Caligus undulatus

Caligus undulatus : cosmopolitan pelagic caligid Caligus undulatus was first described by Shen & Li (1959) from coastal plankton samples of Qingdao (Tsingtao) Harbour, eastern China. Subsequent pelagic records of this species came from India (Pillai 1966), Brazil (Montú 1982), Japan, Korea (Venm...

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Main Authors: Maran, Balu Alagar Venmathi, Suárez-Morales, Eduardo, Ohtsuka, Susumu, Soh, Ho Young, Hwang, Ui Wook
Format: Text
Language:unknown
Published: Zenodo 2016
Subjects:
Online Access:https://dx.doi.org/10.5281/zenodo.5625652
https://zenodo.org/record/5625652
id ftdatacite:10.5281/zenodo.5625652
record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic Biodiversity
Taxonomy
Animalia
Arthropoda
Maxillopoda
Siphonostomatoida
Caligidae
Caligus
Caligus undulatus
spellingShingle Biodiversity
Taxonomy
Animalia
Arthropoda
Maxillopoda
Siphonostomatoida
Caligidae
Caligus
Caligus undulatus
Maran, Balu Alagar Venmathi
Suárez-Morales, Eduardo
Ohtsuka, Susumu
Soh, Ho Young
Hwang, Ui Wook
Caligus undulatus
topic_facet Biodiversity
Taxonomy
Animalia
Arthropoda
Maxillopoda
Siphonostomatoida
Caligidae
Caligus
Caligus undulatus
description Caligus undulatus : cosmopolitan pelagic caligid Caligus undulatus was first described by Shen & Li (1959) from coastal plankton samples of Qingdao (Tsingtao) Harbour, eastern China. Subsequent pelagic records of this species came from India (Pillai 1966), Brazil (Montú 1982), Japan, Korea (Venmathi Maran & Ohtsuka 2008; Venmathi Maran unpubl. data) and Mexico (Suárez- Morales et al. 2012a). Generally, caligid females are larger than males, but in C. undulatus , males have a much larger body size than females; this unusual size sexual dimorphism remained unnoticed until the recent discovery of the species in Korean waters (Moon et al. unpubl. data). The adult female of C. undulatus from Korea is larger (4.46 mm) (Moon et al. unpubl. data) than previously reported specimens (Shen & Li 1959; Venmathi Maran & Ohtsuka 2008; Venmathi Maran et al. 2012a). The Korean adult male (4.61 mm) (Moon et al. unpubl. data) is much larger than specimens from China (3.08 mm) (Shen & Li 1959), India (3.50 mm) (Pillai 1966), Japan (3.50 mm), Korea (3.52 mm) (Venmathi Maran & Ohtsuka 2008) and Mexico (2.82 mm) (Suárez-Morales et al. 2012a). Its wide size range (2.82- 4.61 mm) might reflect the geographical variability of the species. This peculiar feature of larger males has been reported in ca. 20 caligid species (Ho & Lin 2004a). Until now, all reports of C. undulatus were based on specimens collected from plankton samples (Shen & Li 1959; Pillai 1966, 1985; Venmathi Maran & Ohtsuka 2008; Suárez-Morales et al. 2012a; Venmathi Maran et al. 2012a, b) (Table 2), but it has not yet been recorded from a fish host. Since it has been sighted in widely separated geographic areas, it is conceivable that its fish host is highly migratory (Ho & Lin 2004b; Venmathi Maran & Ohtsuka 2008). The recent finding of C. undulatus (Moon et al. unpubl. data) is the second record of this species in Korean waters. A detailed parasitological survey of the fish hosts in this country but also in other East Asian countries (China, Japan, Philippines, Taiwan) is required to help understanding the host-parasite dynamics of this widespread caligid. Since C. undulatus is a common zooplankter in coastal waters around the world it could potentially serve as a good model to elucidate the caligid life cycle, even though its host is as yet unknown. C. longiramus Venmathi Maran, Ohtsuka & Jitchum, 2012 ♀ Japan Venmathi Maran et al. (2012b) C. ogawai Venmathi Maran, Ohtsuka & Shang, 2012 ♀, ♂ Japan Venmathi Maran et al. (2012c) C. quadrigenitalis Venmathi Maran, Ohtsuka & Shang, ♀ Japan Venmathi Maran et al. (2012c) 2012 The family Caligidae currently comprises ca. 450 valid species (Dojiri & Ho 2013), but information on the complete life cycle is only available for 18 species of Caligus (13 species) and Lepeophtheirus (five species) (Dojiri & Ho 2013; Venmathi Maran et al. 2013). The life cycle comprises eight stages, including two free-living naupliar stages, one infective copepodid followed by either four chalimus stages and the adult (in Caligus ) or two chalimus stages, two preadult stages and the adult (in Lepeophtheirus ) (Venmathi Maran et al. 2013). Upon location of a suitable host the infective copepodid attaches itself by means of a frontal filament. This structure is considered an evolutionary novelty exhibited by many siphonostomatoids associated with vertebrate (Piasecki & MacKinnon 1993) and invertebrate hosts (Ohtsuka et al. 2007). Traditionally, it was assumed that the filament remained permanently attached to the host during the chalimus phase. However, we found free-living chalimus stages in plankton samples, especially in areas adjacent to aquaculture facilities, and identified the developmental stages based solely on the morphology of the frontal filament. The number of extension lobes on the frontal filament of caligids are consistent with other features of the chalimus stages and can be used as a character to distinguish between successive stages (Huys 2014). In the Caligidae, the formation and development of the frontal filament during molting follows two different patterns, the multi-node type (found in Caligus ) or the singlenode type (in Lepeophtheirus ) (Ohtsuka et al. 2009). Several works have reported the presence of developmental stages (chalimi) of Lepeophtheirus salmonis (Krøyer, 1837) in plankton samples adjacent to aquaculture facilities in Europe (Copley et al. 2005; Costello et al . 1998a, b; Penston et al . 2004; 2011). A study by Hull et al. (1998) revealed that L. salmonis can easily transfer from one host individual to another. Adults of Caligus sclerotinosus were collected in plankton samples off aquaculture facilities in Japan (Venmathi & Ohtsuka 2008) and Korea (unpubl. data) while copepodids of L. elegans Gusev, 1951 were collected around aquaculture facilities in Korea (unpubl. data). These data confirm that developmental stages of caligids are frequently found in the plankton but the discovery of adults in the water column is less easily explainable. This pattern might also be applicable to the life cycle of some species of the cyclopoid families Ergasilidae (Ohtsuka et al. 2004) and Lernaeidae (Piasecki et al. 2004), both which utilize freshwater and brackish-water fish hosts. In contrast to caligiforms, the ergasilid life cycle involves six copepodid stages, the final one being the adult. All adult males die after mating in the water column, whereas only postmated adult females remain permanently or temporarily attached to the hosts. This strategy explains the presence of adult females in the plankton. These freeswimming ergasilid females were misidentified as members of the planktonic genus Limnoncaea Kokubo, 1914 before its rejection as a valid taxon (Ohtsuka et al. 2004) (similar to the pandarid genus Nogaus cf. Boxshall & Halsey 2004). These temporarily planktonic females tend to carry fewer eggs per egg sac compared to congeners which remain permanently attached to the host. Modifications of the body and appendages occur in adults of some ergasilids and lernaeids, but not in these presumably planktonic taxa (Ohtsuka et al. 2004; Piasecki et al. 2004). Thus, pelagic adults are likely to be common in the life cycle of caligiform copepods but the adaptive benefits of free-living adults detached from their hosts needs to be studied through laboratory experiments (Venmathi Maran & Ohtsuka 2008; Venmathi Maran et al. 2012a). : Published as part of Maran, Balu Alagar Venmathi, Suárez-Morales, Eduardo, Ohtsuka, Susumu, Soh, Ho Young & Hwang, Ui Wook, 2016, On the occurrence of caligids (Copepoda: Siphonostomatoida) in the marine plankton: a review and checklist, pp. 437-447 in Zootaxa 4174 (1) on pages 440-442, DOI: 10.11646/zootaxa.4174.1.27, http://zenodo.org/record/160209 : {"references": ["Shen, C. - j. & Li, H. - l. (1959). Parasitic copepods from fishes of China, IV. Caligoida. Caligidae (3). Acta zoologica sinica, 11, 12 - 20 (In Chinese with English summary).", "Pillai, N. K. (1966) Notes on copepods parasitic on South Indian marine fishes. Journal of the marine biological Association of India, 8, 123 - 140.", "Montu, M. (1982) Alguns copepodos parasitas de peixes do sul do Brasil. Arquivos de Biologia e Tecnologia, 25, 329 - 339.", "Venmathi Maran, B. A. & Ohtsuka, S. (2008) Description of caligiform copepods in plankton samples collected from East Asia: Accidental occurrences or a new mode of life cycle? Plankton Benthos Research, 3, 202 - 215. http: // dx. doi. org / 10.3800 / pbr. 3.202", "Venmathi Maran, B. A., Oh, S-Y., Soh, H. Y., Choi H. J. & Myoung, J. - G. (2012 a) Caligus sclerotinosus (Copepoda: Caligidae), a serious pest of cultured red seabream Pagrus major (Sparidae) in Korea. Veterinary Parasitology, 188, 355 - 361. http: // dx. doi. org / 10.1016 / j. vetpar. 2012.03.023", "Suarez-Morales, E., Camisotti, H. & Martin, A. (2012 a) A new species of Caligus (Copepoda, Siphonostomatoida) from the plankton of the Caribbean coast of Venezuela with a key to species. Zookeys, 201, 59 - 71. http: // dx. doi. org / 10.3897 / zookeys. 201.3099", "Ho, J. - s. & Lin, C. - L. (2004 a) Sea Lice of Taiwan (Copepoda: Siphonostomatoida: Caligidae). The Sueichan Press, Keelung, 388 pp.", "Pillai, N. K. (1985) The Fauna of India. Copepod Parasites of marine Fishes. Zoological Society of India, Calcutta, 900 pp.", "Venmathi Maran, B. A., Ohtsuka, S. & Jitchum, P. (2012 b) Occurrence of caligid copepods (Crustacea) in plankton samples collected from Japan and Thailand, with the description of a new species. Species Diversity, 17, 87 - 95. http: // dx. doi. org / 10.12782 / sd. 17.1.087", "Ho, J. - s. & Lin, C. - L. (2004 b) Caligus planktonis Pillai (Copepoda: Siphonostomatoida) parasitic on the large scale mullet of Taiwan. Crustaceana, 76, 1201 - 1209. http: // dx. doi. org / 10.1163 / 156854003773123438", "Venmathi Maran, B. A., Ohtsuka, S. & Shang, X. (2012 c) Records of adult caligiform copepods (Crustacea: Copepoda: Siphonostomatoida) in marine plankton from East Asia, including descriptions of two new species of Caligus (Caligidae). Species Diversity, 17, 201 - 219. http: // dx. doi. org / 10.12782 / sd. 17.2.201", "Dojiri, M. & Ho, J. - s. (2013). Systematics of the Caligidae, copepods parasitic on marine fishes. Crustaceana Monograph Series, 18, 448 pp. http: // dx. doi. org / 10.1163 / 9789004204256 _ 014", "Venmathi Maran, B. A., Moon, S. Y., Ohtsuka, S., Oh, S-Y., Soh, H. Y., Myoung, J. - G., Iglikowska, A. & Boxshall, G. A. (2013) The caligid life cycle: new evidence from Lepeophtheirus elegans reconciles the cycles of Caligus and Lepeophtheirus (Copepoda: Caligidae). Parasite, 20, 15. http: // dx. doi. org / 10.1051 / parasite / 2013015", "Piasecki, W. & MacKinnon, B. M. (1993) Changes in structure of the frontal filament in sequential developmental stages of Caligus elongatus von Nordmann, 1832 (Crustacea, Copepoda, Siphonostomatoida). Canadian Journal of Zoology, 71, 889 - 895. http: // dx. doi. org / 10.1139 / z 93 - 116", "Ohtsuka, S., Harada, S., Shimomura, M., Boxshall, G. A., Yoshizaki, R., Ueno, D., Nitta, Y., Iwasaki, S., Okawachi, H. & Sakahira, T. (2007) Temporal partitioning: dynamics of alternating occupancy of a host microhabitat by two different crustacean parasites. Marine Ecology Progress Series, 348, 261 - 272. http: // dx. doi. org / 10.3354 / meps 07096", "Huys, R. (2014) Copepoda. In: Martin, J. W., Olesen, J. & Hoeg, J. T. (Eds.), Atlas of Crustacean Larvae. John Hopkins University Press, Baltimore, pp. 144 - 164.", "Ohtsuka, S., Takami, I., Venmathi Maran, B. A., Ogawa, K., Shimono, T., Fujita, Y., Asakawa, M. & Boxshall, G. A. (2009) Developmental stages and growth of Pseudocaligus fugu Yamaguti, 1936 (Copepoda: Siphonostomatoida: Caligidae) host-specific to Puffer. Journal of natural History, 43, 1779 - 1804. http: // dx. doi. org / 10.1080 / 00222930902993757", "Kroyer, H. (1837) Om Snyltekrebsene, isaer med Hensyn til den danske Fauna. Naturhistorisk Tidsskrift, 1 (2), 172 - 208 [1 (3), 252 - 304; 1 (5), 476 - 504; 1 (6), 605 - 628; 2 (1), 8 - 25, 131 - 157].", "Copley, L., Tierney, T. D., Kane, F., Naughton, O., Kennedy, S., O'Donhoe, P., Jackson, D. & McGrath, D. (2005) Sea lice, Lepeophtheirus salmonis and Caligus elongatus, levels on salmon returning to the west coast of Ireland. Journal of the marine biological Association of the United Kingdom, 85, 87 - 92. http: // dx. doi. org / 10.1017 / S 0025315405010878 h", "Penston, M. J., McKibben, M. A., Hay, D. W. & Gillibrand, P. A. (2004) Observations on open-water densities of sea lice larvae in Loch Shieldaig, Western Scotland. Aquacultural Research, 35, 793 - 805. http: // dx. doi. org / 10.1111 / j. 1365 - 2109.2004.01102. x", "Penston, M. J., McBeath, A. J. A. & Millar, C. P. (2011) Densities of planktonic Lepeophtheirus salmonis before and after Atlantic salmon farm relocation. Aquaculture Environment Interactions, 1, 225 - 232. http: // dx. doi. org / 10.3354 / aei 00022", "Hull, M. Q., Pike, A. W., Mordue, A. J. & Rae, G. H. (1998) Patterns of pair formation and mating in an ectoparasitic caligid copepod Lepeophtheirus salmonis (Kroyer, 1837): implications for its sensory and mating biology. Philosophical Transactions of the Royal Society London, 353, 753 - 764. http: // dx. doi. org / 10.1098 / rstb. 1998.0241", "Gusev, A. V. (1951) Paraziticheskie Copepoda s nekotorykh morskikh ryb. Parazitologicheskij Sbornik, 13, 394 - 463 (In Russian).", "Ohtsuka, S., Ho, J. - s. & Nagasawa, K. (2004) Ergasilid copepods (Poecilostomatoida) in plankton samples from Hokkaido, Japan with reconsideration of the taxonomic status of Limnoncaea Kokubo, 1914. Journal of natural History, 38, 471 - 498. http: // dx. doi. org / 10.1080 / 0022293021000034778", "Piasecki, W., Goodwin, A. E., Eiras, J. C. & Nowak, B. F. (2004) Importance of Copepoda in freshwater aquaculture. Zoological Studies, 43, 193 - 205.", "Kokubo, S. (1914) Emendation of the scope of family Oncaeidae with description of one new genus and three new species. Zoological Magazine, Tokyo, 16, 533 - 541.", "Boxshall, G. A. & Halsey, S. H. (2004) An Introduction to Copepod Diversity. The Ray Society, London, xv + 966 pp."]}
format Text
author Maran, Balu Alagar Venmathi
Suárez-Morales, Eduardo
Ohtsuka, Susumu
Soh, Ho Young
Hwang, Ui Wook
author_facet Maran, Balu Alagar Venmathi
Suárez-Morales, Eduardo
Ohtsuka, Susumu
Soh, Ho Young
Hwang, Ui Wook
author_sort Maran, Balu Alagar Venmathi
title Caligus undulatus
title_short Caligus undulatus
title_full Caligus undulatus
title_fullStr Caligus undulatus
title_full_unstemmed Caligus undulatus
title_sort caligus undulatus
publisher Zenodo
publishDate 2016
url https://dx.doi.org/10.5281/zenodo.5625652
https://zenodo.org/record/5625652
long_lat ENVELOPE(-63.038,-63.038,-73.952,-73.952)
ENVELOPE(65.468,65.468,-70.877,-70.877)
ENVELOPE(-55.833,-55.833,-63.000,-63.000)
ENVELOPE(-62.833,-62.833,-65.100,-65.100)
ENVELOPE(-145.700,-145.700,-86.450,-86.450)
ENVELOPE(-57.917,-57.917,-61.950,-61.950)
ENVELOPE(43.341,43.341,66.102,66.102)
ENVELOPE(-64.699,-64.699,-75.389,-75.389)
geographic Indian
Kane
McGrath
Morales
Goodwin
Suarez
Nowak
Gusev
McKibben
geographic_facet Indian
Kane
McGrath
Morales
Goodwin
Suarez
Nowak
Gusev
McKibben
genre Atlantic salmon
Copepods
genre_facet Atlantic salmon
Copepods
op_relation http://zenodo.org/record/160209
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http://zoobank.org/B00644D4-CB2F-47E4-AA9C-A5CE2A46BA52
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http://zenodo.org/record/160209
http://publication.plazi.org/id/FF9E0309A063FFF2FFB8FF97FFBFFF9D
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op_rights Open Access
info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.5281/zenodo.5625652
https://doi.org/10.11646/zootaxa.4174.1.27
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spelling ftdatacite:10.5281/zenodo.5625652 2023-05-15T15:33:12+02:00 Caligus undulatus Maran, Balu Alagar Venmathi Suárez-Morales, Eduardo Ohtsuka, Susumu Soh, Ho Young Hwang, Ui Wook 2016 https://dx.doi.org/10.5281/zenodo.5625652 https://zenodo.org/record/5625652 unknown Zenodo http://zenodo.org/record/160209 http://publication.plazi.org/id/FF9E0309A063FFF2FFB8FF97FFBFFF9D http://zoobank.org/B00644D4-CB2F-47E4-AA9C-A5CE2A46BA52 https://zenodo.org/communities/biosyslit https://dx.doi.org/10.11646/zootaxa.4174.1.27 http://zenodo.org/record/160209 http://publication.plazi.org/id/FF9E0309A063FFF2FFB8FF97FFBFFF9D http://zoobank.org/B00644D4-CB2F-47E4-AA9C-A5CE2A46BA52 https://dx.doi.org/10.5281/zenodo.5625653 https://zenodo.org/communities/biosyslit Open Access info:eu-repo/semantics/openAccess Biodiversity Taxonomy Animalia Arthropoda Maxillopoda Siphonostomatoida Caligidae Caligus Caligus undulatus Taxonomic treatment article-journal Text ScholarlyArticle 2016 ftdatacite https://doi.org/10.5281/zenodo.5625652 https://doi.org/10.11646/zootaxa.4174.1.27 https://doi.org/10.5281/zenodo.5625653 2022-02-08T12:40:44Z Caligus undulatus : cosmopolitan pelagic caligid Caligus undulatus was first described by Shen & Li (1959) from coastal plankton samples of Qingdao (Tsingtao) Harbour, eastern China. Subsequent pelagic records of this species came from India (Pillai 1966), Brazil (Montú 1982), Japan, Korea (Venmathi Maran & Ohtsuka 2008; Venmathi Maran unpubl. data) and Mexico (Suárez- Morales et al. 2012a). Generally, caligid females are larger than males, but in C. undulatus , males have a much larger body size than females; this unusual size sexual dimorphism remained unnoticed until the recent discovery of the species in Korean waters (Moon et al. unpubl. data). The adult female of C. undulatus from Korea is larger (4.46 mm) (Moon et al. unpubl. data) than previously reported specimens (Shen & Li 1959; Venmathi Maran & Ohtsuka 2008; Venmathi Maran et al. 2012a). The Korean adult male (4.61 mm) (Moon et al. unpubl. data) is much larger than specimens from China (3.08 mm) (Shen & Li 1959), India (3.50 mm) (Pillai 1966), Japan (3.50 mm), Korea (3.52 mm) (Venmathi Maran & Ohtsuka 2008) and Mexico (2.82 mm) (Suárez-Morales et al. 2012a). Its wide size range (2.82- 4.61 mm) might reflect the geographical variability of the species. This peculiar feature of larger males has been reported in ca. 20 caligid species (Ho & Lin 2004a). Until now, all reports of C. undulatus were based on specimens collected from plankton samples (Shen & Li 1959; Pillai 1966, 1985; Venmathi Maran & Ohtsuka 2008; Suárez-Morales et al. 2012a; Venmathi Maran et al. 2012a, b) (Table 2), but it has not yet been recorded from a fish host. Since it has been sighted in widely separated geographic areas, it is conceivable that its fish host is highly migratory (Ho & Lin 2004b; Venmathi Maran & Ohtsuka 2008). The recent finding of C. undulatus (Moon et al. unpubl. data) is the second record of this species in Korean waters. A detailed parasitological survey of the fish hosts in this country but also in other East Asian countries (China, Japan, Philippines, Taiwan) is required to help understanding the host-parasite dynamics of this widespread caligid. Since C. undulatus is a common zooplankter in coastal waters around the world it could potentially serve as a good model to elucidate the caligid life cycle, even though its host is as yet unknown. C. longiramus Venmathi Maran, Ohtsuka & Jitchum, 2012 ♀ Japan Venmathi Maran et al. (2012b) C. ogawai Venmathi Maran, Ohtsuka & Shang, 2012 ♀, ♂ Japan Venmathi Maran et al. (2012c) C. quadrigenitalis Venmathi Maran, Ohtsuka & Shang, ♀ Japan Venmathi Maran et al. (2012c) 2012 The family Caligidae currently comprises ca. 450 valid species (Dojiri & Ho 2013), but information on the complete life cycle is only available for 18 species of Caligus (13 species) and Lepeophtheirus (five species) (Dojiri & Ho 2013; Venmathi Maran et al. 2013). The life cycle comprises eight stages, including two free-living naupliar stages, one infective copepodid followed by either four chalimus stages and the adult (in Caligus ) or two chalimus stages, two preadult stages and the adult (in Lepeophtheirus ) (Venmathi Maran et al. 2013). Upon location of a suitable host the infective copepodid attaches itself by means of a frontal filament. This structure is considered an evolutionary novelty exhibited by many siphonostomatoids associated with vertebrate (Piasecki & MacKinnon 1993) and invertebrate hosts (Ohtsuka et al. 2007). Traditionally, it was assumed that the filament remained permanently attached to the host during the chalimus phase. However, we found free-living chalimus stages in plankton samples, especially in areas adjacent to aquaculture facilities, and identified the developmental stages based solely on the morphology of the frontal filament. The number of extension lobes on the frontal filament of caligids are consistent with other features of the chalimus stages and can be used as a character to distinguish between successive stages (Huys 2014). In the Caligidae, the formation and development of the frontal filament during molting follows two different patterns, the multi-node type (found in Caligus ) or the singlenode type (in Lepeophtheirus ) (Ohtsuka et al. 2009). Several works have reported the presence of developmental stages (chalimi) of Lepeophtheirus salmonis (Krøyer, 1837) in plankton samples adjacent to aquaculture facilities in Europe (Copley et al. 2005; Costello et al . 1998a, b; Penston et al . 2004; 2011). A study by Hull et al. (1998) revealed that L. salmonis can easily transfer from one host individual to another. Adults of Caligus sclerotinosus were collected in plankton samples off aquaculture facilities in Japan (Venmathi & Ohtsuka 2008) and Korea (unpubl. data) while copepodids of L. elegans Gusev, 1951 were collected around aquaculture facilities in Korea (unpubl. data). These data confirm that developmental stages of caligids are frequently found in the plankton but the discovery of adults in the water column is less easily explainable. This pattern might also be applicable to the life cycle of some species of the cyclopoid families Ergasilidae (Ohtsuka et al. 2004) and Lernaeidae (Piasecki et al. 2004), both which utilize freshwater and brackish-water fish hosts. In contrast to caligiforms, the ergasilid life cycle involves six copepodid stages, the final one being the adult. All adult males die after mating in the water column, whereas only postmated adult females remain permanently or temporarily attached to the hosts. This strategy explains the presence of adult females in the plankton. These freeswimming ergasilid females were misidentified as members of the planktonic genus Limnoncaea Kokubo, 1914 before its rejection as a valid taxon (Ohtsuka et al. 2004) (similar to the pandarid genus Nogaus cf. Boxshall & Halsey 2004). These temporarily planktonic females tend to carry fewer eggs per egg sac compared to congeners which remain permanently attached to the host. Modifications of the body and appendages occur in adults of some ergasilids and lernaeids, but not in these presumably planktonic taxa (Ohtsuka et al. 2004; Piasecki et al. 2004). Thus, pelagic adults are likely to be common in the life cycle of caligiform copepods but the adaptive benefits of free-living adults detached from their hosts needs to be studied through laboratory experiments (Venmathi Maran & Ohtsuka 2008; Venmathi Maran et al. 2012a). : Published as part of Maran, Balu Alagar Venmathi, Suárez-Morales, Eduardo, Ohtsuka, Susumu, Soh, Ho Young & Hwang, Ui Wook, 2016, On the occurrence of caligids (Copepoda: Siphonostomatoida) in the marine plankton: a review and checklist, pp. 437-447 in Zootaxa 4174 (1) on pages 440-442, DOI: 10.11646/zootaxa.4174.1.27, http://zenodo.org/record/160209 : {"references": ["Shen, C. - j. & Li, H. - l. (1959). Parasitic copepods from fishes of China, IV. Caligoida. Caligidae (3). Acta zoologica sinica, 11, 12 - 20 (In Chinese with English summary).", "Pillai, N. K. (1966) Notes on copepods parasitic on South Indian marine fishes. Journal of the marine biological Association of India, 8, 123 - 140.", "Montu, M. 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Zoological Studies, 43, 193 - 205.", "Kokubo, S. (1914) Emendation of the scope of family Oncaeidae with description of one new genus and three new species. Zoological Magazine, Tokyo, 16, 533 - 541.", "Boxshall, G. A. & Halsey, S. H. (2004) An Introduction to Copepod Diversity. The Ray Society, London, xv + 966 pp."]} Text Atlantic salmon Copepods DataCite Metadata Store (German National Library of Science and Technology) Indian Kane ENVELOPE(-63.038,-63.038,-73.952,-73.952) McGrath ENVELOPE(65.468,65.468,-70.877,-70.877) Morales ENVELOPE(-55.833,-55.833,-63.000,-63.000) Goodwin ENVELOPE(-62.833,-62.833,-65.100,-65.100) Suarez ENVELOPE(-145.700,-145.700,-86.450,-86.450) Nowak ENVELOPE(-57.917,-57.917,-61.950,-61.950) Gusev ENVELOPE(43.341,43.341,66.102,66.102) McKibben ENVELOPE(-64.699,-64.699,-75.389,-75.389)