxillopoda

Thecostraca
Tantulocarida
Branchiura
Pentastomida
Mystacocarida
Copepoda

Ostracoda

Myodocopa
Podocopa

Malacostraca

Phyllocarida
Hoplocarida
Eumalacostraca
Cladistically included but traditionally excluded taxa

Hexapods

The 67,000 described species range in size from Stygotantulus stocki at 0.1 mm (0.004 in), to the Japanese spider crab with a leg span of up to 3.8 m (12.5 ft) and a mass of 20 kg (44 lb). Like other arthropods, crustaceans have an exoskeleton, which they moult to grow. They are distinguished from other groups of arthropods, such as insects, myriapods and chelicerates, by the possession of biramous (two-parted) limbs, and by their larval forms, such as the nauplius stage of branchiopods and copepods.

Most crustaceans are free-living aquatic animals, but some are terrestrial (e.g. woodlice), some are parasitic (e.g. Rhizocephala, fish lice, tongue worms) and some are sessile (e.g. barnacles). The group has an extensive fossil record, reaching back to the Cambrian, and includes living fossils such as Triops cancriformis, which has existed apparently unchanged since the Triassic period. More than 7.9 million tons of crustaceans per year are produced by fishery or farming for human consumption,[3] the majority of it being shrimp and prawns. Krill and copepods are not as widely fished, but may be the animals with the greatest biomass on the planet, and form a vital part of the food chain. The scientific study of crustaceans is known as carcinology (alternatively, malacostracology, crustaceology or crustalogy), and a scientist who works in carcinology is a carcinologist.

Structure

A shed carapace of a lady crab, part of the hard exoskeleton
Body structure of a typical crustacean – krill

The body of a crustacean is composed of segments, which are grouped into three regions: the cephalon or head,[4] the pereon or thorax,[5] and the pleon or abdomen.[6] The head and thorax may be fused together to form a cephalothorax,[7] which may be covered by a single large carapace.[8] The crustacean body is protected by the hard exoskeleton, which must be moulted for the animal to grow. The shell around each somite can be divided into a dorsal tergum, ventral sternum and a lateral pleuron. Various parts of the exoskeleton may be fused together.[9]:289

Each somite, or body segment can bear a pair of appendages: on the segments of the head, these include two pairs of antennae, the mandibles and maxillae;[4] the thoracic segments bear legs, which may be specialised as pereiopods (walking legs) and maxillipeds (feeding legs).[5] The abdomen bears pleopods,[6] and ends in a telson, which bears the anus, and is often flanked by uropods to form a tail fan.[10] The number and variety of appendages in different crustaceans may be partly responsible for the group's success.[11]

Crustacean appendages are typically biramous, meaning they are divided into two parts; this includes the second pair of antennae, but not the first, which is usually uniramous, the exception being in the Class Malacostraca where the antennules may be generally biramous or even triramous.[12][13] It is unclear whether the biramous condition is a derived state which evolved in crustaceans, or whether the second branch of the limb has been lost in all other groups. Trilobites, for instance, also possessed biramous appendages.[14]

The main body cavity is an open circulatory system, where blood is pumped into the haemocoel by a heart located near the dorsum.[15] Malacostraca have haemocyanin as the oxygen-carrying pigment, while copepods, ostracods, barnacles and branchiopods have haemoglobins.[16] The alimentary canal consists of a straight tube that often has a gizzard-like "gastric mill" for grinding food and a pair of digestive glands that absorb food; this structure goes in a spiral format.[17] Structures that function as kidneys are located near the antennae. A brain exists in the form of ganglia close to the antennae, and a collection of major ganglia is found below the gut.[18]

In many decapods, the first (and sometimes the second) pair of pleopods are specialised in the male for sperm transfer. Many terrestrial crustaceans (such as the Christmas Island red crab) mate seasonally and return to the sea to release the eggs. Others, such as woodlice, lay their eggs on land, albeit in damp conditions. In most decapods, the females retain the eggs until they hatch into free-swimming larvae.[19]

Ecology

The majority of crustaceans are aquatic, living in either marine or freshwater environments, but a few groups have adapted to life on land, such as terrestrial crabs, terrestrial hermit crabs, and woodlice. Marine crustaceans are as ubiquitous in the oceans as insects are on land.[20][21] The majority of crustaceans are also motile, moving about independently, although a few taxonomic units are parasitic and live attached to their hosts (including sea lice, fish lice, whale lice, tongue worms, and Cymothoa exigua, all of which may be referred to as "crustacean lice"), and adult barnacles live a sessile life – they are attached headfirst to the substrate and cannot move independently. Some branchiurans are able to withstand rapid changes of salinity and will also switch hosts from marine to non-marine species.[22]:672 Krill are the bottom layer and the most important part of the food chain in Antarctic animal communities.[23]:64 Some crustaceans are significant invasive species, such as the Chinese mitten crab, Eriocheir sinensis,[24] and the Asian shore crab, Hemigrapsus sanguineus.[25]

Life cycle

Eggs of Potamon fluviatile, a freshwater crab
Zoea larva of the European lobster, Homarus gammarus

Mating system

The majority of crustaceans have separate sexes, and reproduce sexually.[26] A small number are hermaphrodites, including barnacles, remipedes,[27] and Cephalocarida.[28] Some may even change sex during the course of their life.[28] Parthenogenesis is also widespread among crustaceans, where viable eggs are produced by a female without needing fertilisation by a male.[26] This occurs in many branchiopods, some ostracods, some isopods, and certain "higher" crustaceans, such as the Marmorkrebs crayfish.

Eggs

In many groups of crustaceans, the fertilised eggs are simply released into the water column, while others have developed a number of mechanisms for holding on to the eggs until they are ready to hatch. Most decapods carry the eggs attached to the pleopods, while peracarids, notostracans, anostracans, and many isopods form a brood pouch from the carapace and thoracic limbs.[26] Female Branchiura do not carry eggs in external ovisacs but attach them in rows to rocks and other objects.[29]:788 Most leptostracans and krill carry the eggs between their thoracic limbs; some copepods carry their eggs in special thin-walled sacs, while others have them attached together in long, tangled strings.[26]

Larvae

Crustaceans exhibit a number of larval forms, of which the earliest and most characteristic is the nauplius. This has three pairs of appendages, all emerging from the young animal's head, and a single naupliar eye. In most groups, there are further larval stages, including the zoea (pl. zoeæ or zoeas[30]). This name was given to it when naturalists believed it to be a separate species.[31] It follows the nauplius stage and precedes the post-larva. Zoea larvae swim with their thoracic appendages, as opposed to nauplii, which use cephalic appendages, and megalopa, which use abdominal appendages for swimming. It often has spikes on its carapace, which may assist these small organisms in maintaining directional swimming.[32] In many decapods, due to their accelerated development, the zoea is the first larval stage. In some cases, the zoea stage is followed by the mysis stage, and in others, by the megalopa stage, depending on the crustacean group involved.

Classification

The name "crustacean" dates from the earliest works to describe the animals, including those of Pierre Belon and Guillaume Rondelet, but the name was not used by some later authors, including Carl Linnaeus, who included crustaceans among the "Aptera" in his Systema Naturae.[33] The earliest nomenclaturally valid work to use the name "Crustacea" was Morten Thrane Brünnich's Zoologiæ Fundamenta in 1772,[34] although he also included chelicerates in the group.[33]

The subphylum Crustacea comprises almost 67,000 described species,[35] which is thought to be just 110 to 1100 of the total number as the majority of species remain as yet undiscovered.[36] Although most crustaceans are small, their morphology varies greatly and includes both the largest arthropod in the world – the Japanese spider crab with a leg span of 3.7 metres (12 ft)[37] – and the smallest, the 100-micrometre-long (0.004 in) Stygotantulus stocki.[38] Despite their diversity of form, crustaceans are united by the special larval form known as the nauplius.

The exact relationships of the Crustacea to other taxa are not completely settled as of April 2012. Studies based on morphology led to the Pancrustacea hypothesis,[39] in which Crustacea and Hexapoda (insects and allies) are sister groups. More recent studies using DNA sequences suggest that Crustacea is paraphyletic, with the hexapods nested within a larger Pancrustacea clade.[40][41]

Although the classification of crustaceans has been quite variable, the system used by Martin and Davis[42] largely supersedes earlier works. Mystacocarida and Branchiura, here treated as part of Maxillopoda, are sometimes treated as their own classes. Six classes are usually recognised:

Copepods, from Ernst Haeckel's 1904 work Kunstformen der Natur
Decapods, from Ernst Haeckel's 1904 work Kunstformen der Natur
ClassMembersOrdersPhoto
Branchiopodabrine shrimp
fairy shrimp
water fleas
tadpole shrimp
clam shrimp
Anostraca
Lipostraca
Notostraca
Laevicaudata
Spinicaudata
Cyclestherida
Cladocera

Daphnia pulex (Cladocera)
RemipediaNectiopoda
Speleonectes tanumekes (Speleonectidae)
Cephalocaridahorseshoe shrimpBrachypoda
Hutchinsoniella macracantha
Maxillopodabarnacles
copepods
Calanoida
Pedunculata
Sessilia
c. 20 others

Chthamalus stellatus (Sessilia)
Ostracodaseed shrimpMyodocopida
Halocyprida
Platycopida
Podocopida

Cylindroleberididae
Malacostracacrabs
lobsters
crayfish
shrimp
krill
mantis shrimp
woodlice
hooded shrimp
scuds
sandhoppers
etc.
Decapoda
Isopoda
Amphipoda
Stomatopoda
c. 12 others

Gammarus roeseli (Amphipoda)

Fossil record

Crustaceans have a rich and extensive fossil record, which begins with animals such as Canadaspis and Perspicaris from the Middle Cambrian age Burgess Shale.[43][44] Most of the major groups of crustaceans appear in the fossil record before the end of the Cambrian, namely the Branchiopoda, Maxillopoda (including barnacles and tongue worms) and Malacostraca; there is some debate as to whether or not Cambrian animals assigned to Ostracoda are truly ostracods, which would otherwise start in the Ordovician.[45] The only classes to appear later are the Cephalocarida,[46] which have no fossil record, and the Remipedia, which were first described from the fossil Tesnusocaris goldichi, but do not appear until the Carboniferous.[47] Most of the early crustaceans are rare, but fossil crustaceans become abundant from the Carboniferous period onwards.[43]

Norway lobsters on sale at a Spanish market

Within the Malacostraca, no fossils are known for krill,[48] while both Hoplocarida and Phyllopoda contain important groups that are now extinct as well as extant members (Hoplocarida: mantis shrimp are extant, while Aeschronectida are extinct;[49] Phyllopoda: Canadaspidida are extinct, while Leptostraca are extant[44]). Cumacea and Isopoda are both known from the Carboniferous,[50][51] as are the first true mantis shrimp.[52] In the Decapoda, prawns and polychelids appear in the Triassic,[53][54] and shrimp and crabs appear in the Jurassic;[55][56] . The fossil burrow Ophiomorpha is attributed to ghost shrimps, whereas the fossil burrow Camborygma is attributed to crayfishes. The Permian–Triassic deposits of Nurra preserve the oldest (Permian: Roadian) fluvial burrows ascribed to ghost shrimps (Decapoda: Axiidea, Gebiidea) and crayfishes (Decapoda: Astacidea, Parastacidea), respectively[57].

However, the great radiation of crustaceans occurred in the Cretaceous, particularly in crabs, and may have been driven by the adaptive radiation of their main predators, bony fish.[56] The first true lobsters also appear in the Cretaceous.[58]

Consumption by humans

Many crustaceans are consumed by humans, and nearly 10,700,000 tons were produced in 2007; the vast majority of this output is of decapod crustaceans: crabs, lobsters, shrimp, crawfish, and prawns.[59] Over 60% by weight of all crustaceans caught for consumption are shrimp and prawns, and nearly 80% is produced in Asia, with China alone producing nearly half the world's total.[59] Non-decapod crustaceans are not widely consumed, with only 118,000 tons of krill being caught,[59] despite krill having one of the greatest biomasses on the planet.[60]

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See also

References

  1. Calman, William Thomas (1911). "Crustacea" . In Chisholm, Hugh (ed.). Encyclopædia Britannica. 7 (11th ed.). Cambridge University Press. p. 552.
  2. Omar Rota-Stabelli; Ehsan Kayal; Dianne Gleeson; Jennifer Daub; Jeffrey L. Boore; Maximilian J. Telford; Davide Pisani; Mark Blaxter & Dennis V. Lavrov (2010). "Ecdysozoan Mitogenomics: Evidence for a Common Origin of the Legged Invertebrates, the Panarthropoda". Genome Biology and Evolution. 2: 425–440. doi:10.1093/gbe/evq030. PMC 2998192. PMID 20624745. Archived from the original on 2012-07-10.
  3. "The State of World Fisheries and Aquaculture 2018 - Meeting the sustainable development goals" (PDF). Food and Agriculture Organization of the United Nations.
  4. "Cephalon". Crustacean Glossary. Natural History Museum of Los Angeles County. Archived from the original on 2011-07-27. Retrieved 2016-09-10.
  5. "Thorax". Crustacean Glossary. Natural History Museum of Los Angeles County. Archived from the original on 2011-07-27. Retrieved 2016-09-10.
  6. "Abdomen". Crustacean Glossary. Natural History Museum of Los Angeles County. Archived from the original on 2011-07-27. Retrieved 2016-09-10.
  7. "Cephalothorax". Crustacean Glossary. Natural History Museum of Los Angeles County. Archived from the original on 2011-07-27. Retrieved 2016-09-10.
  8. "Carapace". Crustacean Glossary. Natural History Museum of Los Angeles County. Archived from the original on 2011-07-27. Retrieved 2016-09-10.
  9. P. J. Hayward; J. S. Ryland (1995). Handbook of the marine fauna of north-west Europe. Oxford University Press. ISBN 978-0-19-854055-7. Retrieved 2016-09-10.
  10. "Telson". Crustacean Glossary. Natural History Museum of Los Angeles County. Archived from the original on 2011-07-27. Retrieved 2016-09-10.
  11. Elizabeth Pennisi (July 4, 1997). "Crab legs and lobster claws". Science. 277 (5322): 36. doi:10.1126/science.277.5322.36.
  12. "Antennule". Crustacean Glossary. Natural History Museum of Los Angeles County. Retrieved 2016-09-10.
  13. "Crustaceamorpha: appendages". University of California, Berkeley. Retrieved 2016-09-10.
  14. N. C. Hughes (February 2003). "Trilobite tagmosis and body patterning from morphological and developmental perspectives". Integrative and Comparative Biology. 43 (1): 185–206. doi:10.1093/icb/43.1.185. PMID 21680423.
  15. Akira Sakurai. "Closed and Open Circulatory System". Georgia State University. Retrieved 2016-09-10.
  16. Klaus Urich (1994). "Respiratory pigments". Comparative Animal Biochemistry. Springer. pp. 249–287. ISBN 978-3-540-57420-0.
  17. H. J. Ceccaldi. Anatomy and physiology of digestive tract of Crustaceans Decapods reared in aquaculture (PDF). Advances in Tropical Aquaculture. Tahiti Feb. 20 – March 4, 1989. AQUACOP, IFREMER. Actes de Colloque 9. pp. 243–259.
  18. Ghiselin, Michael T. (2005). "Crustacean". Encarta. Microsoft.
  19. Burkenroad, M. D. (1963). "The evolution of the Eucarida (Crustacea, Eumalacostraca), in relation to the fossil record". Tulane Studies in Geology. 2 (1): 1–17.
  20. "Crabs, lobsters, prawns and other crustaceans". Australian Museum. January 5, 2010. Retrieved 2016-09-10.
  21. "Benthic animals". Icelandic Ministry of Fisheries and Agriculture. Archived from the original on 2014-05-11. Retrieved 2016-09-10.
  22. Alan P. Covich; James H. Thorp (1991). "Crustacea: Introduction and Peracarida". In James H. Thorp; Alan P. Covich (eds.). Ecology and Classification of North American Freshwater Invertebrates (1st ed.). Academic Press. pp. 665–722. ISBN 978-0-12-690645-5. Retrieved 2016-09-10.
  23. Virtue, P. D.; Nichols, P. D.; Nicols, S. (1997). "Dietary-related mechanisms of survival in Euphasia superba: biochemical changes during long term starvation and bacteria as a possible source of nutrition.". In Bruno Battaglia; Valencia, José; Walton, D. W. H. (eds.). Antarctic communities: species, structure, and survival. Cambridge University Press. ISBN 978-0-521-48033-8. Retrieved 2016-09-10.
  24. Gollasch, Stephan (October 30, 2006). "Eriocheir sinensis" (PDF). Global Invasive Species Database. Invasive Species Specialist Group. Retrieved 2016-09-10.
  25. John J. McDermott (1999). "The western Pacific brachyuran Hemigrapsus sanguineus (Grapsidae) in its new habitat along the Atlantic coast of the United States: feeding, cheliped morphology and growth". In Schram, Frederick R.; Klein, J. C. von Vaupel (eds.). Crustaceans and the biodiversity crisis: Proceedings of the Fourth International Crustacean Congress, Amsterdam, the Netherlands, July 20–24, 1998. Koninklijke Brill. pp. 425–444. ISBN 978-90-04-11387-9. Retrieved 2016-09-10.
  26. "Crustacean (arthropod)". Encyclopædia Britannica.
  27. G. L. Pesce. "Remipedia Yager, 1981".
  28. D. E. Aiken; V. Tunnicliffe; C. T. Shih; L. D. Delorme. "Crustacean". The Canadian Encyclopedia. Retrieved 2016-09-10.
  29. Alan P. Covich; James H. Thorp (2001). "Introduction to the Subphylum Crustacea". In James H. Thorp; Alan P. Covich (eds.). Ecology and classification of North American freshwater invertebrates (2nd ed.). Academic Press. pp. 777–798. ISBN 978-0-12-690647-9. Retrieved 2016-09-10.
  30. "Zoea". Oxford English Dictionary (3rd ed.). Oxford University Press. September 2005. (Subscription or UK public library membership required.)
  31. Calman, William Thomas (1911). "Crab" . In Chisholm, Hugh (ed.). Encyclopædia Britannica. 7 (11th ed.). Cambridge University Press. p. 356.
  32. W. F. R. Weldon (July 1889). "Note on the function of the spines of the Crustacean zoœa" (PDF). Journal of the Marine Biological Association of the United Kingdom. 1 (2): 169–172. doi:10.1017/S0025315400057994. Archived from the original (PDF) on 2011-07-17.
  33. Lipke B. Holthuis (1991). "Introduction". Marine Lobsters of the World. FAO Species Catalogue, Volume 13. Food and Agriculture Organization. pp. 1–2. ISBN 978-92-5-103027-1.
  34. M. T. Brünnich (1772). Zoologiæ fundamenta prælectionibus academicis accomodata. Grunde i Dyrelaeren (in Latin and Danish). Copenhagen & Leipzig: Fridericus Christianus Pelt. pp. 1–254.
  35. Zhi-Qiang Zhang (2011). Z.-Q. Zhang (ed.). "Animal biodiversity: an outline of higher-level classification and survey of taxonomic richness - Phylum Arthropoda von Siebold, 1848" (PDF). Zootaxa. 4138: 99–103.
  36. "Crustaceans — bugs of the sea". Te Ara: The Encyclopedia of New Zealand. Ministry for Culture and Heritage. Retrieved 2016-09-10.
  37. "Japanese Spider Crabs Arrive at Aquarium". Oregon Coast Aquarium. Archived from the original on 2010-03-23. Retrieved 2016-09-10.
  38. Craig R. McClain; Alison G. Boyer (June 22, 2009). "Biodiversity and body size are linked across metazoans". Proceedings of the Royal Society B: Biological Sciences. 276 (1665): 2209–2215. doi:10.1098/rspb.2009.0245. PMC 2677615. PMID 19324730.
  39. J. Zrzavý; P. Štys (May 1997). "The basic body plan of arthropods: insights from evolutionary morphology and developmental biology". Journal of Evolutionary Biology. 10 (3): 353–367. doi:10.1046/j.1420-9101.1997.10030353.x.
  40. Jerome C. Regier; Jeffrey W. Shultz; Andreas Zwick; April Hussey; Bernard Ball; Regina Wetzer; Joel W. Martin; Clifford W. Cunningham (February 25, 2010). "Arthropod relationships revealed by phylogenomic analysis of nuclear protein-coding sequences". Nature. 463 (7284): 1079–1083. Bibcode:2010Natur.463.1079R. doi:10.1038/nature08742. PMID 20147900.
  41. Björn M. von Reumont; Ronald A. Jenner; Matthew A. Wills; Emiliano Dell'Ampio; Günther Pass; Ingo Ebersberger; Benjamin Meyer; Stefan Koenemann; Thomas M. Iliffe; Alexandros Stamatakis; Oliver Niehuis; Karen Meusemann; Bernhard Misof (March 2012). "Pancrustacean phylogeny in the light of new phylogenomic data: support for Remipedia as the possible sister group of Hexapoda". Molecular Biology and Evolution. 29 (3): 1031–1045. doi:10.1093/molbev/msr270. PMID 22049065.
  42. Joel W. Martin; George E. Davis (2001). An Updated Classification of the Recent Crustacea (PDF). Natural History Museum of Los Angeles County. pp. 1–132.
  43. "Fossil Record". Fossil Groups: Crustacea. University of Bristol. Archived from the original on 2016-09-07. Retrieved 2016-09-10.
  44. Derek Briggs (January 23, 1978). "The morphology, mode of life, and affinities of Canadaspis perfecta (Crustacea: Phyllocarida), Middle Cambrian, Burgess Shale, British Columbia". Philosophical Transactions of the Royal Society B. 281 (984): 439–487. Bibcode:1978RSPTB.281..439B. doi:10.1098/rstb.1978.0005.
  45. Matthew Olney. "Ostracods". An insight into micropalaeontology. University College, London. Retrieved 2016-09-10.
  46. Hessler, R. R. (1984). "Cephalocarida: living fossil without a fossil record". In N. Eldredge; S. M. Stanley (eds.). Living Fossils. New York: Springer Verlag. pp. 181–186. ISBN 978-3-540-90957-6.
  47. Stefan Koenemann; Frederick R. Schram; Mario Hönemann; Thomas M. Iliffe (12 April 2007). "Phylogenetic analysis of Remipedia (Crustacea)". Organisms Diversity & Evolution. 7 (1): 33–51. doi:10.1016/j.ode.2006.07.001.
  48. "Antarctic Prehistory". Australian Antarctic Division. July 29, 2008. Archived from the original on September 30, 2009. Retrieved February 25, 2010.
  49. Ronald A. Jenner; Cees H. J. Hof; Frederick R. Schram (1998). "Palaeo- and archaeostomatopods (Hoplocarida: Crustacea) from the Bear Gulch Limestone, Mississippian (Namurian), of central Montana". Contributions to Zoology. 67 (3): 155–186. doi:10.1163/18759866-06703001.
  50. Frederick Schram; Cees H. J. Hof; Royal H. Mapes & Polly Snowdon (2003). "Paleozoic cumaceans (Crustacea, Malacostraca, Peracarida) from North America". Contributions to Zoology. 72 (1): 1–16. doi:10.1163/18759866-07201001.
  51. Frederick R. Schram (August 28, 1970). "Isopod from the Pennsylvanian of Illinois". Science. 169 (3948): 854–855. Bibcode:1970Sci...169..854S. doi:10.1126/science.169.3948.854. PMID 5432581.
  52. Cees H. J. Hof (1998). "Fossil stomatopods (Crustacea: Malacostraca) and their phylogenetic impact". Journal of Natural History. 32 (10 & 11): 1567–1576. doi:10.1080/00222939800771101.
  53. Robert P. D. Crean (November 14, 2004). "Dendrobranchiata". Order Decapoda. University of Bristol. Archived from the original on February 29, 2012. Retrieved February 25, 2010.
  54. Hiroaki Karasawa; Fumio Takahashi; Eiji Doi; Hideo Ishida (2003). "First notice of the family Coleiidae Van Straelen (Crustacea: Decapoda: Eryonoides) from the upper Triassic of Japan". Paleontological Research. 7 (4): 357–362. doi:10.2517/prpsj.7.357.
  55. Fenner A. Chace Jr. & Raymond B. Manning (1972). "Two new caridean shrimps, one representing a new family, from marine pools on Ascension Island (Crustacea: Decapoda: Natantia)". Smithsonian Contributions to Zoology. 131 (131): 1–18. doi:10.5479/si.00810282.131. S2CID 53067015.
  56. J. W. Wägele (December 1989). "On the influence of fishes on the evolution of benthic crustaceans". Zeitschrift für Zoologische Systematik und Evolutionsforschung. 27 (4): 297–309. doi:10.1111/j.1439-0469.1989.tb00352.x.
  57. Baucon, A., Ronchi, A., Felletti, F., Neto de Carvalho, C. 2014. Evolution of Crustaceans at the edge of the end-Permian crisis: ichnonetwork analysis of the fluvial succession of Nurra (Permian-Triassic, Sardinia, Italy). Palaeogeography, Palaeoclimatology, Palaeoecology, 410. Abstract available fromhttp://www.tracemaker.com
  58. Dale Tshudy; W. Steven Donaldson; Christopher Collom; Rodney M. Feldmann; Carrie E. Schweitzer (2005). "Hoploparia albertaensis, a new species of clawed lobster (Nephropidae) from the Late Coniacean, shallow-marine Bad Heart Formation of northwestern Alberta, Canada". Journal of Paleontology. 79 (5): 961–968. doi:10.1666/0022-3360(2005)079[0961:HAANSO]2.0.CO;2.
  59. "FIGIS: Global Production Statistics 1950–2007". Food and Agriculture Organization. Retrieved 2016-09-10.
  60. Nicol, Steven; Endo, Yoshinari (1997). Krill Fisheries of the World. Fisheries Technical Paper. 367. Food and Agriculture Organization. ISBN 978-92-5-104012-6.

Sources

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