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Thirteen - Non-Insect Terrestrial Arthropods

Published online by Cambridge University Press:  13 April 2023

Norman Maclean
Affiliation:
University of Southampton
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Summary

Numerous non-insect limno/terrestrial arthropods appear in the IUCN Red List of Threatened Species. Nearly all arachnids and myriapods are terrestrial, but within Pancrustacea, many taxa can inhabit marine, limnic and terrestrial environments and it is not possible to easily disentangle the numbers of listed species without sorting them species by species. In some cases, as in Malacostraca, the number provided includes species inhabiting either environment, or even cases of amphidromous species that spend part of their life cycle at sea and part in rivers and streams, as is the case of many shrimp species.

Type
Chapter
Information
The Living Planet
The State of the World's Wildlife
, pp. 270 - 278
Publisher: Cambridge University Press
Print publication year: 2023

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References

Ballesteros, J.A. and Sharma, P.P. (2019) A critical appraisal of the placement of Xiphosura (Chelicerata) with account of known sources of phylogenetic error. Syst Biol 68: 896917.Google Scholar
Boyer, S.L., Baker, C.M., Popkin-Hall, Z.R., et al. (2015) Phylogeny and biogeography of the mite harvestmen (Arachnida : Opiliones : Cyphophthalmi) of Queensland, Australia, with a description of six new species from the rainforests of the Wet Tropics. Invertebr Syst 29: 3770.CrossRefGoogle Scholar
Clouse, R.M. and Giribet, G. (2010) When Thailand was an island: the phylogeny and biogeography of mite harvestmen (Opiliones, Cyphophthalmi, Stylocellidae) in Southeast Asia. J Biogeogr 37: 11141130.Google Scholar
De Grave, S., Smith, K.G., Adeleret, N.A., et al. (2015) Dead shrimp blues: a global assessment of extinction risk in freshwater shrimps (Crustacea: Decapoda: Caridea). PLoS One 10: e0120198.CrossRefGoogle Scholar
Derkarabetian, S. Burns, M., Starrett, J. and Hedin, M. (2016) Population genomic evidence for multiple Pliocene refugia in a montane-restricted harvestman (Arachnida, Opiliones, Sclerobunus robustus) from the southwestern United States. Mol Ecol 25: 46114631.Google Scholar
Drew, M.M., Harzsch, S., Stensmyr, M., Erland, S. and Hansson, B.S. (2010) A review of the biology and ecology of the Robber Crab, Birgus latro (Linnaeus, 1767) (Anomura: Coenobitidae). Zool Anz 249: 4567.CrossRefGoogle Scholar
Edgecombe, G.D., Vahtera, V., Giribet, G. and Kaunisto, P. (2015) Species limits and phylogeography of Newportia (Scolopendromorpha) and implications for widespread morphospecies. ZooKeys 510: 6577.CrossRefGoogle Scholar
Fernández, R. and Giribet, G. (2015) Unnoticed in the tropics: phylogenomic resolution of the poorly known arachnid order Ricinulei (Arachnida). Royal Soc Open Sci 2: 150065.CrossRefGoogle ScholarPubMed
Gherardi, F., Aquiloni, L., Diéguez-Uribeondo, J. and Tricarico, E. (2011) Managing invasive crayfish: is there a hope? Aquat Sci 73: 185200.Google Scholar
Giribet, G. (2018) Current views on chelicerate phylogeny – a tribute to Peter Weygoldt. Zool Anz 273: 713.CrossRefGoogle Scholar
Giribet, G. and Edgecombe, G.D. (2006) The importance of looking at small-scale patterns when inferring Gondwanan biogeography: a case study of the centipede Paralamyctes (Chilopoda, Lithobiomorpha, Henicopidae). Biol J Linn Soc 89: 6578.Google Scholar
Giribet, G. and Edgecombe, G.D. (2019) The phylogeny and evolutionary history of arthropods. Curr Biol 29: R592R602.Google Scholar
Gutekunst, J., Andriantsoa, R., Falckenhayn, C. et al. (2018) Clonal genome evolution and rapid invasive spread of the marbled crayfish. Nat Ecol Evol 2: 567573.Google Scholar
Guzik, M.T., Austin, A.D., Cooper, S.J.B., et al. (2010) Is the Australian subterranean fauna uniquely diverse? Invertebr Syst 24: 407418.Google Scholar
Harvey, M.S. (2002) Short-range endemism among the Australian fauna: some examples from non-marine environments. Invertebr Syst 16: 555570.CrossRefGoogle Scholar
Harvey, M.S., Huey, J.A., Hillyer, M.J., McIntyre, E. and Giribet, G. (2016) The first troglobitic species of Gymnobisiidae (Pseudoscorpiones : Neobisioidea), from Table Mountain (Western Cape Province, South Africa) and its phylogenetic position. Invertebr Syst 30: 7585.Google Scholar
Harvey, M.S., Rix, M.G., Framenau, V.W., et al. (2011) Protecting the innocent: studying short-range endemic taxa enhances conservation outcomes. Invertebr Syst 25: 110.Google Scholar
Harvey, M.S., York Main, B., Rix, M.G., Cooper, S.J.B. (2015) Refugia within refugia: in situ speciation and conservation of threatened Bertmainius (Araneae : Migidae), a new genus of relictual trapdoor spiders endemic to the mesic zone of south-western Australia. Invertebr Syst 29: 511553.Google Scholar
Hedin, M. and Carlson, D. (2011) A new trapdoor spider species from the southern Coast Ranges of California (Mygalomorphae, Antrodiaetidae, Aliatypus coylei, sp. nov,), including consideration of mitochondrial phylogeographic structuring. Zootaxa 2963: 5568.Google Scholar
Humphreys, W.F. (2008) Rising from Down Under: developments in subterranean biodiversity in Australia from a groundwater fauna perspective. Invertebr Syst 22: 85101.Google Scholar
Jaume, D. (2008) Global diversity of spelaeogriphaceans and thermosbaenaceans (Crustacea; Spelaeogriphacea and Thermosbaenacea) in freshwater. Hydrobiologia 595: 219224.Google Scholar
Juberthie, C. (1994) Ricinulei. In: Juberthie, C. Decu, V. (Eds.), Encyclopaedia Biospeologica. Moulis-Boucarest: Société de Biospéologie.Google Scholar
Lozano-Fernandez, J., Carton, R., Tanner, A.R., et al. (2016) A molecular palaeobiological exploration of arthropod terrestrialisation. Phil Trans Royal Soc B 371: 20150133.Google Scholar
Martens, K. (2003) On a remarkable South African giant ostracod (Crustacea, Ostracoda, Cyprididae) from temporary pools, with additional appendages. Hydrobiologia 500: 115130.Google Scholar
Morris, J.L., Puttick, M.N., Clark, J.W., et al. (2018) The timescale of early land plant evolution. Proc Natl Acad Sci USA 115: E2274E2283.Google Scholar
Mulhern, T.D. (2018) Correcting misconceptions about the names applied to Tasmania’s giant freshwater crayfish Astacopsis gouldi (Decapoda: Parastacidae). Pap Proc Royal Soc Tasmania 152: 16.Google Scholar
O’Dowd, D.J., Green, P.T. and Lake, P.S. (2003) Invasional ‘meltdown’ on an oceanic island. Ecol Lett 6: 812817.CrossRefGoogle Scholar
Rambla, M. and Juberthie, C. (1994) Opiliones. In: Juberthie, C. Decu, V. (Eds.), Encyclopaedia Biospeologica. Moulis-Boucarest: Société de Biospéologie.Google Scholar
Richart, C.H. and Hedin, M. (2016) Glacial refugia and riverine barriers: biogeography of Acuclavella (Opiliones, Ischyropsalidoidea) in Northern Idaho. Denver Mus Nat Sci Rep 3: 161.Google Scholar
Rix, M.G., Wilson, J.D., Rix, A.G., et al. (2018) Population demography and biology of a new species of giant spiny trapdoor spider (Araneae: Idiopidae: Euoplos) from inland Queensland: developing a ‘slow science’ study system to address a conservation crisis. Austral Entomol 58: 282297.Google Scholar
Schwentner, M., Combosch, D.J., Nelson, J.P. and Giribet, G. (2017) A phylogenomic solution to the origin of insects by resolving crustacean-hexapod relationships. Curr Biol 27: 18181824.CrossRefGoogle Scholar
Wesener, T. and Wägele, J.-W. (2008) The giant pill-millipedes of Madagascar: revision of the genus Zoosphaerium (Myriapoda, Diplopoda, Sphaerotheriida). Zoosystema 30: 585.Google Scholar
Wesener, T., Enghoff, H. and Sierwald, P. (2009) Review of the Spirobolida on Madagascar, with descriptions of twelve new genera, including three genera of ‘fire millipedes’ (Diplopoda). ZooKeys 19: 1128.CrossRefGoogle Scholar
Wesener, T., Minh-Tu Le, D. and Loria, S.F. (2014) Integrative revision of the giant pill-millipede genus Sphaeromimus from Madagascar, with the description of seven new species (Diplopoda, Sphaerotheriida, Arthrosphaeridae). ZooKeys 414: 67107.Google Scholar

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