Praxillinicola kroyeri M'Intosh 1885

Praxillinicola kroyeri M’Intosh, 1885 (Figs. 7–8) Praxillinicola kröyeri M’Intosh, 1885 —incorrect original spelling (ICZN Art. 32.5.2.1). Original description. M’Intosh (1885): 409, Plate XXXIX A, fig. 10. Host. Praxillella abyssorum (M’Intosh, 1885) [as Praxilla abyssorum M’Intosh, 1885] (family M...

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Main Author:	Huys, Rony
Format:	Text
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Published:	Zenodo 2016
Subjects:	Biodiversity Taxonomy Animalia Arthropoda Maxillopoda Poecilostomatoida Clausiidae Praxillinicola Praxillinicola kroyeri Arctic Antarctic Arctic Ocean Laptev Sea Pacific Antarctic Ocean Martínez Rouse Bandera Leahy Antarc* Kamchatka laptev North East Atlantic Copepods
Online Access:	https://dx.doi.org/10.5281/zenodo.6071947 https://zenodo.org/record/6071947

id	ftdatacite:10.5281/zenodo.6071947
record_format	openpolar
institution	Open Polar
collection	DataCite Metadata Store (German National Library of Science and Technology)
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language	unknown
topic	Biodiversity Taxonomy Animalia Arthropoda Maxillopoda Poecilostomatoida Clausiidae Praxillinicola Praxillinicola kroyeri
spellingShingle	Biodiversity Taxonomy Animalia Arthropoda Maxillopoda Poecilostomatoida Clausiidae Praxillinicola Praxillinicola kroyeri Huys, Rony Praxillinicola kroyeri M'Intosh 1885
topic_facet	Biodiversity Taxonomy Animalia Arthropoda Maxillopoda Poecilostomatoida Clausiidae Praxillinicola Praxillinicola kroyeri
description	Praxillinicola kroyeri M’Intosh, 1885 (Figs. 7–8) Praxillinicola kröyeri M’Intosh, 1885 —incorrect original spelling (ICZN Art. 32.5.2.1). Original description. M’Intosh (1885): 409, Plate XXXIX A, fig. 10. Host. Praxillella abyssorum (M’Intosh, 1885) [as Praxilla abyssorum M’Intosh, 1885] (family Maldanidae). Type locality. Attached to incomplete specimen of P. abyssorum trawled at H.M.S. Challenger station 157 (Antarctic Ocean); 53º55’ S, 108º35’ E; depth 1,950 fathoms (3,566 m); diatom ooze. Material examined. Holotype &female; (NHMUK reg. no. 85.12.1.305A); attached to the fifteenth segment of the holotype of P. abyssorum (NHMUK reg. no. 85.12.1.305) by “… two small processes on the under surface of the snout …” (M’Intosh 1885: 409); collected 03 March 1874. Redescription of female. Body elongate and dorsoventrally flattened (Fig. 7 A, B); consisting of cephalosome and indistinctly 5-segmented postcephalosomic trunk; total body length 2,190 µm, measured from anterior margin of rostral projection to posterior margin of abdomen (about 2.5 mm according to M’Intosh (1885)); maximum width 677 µm, measured halfway down the second postcephalosomic somite. Cephalosome bell-shaped, separated from trunk by transverse membranous zone dorsally and ventrally (Fig. 7 A, B); dorsal surface with transverse furrow, median pore and four pairs of spiniform sensilla (Fig. 8 E). Surface of cephalosome with numerous denticles and spinules as indicated in Figs. 7 A, B and 8A, B, E. Rostral projection arising from ventral surface, rounded, fused at base (Figs. 7 B; 8E). Postcephalosomic trunk probably consisting of four thoracic prosomites and undivided urosome (Fig. 7 A, B); original somitic boundaries indicated by bilateral constrictions and transverse membranous zones dorsally and laterally; membranous zone between prosome and urosome continuous ventrally but interrupted middorsally by anal slit (Fig. 8 H). Prosomites limbless, with numerous spiniform and few setiform sensilla on dorsal surface as indicated in Fig. 7 A; forming continuous unadorned sole ventrally (Fig. 7 B); fourth prosomite possibly compound as indicated by sensillar pattern. Capacious body cavity mostly filled with several hundreds of oocytes (Fig. 7 B). Urosome 1-segmented, short, representing about 10% of total body length; about 1.5 times as wide as long; with paired dorsolateral genital apertures (Figs. 7 A; 8H) near posterolateral corners, no armature discernible; ventral surface with median depression in proximal quarter, containing paired copulatory pores (with minute associated pores posteriorly) (Fig. 7 C), and patch of minute spinules in distal quarter (Fig. 7 B). Anal operculum absent; anal slit triradiate (Fig. 8 H), positioned middorsally in anterior half of urosome. Caudal rami absent. Ventral surface of cephalosome with paired anterior sockets containing vestigial antennules and antennae (Figs. 7 B; 8A, B). Antennule (Fig. 8 A–C) reduced, 1-segmented, consisting of large outer and smaller inner lobe; outer lobe with strong, medially directed, bipectinate claw; inner lobe with two short spines on posterior surface and two spiniform and two rounded extensions along outer margin. Antenna (Fig. 8 A, B, D) 2-segmented, comprising coxobasis and 1-segmented endopod. Coxobasis without armature; posterior surface with numerous minute spinules. Endopod shorter than coxobasis; apex with spinular pad; posterior surface with one short and one minute spine. Labrum (Fig. 8 E) narrow, produced into paired hook-like projections; three pairs of strong retractor muscles originating from frontal wall of cephalosome and inserting on bases of labral hooks (only one pair illustrated in Fig. 8 E). Oral opening flanked by dense spinular patches. Paragnaths, mandibles, maxillules and maxillae absent. Maxillipeds (Fig. 8 F, G) compact, located in distal third of cephalosome (Fig. 7 B); 3-segmented, comprising robust protopod (fused syncoxa and basis) and 2-segmented endopod. Protopod unarmed but with large spinous process on anterior surface, near articulation with endopod; forming concavity along palmar (medial) margin in which endopod can be withdrawn (Fig. 8 F). Enp-1 unarmed, partly fused with protopod along posterior surface (Fig. 8 G). Enp-2 narrower than enp-1; apex with spinular pad; posterior surface with two short spines. Legs 1–6 absent. Male. Unknown. Remarks. M’Intosh’s (1885) description is very brief, illustrating only the whole animal in ventral aspect (Fig. 1 B). He interpreted the body as 9-segmented but it is not clear from his illustration which body regions his “segments” relate to. The abdomen was described as having two dilated somites anteriorly, followed by four narrower ones, the last one being the genital somite presenting a “...central genital aperture”. This study revealed that the postcephalosomic trunk probably consists of four thoracic prosomites and an undivided urosome. M’Intosh identified only one pair of appendages which he equated with the antennae (or antennules) with which the copepod attaches itself to the host. From their posterior position in his habitus drawing it appears that in reality he was referring to the maxillipeds. The central projection on the anterior ventral margin referred to as the rostrum by M’Intosh (1885) is here reinterpreted as the prominent labrum. Praxillinicola kroyeri is unusual in the morphology and arrangement of its cephalosomic appendages. The paragnaths, mandibles, maxillules and maxillae are entirely absent while the strongly reduced antennules and antennae are contained within shared anterior sockets on the ventral surface of the cephalosome. Attachment to its maldanid host is secured by the maxillipeds, at least in females, and both the antennules and labral hooks probably function as auxiliary attachment organs. The distal apex of the maxilliped is blunt and modified into a distinct spinular pad as in other annelidicolous families such as the Anomoclausiidae, Clausiidae, Nereicolidae and Spiophanicolidae. The antennule of Praxillinicola is the most outstanding character of the genus. The bilobate structure of the antennule with a strong, medially directed, bipectinate claw on the outer lobe has not been observed in any other genus of the Cyclopoida. The antennule of P. kroyeri shows a remarkable, but deceiving, similarity with the appendage tentatively identified as the antenna in Phyllodicola petiti (Delamare-Deboutteville & Laubier, 1960a). Laubier’s (1961) Fig. 3 j (see also Delamare-Deboutteville & Laubier 1960a: Fig. C) shows a bilobate appendage with an outer branch consisting of two annular sclerites connected to each other by thinner areas of chitin (this condition was interpreted as 4-segmented by Boxshall & Halsey (2004)) and carrying two small claws at its tip, and an inner branch which resembles the bipectinate claw in P. kroyeri . However, Laubier’s illustration is an optical section through what appears to be a stacked series of semicircular lamellae originating from a common stalk (see his Fig. 3 h). A similar structure was observed in the second phyllodicolid genus, Cyclorhiza Heegaard, 1942 (Gotto & Leahy 1988). Apart from their morphology being radically different, the structures also cannot be positional homologues since in Praxillinicola the claw originates from the outer lobe whereas in both phyllodicolid genera the lamellate structure represents the inner branch. Unlike P. kroyeri , adult females in the family Phyllodicolidae are mesoparasitic and utilize exclusively phyllodocid polychaetes as hosts (Heegaard 1942; Delamare- Deboutteville & Laubier 1960a; Laubier 1961; Gotto & Leahy 1988; O’Reilly 2000). Polychaete hosts are infested by a range of, mostly poecilostome, families (Conradi et al. 2015). Approximately 170 species, representing 76 genera and 23 families are known to utilize polychaetes, either as ectoparasites, endoparasites or mesoparasites. None of the ectoparasitic members shows a comparable extreme reduction in body plan and segmentation as in Praxillinicola . Although the complete absence of legs 1–5 in the female is also displayed in some species of Anomopsyllus (Kim et al. 2013) and Vectoriella (Laubier & Carton 1973), these nereicolids have an inflated trunk, a 2-segmented urosome and functional caudal rami, as well as a complete suite of cephalic appendages. Despite its highly transformed body P. kroyeri has retained the plesiomorphic condition of the female genital system, with the gonopores positioned dorsolaterally and the paired copulatory pores lying close together in a depression on the midventral surface. Among the poecilostome families this condition has been reported only in the Erebonasteridae (Huys & Boxshall 1990; Humes & Huys 1992; Martínez Arbizu 1997). The presence of paired ventral copulatory pores was recently confirmed in the Serpulidicolidae (R. Huys, pers. obs.) and is probably related to the unusual ventral surface to ventral surface mating posture of the diminutive males in this family ( e.g. Southward 1964; Stock 1979). All serpulidicolids are external parasites of tubicolous, serpulid polychaetes. Although the hosts of most erebonasterids are currently unknown, at least one member is an associate of deep-sea vestimentiferan worms (Humes 1973), a group that is now considered to belong to the polychaete family Siboglinidae (Rouse 2001). Some authorities (Gotto 1979; Ho 1984) have considered the family Serpulidicolidae a member of the “Nereicoliform Group”, however, it is equally conceivable that it forms part of a different annelidicolous lineage including the Erebonasteridae and Praxellinicolidae. Maldanid polychaetes are typically, but not exclusively, utilized by members of the Clausiidae (O’Reilly 1995; Kim et al. 2013), and occasionally by species of the Clausidiidae (Bocquet et al. 1963), but it is unlikely that P. kroyeri has a close affiliation to either of these families. Based on the unique characters discussed above it is here fixed as the type of a new family, Praxillinicolidae, which has independently entered into an ectoparasitic association with maldanid hosts. : Published as part of Huys, Rony, 2016, Enigmas from the past: M'Intosh's (1885) annelidicolous copepods from the voyage of H. M. S. Challenger, pp. 355-385 in Zootaxa 4174 (1) on pages 366-370, DOI: 10.11646/zootaxa.4174.1.22, http://zenodo.org/record/262257 : {"references": ["Delamare-Deboutteville, C. & Laubier, L. (1960 a) Les Phyllocolidae, une famille nouvelle de Copepodes parasites d'Annelides Polychetes. Comptes rendus hebdomadaires des Seances de l'Academie des Sciences, Paris, 251, 2083 - 2085.", "Boxshall, G. A. & Halsey, H. S. (2004) An Introduction to Copepod Diversity. The Ray Society, London, xv + 966 pp.", "Heegaard, P. E. (1942) Cyclorhiza eteonicola n. gen., n. sp., a new parasitic copepod. Det Kongelige norske Videnskabers Selskab Forhandlinger, 15 (14), 53 - 54.", "Gotto, R. V. & Leahy, Y. (1988) A new annelidicolous copepod, Cyclorhiza megalova n. sp., with comments on its functional biology and possible phylogenetic relationships. In: Boxshall, G. A. & Schminke, H. K. (Eds.), Biology of Copepods. Proceedings of the Third International Conference on Copepoda. Hydrobiologia, 167 / 168, 533 - 538. http: // dx. doi. org / 10.1007 / BF 00026348", "Laubier, L. (1961) Phyllodicola petiti (Delamare et Laubier, 1960) et la famille des Phyllodicolidae, Copepodes parasites d'Annelides Polychetes en Mediterranee occidentale. Crustaceana, 2, 228 - 242. http: // dx. doi. org / 10.1163 / 156854061 X 00202", "O'Reilly, M. G. (2000) Notes on copepod parasites of phyllodocid polychaete worms in Scottish waters; including the first UK records of the Mediterranean copepod Phyllodicola petiti (Delamare-Deboutteville & Laubier, 1960). The Glasgow Naturalist, 23 (5), 39 - 44.", "Conradi, M., Bandera, M. E., Marin, I. & Martin, D. (2015) Polychaete-parasitizing copepods from the deep-sea Kuril - Kamchatka Trench (Pacific Ocean), with the description of a new Ophelicola species and comments on the currently known annelidicolous copepods. Deep-Sea Research Part II: Topical Studies in Oceanography, 111, 147 - 165. http: // dx. doi. org / 10.1016 / j. dsr 2.2014.08.018", "Huys, R. & Boxshall, G. A. (1990) Discovery of Centobnaster humesi, new genus, new species (Erebonasteridae), the most primitive poecilostomatoid copepod known, in New Caledonian deep waters. Journal of crustacean Biology, 10, 504 - 519. http: // dx. doi. org / 10.2307 / 1548341", "Humes, A. G. & Huys, R. (1992) Copepoda (Poecilostomatoida and Siphonostomatoida) from deep-sea hydrothermal vent areas off British Columbia, including Amphicrossus altalis, a new species of Erebonasteridae, with notes on the taxonomic position of the genus Tychidion Humes. Canadian Journal of Zoology, 70, 1369 - 1380. http: // dx. doi. org / 10.1139 / z 92 - 193", "Martinez Arbizu, P. (1997) The monophyly of Erebonasteridae, with the description of Centobnaster severnicus sp. n. (Copepoda: Poecilostomatoida) from the Laptev Sea (Arctic Ocean). Zoologischer Anzeiger, 235, 263 - 270.", "Southward, E. C. (1964) On three new cyclopoid copepods associated with deep-water polychaetes in the north-east Atlantic. Crustaceana, 6, 207 - 219. http: // dx. doi. org / 10.1163 / 156854064 X 00605", "Stock, J. H. (1979) Serpulidicolidae, a new family of Copepoda associated with tubicolous polychaetes, with descriptions of a new genus and species from the Gulf of Mexico. Memoirs of the Hourglass Cruises, 5 (2), 1 - 11", "Humes, A. G. (1973) Tychidion guyanense n. gen., n. sp. (Copepoda, Cyclopoida) associated with an annelid off Guyana. Zoologische Mededelingen, Leiden, 46, 189 - 196.", "Rouse, G. W. (2001) A cladistic analysis of Siboglinidae Caullery, 1914 (Polychaeta, Annelida): formerly the phyla Pogonophora and Vestimentifera. Zoological Journal of the Linnean Society, 132, 55 - 80. http: // dx. doi. org / 10.1111 / j. 1096 - 3642.2001. tb 02271. x", "Gotto, R. V. (1979) The association of Copepoda with marine invertebrates. Advances in marine Biology, 16, 1 - 109. http: // dx. doi. org / 10.1016 / S 0065 - 2881 (08) 60292 - 8", "Ho, J. - S. (1984) New family of poecilostomatoid copepods (Spiophanicolidae) parasitic on polychaetes from Southern California, with a phylogenetic analysis of nereicoliform families. Journal of crustacean Biology, 4, 134 - 146. http: // dx. doi. org / 10.2307 / 1547902", "O'Reilly, M. G. (1995) A new genus of copepod (Copepoda: Poecilostomatoida) commensal with the maldanid polychaete Rhodine gracilior, with a review of the family Clausiidae. Journal of natural History, 29, 47 - 64. http: // dx. doi. org / 10.1080 / 00222939500770031", "Bocquet, C., Stock, J. H. & Kleeton, G. (1963) Copepodes parasites d'invertebres des cotes de la Manche. X. Cyclopoides Poecilostomes associes aux Annelides Polychetes, dans la region de Roscoff. Archives de Zoologie experimentale et generale, 102 (notes et revue 1), 20 - 40."]}
format	Text
author	Huys, Rony
author_facet	Huys, Rony
author_sort	Huys, Rony
title	Praxillinicola kroyeri M'Intosh 1885
title_short	Praxillinicola kroyeri M'Intosh 1885
title_full	Praxillinicola kroyeri M'Intosh 1885
title_fullStr	Praxillinicola kroyeri M'Intosh 1885
title_full_unstemmed	Praxillinicola kroyeri M'Intosh 1885
title_sort	praxillinicola kroyeri m'intosh 1885
publisher	Zenodo
publishDate	2016
url	https://dx.doi.org/10.5281/zenodo.6071947 https://zenodo.org/record/6071947
long_lat	ENVELOPE(-62.183,-62.183,-64.650,-64.650) ENVELOPE(67.150,67.150,-67.750,-67.750) ENVELOPE(-67.950,-67.950,-67.183,-67.183) ENVELOPE(-118.333,-118.333,-73.833,-73.833)
geographic	Arctic Antarctic Arctic Ocean Laptev Sea Pacific Antarctic Ocean Martínez Rouse Bandera Leahy
geographic_facet	Arctic Antarctic Arctic Ocean Laptev Sea Pacific Antarctic Ocean Martínez Rouse Bandera Leahy
genre	Antarc* Antarctic Antarctic Ocean Arctic Arctic Ocean Kamchatka laptev Laptev Sea North East Atlantic Copepods
genre_facet	Antarc* Antarctic Antarctic Ocean Arctic Arctic Ocean Kamchatka laptev Laptev Sea North East Atlantic Copepods
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op_rights	Open Access Creative Commons Zero v1.0 Universal https://creativecommons.org/publicdomain/zero/1.0/legalcode cc0-1.0 info:eu-repo/semantics/openAccess
op_rightsnorm	CC0
op_doi	https://doi.org/10.5281/zenodo.6071947 https://doi.org/10.11646/zootaxa.4174.1.22 https://doi.org/10.5281/zenodo.262264 https://doi.org/10.5281/zenodo.262265 https://doi.org/10.5281/zenodo.262258 https://doi.org/10.5281/zenodo.262260 https://d
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spelling	ftdatacite:10.5281/zenodo.6071947 2023-05-15T13:54:44+02:00 Praxillinicola kroyeri M'Intosh 1885 Huys, Rony 2016 https://dx.doi.org/10.5281/zenodo.6071947 https://zenodo.org/record/6071947 unknown Zenodo http://zenodo.org/record/262257 http://publication.plazi.org/id/FF96C362FFA7FF980D18FFC4FFE6FF8C http://zoobank.org/C7196500-B74B-423D-9FE1-3EB079B7F106 https://zenodo.org/communities/biosyslit https://dx.doi.org/10.11646/zootaxa.4174.1.22 http://zenodo.org/record/262257 http://publication.plazi.org/id/FF96C362FFA7FF980D18FFC4FFE6FF8C https://dx.doi.org/10.5281/zenodo.262264 https://dx.doi.org/10.5281/zenodo.262265 https://dx.doi.org/10.5281/zenodo.262258 https://dx.doi.org/10.5281/zenodo.262260 http://zoobank.org/C7196500-B74B-423D-9FE1-3EB079B7F106 https://dx.doi.org/10.5281/zenodo.6071948 https://zenodo.org/communities/biosyslit Open Access Creative Commons Zero v1.0 Universal https://creativecommons.org/publicdomain/zero/1.0/legalcode cc0-1.0 info:eu-repo/semantics/openAccess CC0 Biodiversity Taxonomy Animalia Arthropoda Maxillopoda Poecilostomatoida Clausiidae Praxillinicola Praxillinicola kroyeri article-journal ScholarlyArticle Taxonomic treatment Text 2016 ftdatacite https://doi.org/10.5281/zenodo.6071947 https://doi.org/10.11646/zootaxa.4174.1.22 https://doi.org/10.5281/zenodo.262264 https://doi.org/10.5281/zenodo.262265 https://doi.org/10.5281/zenodo.262258 https://doi.org/10.5281/zenodo.262260 https://d 2022-04-01T10:16:28Z Praxillinicola kroyeri M’Intosh, 1885 (Figs. 7–8) Praxillinicola kröyeri M’Intosh, 1885 —incorrect original spelling (ICZN Art. 32.5.2.1). Original description. M’Intosh (1885): 409, Plate XXXIX A, fig. 10. Host. Praxillella abyssorum (M’Intosh, 1885) [as Praxilla abyssorum M’Intosh, 1885] (family Maldanidae). Type locality. Attached to incomplete specimen of P. abyssorum trawled at H.M.S. Challenger station 157 (Antarctic Ocean); 53º55’ S, 108º35’ E; depth 1,950 fathoms (3,566 m); diatom ooze. Material examined. Holotype &female; (NHMUK reg. no. 85.12.1.305A); attached to the fifteenth segment of the holotype of P. abyssorum (NHMUK reg. no. 85.12.1.305) by “… two small processes on the under surface of the snout …” (M’Intosh 1885: 409); collected 03 March 1874. Redescription of female. Body elongate and dorsoventrally flattened (Fig. 7 A, B); consisting of cephalosome and indistinctly 5-segmented postcephalosomic trunk; total body length 2,190 µm, measured from anterior margin of rostral projection to posterior margin of abdomen (about 2.5 mm according to M’Intosh (1885)); maximum width 677 µm, measured halfway down the second postcephalosomic somite. Cephalosome bell-shaped, separated from trunk by transverse membranous zone dorsally and ventrally (Fig. 7 A, B); dorsal surface with transverse furrow, median pore and four pairs of spiniform sensilla (Fig. 8 E). Surface of cephalosome with numerous denticles and spinules as indicated in Figs. 7 A, B and 8A, B, E. Rostral projection arising from ventral surface, rounded, fused at base (Figs. 7 B; 8E). Postcephalosomic trunk probably consisting of four thoracic prosomites and undivided urosome (Fig. 7 A, B); original somitic boundaries indicated by bilateral constrictions and transverse membranous zones dorsally and laterally; membranous zone between prosome and urosome continuous ventrally but interrupted middorsally by anal slit (Fig. 8 H). Prosomites limbless, with numerous spiniform and few setiform sensilla on dorsal surface as indicated in Fig. 7 A; forming continuous unadorned sole ventrally (Fig. 7 B); fourth prosomite possibly compound as indicated by sensillar pattern. Capacious body cavity mostly filled with several hundreds of oocytes (Fig. 7 B). Urosome 1-segmented, short, representing about 10% of total body length; about 1.5 times as wide as long; with paired dorsolateral genital apertures (Figs. 7 A; 8H) near posterolateral corners, no armature discernible; ventral surface with median depression in proximal quarter, containing paired copulatory pores (with minute associated pores posteriorly) (Fig. 7 C), and patch of minute spinules in distal quarter (Fig. 7 B). Anal operculum absent; anal slit triradiate (Fig. 8 H), positioned middorsally in anterior half of urosome. Caudal rami absent. Ventral surface of cephalosome with paired anterior sockets containing vestigial antennules and antennae (Figs. 7 B; 8A, B). Antennule (Fig. 8 A–C) reduced, 1-segmented, consisting of large outer and smaller inner lobe; outer lobe with strong, medially directed, bipectinate claw; inner lobe with two short spines on posterior surface and two spiniform and two rounded extensions along outer margin. Antenna (Fig. 8 A, B, D) 2-segmented, comprising coxobasis and 1-segmented endopod. Coxobasis without armature; posterior surface with numerous minute spinules. Endopod shorter than coxobasis; apex with spinular pad; posterior surface with one short and one minute spine. Labrum (Fig. 8 E) narrow, produced into paired hook-like projections; three pairs of strong retractor muscles originating from frontal wall of cephalosome and inserting on bases of labral hooks (only one pair illustrated in Fig. 8 E). Oral opening flanked by dense spinular patches. Paragnaths, mandibles, maxillules and maxillae absent. Maxillipeds (Fig. 8 F, G) compact, located in distal third of cephalosome (Fig. 7 B); 3-segmented, comprising robust protopod (fused syncoxa and basis) and 2-segmented endopod. Protopod unarmed but with large spinous process on anterior surface, near articulation with endopod; forming concavity along palmar (medial) margin in which endopod can be withdrawn (Fig. 8 F). Enp-1 unarmed, partly fused with protopod along posterior surface (Fig. 8 G). Enp-2 narrower than enp-1; apex with spinular pad; posterior surface with two short spines. Legs 1–6 absent. Male. Unknown. Remarks. M’Intosh’s (1885) description is very brief, illustrating only the whole animal in ventral aspect (Fig. 1 B). He interpreted the body as 9-segmented but it is not clear from his illustration which body regions his “segments” relate to. The abdomen was described as having two dilated somites anteriorly, followed by four narrower ones, the last one being the genital somite presenting a “...central genital aperture”. This study revealed that the postcephalosomic trunk probably consists of four thoracic prosomites and an undivided urosome. M’Intosh identified only one pair of appendages which he equated with the antennae (or antennules) with which the copepod attaches itself to the host. From their posterior position in his habitus drawing it appears that in reality he was referring to the maxillipeds. The central projection on the anterior ventral margin referred to as the rostrum by M’Intosh (1885) is here reinterpreted as the prominent labrum. Praxillinicola kroyeri is unusual in the morphology and arrangement of its cephalosomic appendages. The paragnaths, mandibles, maxillules and maxillae are entirely absent while the strongly reduced antennules and antennae are contained within shared anterior sockets on the ventral surface of the cephalosome. Attachment to its maldanid host is secured by the maxillipeds, at least in females, and both the antennules and labral hooks probably function as auxiliary attachment organs. The distal apex of the maxilliped is blunt and modified into a distinct spinular pad as in other annelidicolous families such as the Anomoclausiidae, Clausiidae, Nereicolidae and Spiophanicolidae. The antennule of Praxillinicola is the most outstanding character of the genus. The bilobate structure of the antennule with a strong, medially directed, bipectinate claw on the outer lobe has not been observed in any other genus of the Cyclopoida. The antennule of P. kroyeri shows a remarkable, but deceiving, similarity with the appendage tentatively identified as the antenna in Phyllodicola petiti (Delamare-Deboutteville & Laubier, 1960a). Laubier’s (1961) Fig. 3 j (see also Delamare-Deboutteville & Laubier 1960a: Fig. C) shows a bilobate appendage with an outer branch consisting of two annular sclerites connected to each other by thinner areas of chitin (this condition was interpreted as 4-segmented by Boxshall & Halsey (2004)) and carrying two small claws at its tip, and an inner branch which resembles the bipectinate claw in P. kroyeri . However, Laubier’s illustration is an optical section through what appears to be a stacked series of semicircular lamellae originating from a common stalk (see his Fig. 3 h). A similar structure was observed in the second phyllodicolid genus, Cyclorhiza Heegaard, 1942 (Gotto & Leahy 1988). Apart from their morphology being radically different, the structures also cannot be positional homologues since in Praxillinicola the claw originates from the outer lobe whereas in both phyllodicolid genera the lamellate structure represents the inner branch. Unlike P. kroyeri , adult females in the family Phyllodicolidae are mesoparasitic and utilize exclusively phyllodocid polychaetes as hosts (Heegaard 1942; Delamare- Deboutteville & Laubier 1960a; Laubier 1961; Gotto & Leahy 1988; O’Reilly 2000). Polychaete hosts are infested by a range of, mostly poecilostome, families (Conradi et al. 2015). Approximately 170 species, representing 76 genera and 23 families are known to utilize polychaetes, either as ectoparasites, endoparasites or mesoparasites. None of the ectoparasitic members shows a comparable extreme reduction in body plan and segmentation as in Praxillinicola . Although the complete absence of legs 1–5 in the female is also displayed in some species of Anomopsyllus (Kim et al. 2013) and Vectoriella (Laubier & Carton 1973), these nereicolids have an inflated trunk, a 2-segmented urosome and functional caudal rami, as well as a complete suite of cephalic appendages. Despite its highly transformed body P. kroyeri has retained the plesiomorphic condition of the female genital system, with the gonopores positioned dorsolaterally and the paired copulatory pores lying close together in a depression on the midventral surface. Among the poecilostome families this condition has been reported only in the Erebonasteridae (Huys & Boxshall 1990; Humes & Huys 1992; Martínez Arbizu 1997). The presence of paired ventral copulatory pores was recently confirmed in the Serpulidicolidae (R. Huys, pers. obs.) and is probably related to the unusual ventral surface to ventral surface mating posture of the diminutive males in this family ( e.g. Southward 1964; Stock 1979). All serpulidicolids are external parasites of tubicolous, serpulid polychaetes. Although the hosts of most erebonasterids are currently unknown, at least one member is an associate of deep-sea vestimentiferan worms (Humes 1973), a group that is now considered to belong to the polychaete family Siboglinidae (Rouse 2001). Some authorities (Gotto 1979; Ho 1984) have considered the family Serpulidicolidae a member of the “Nereicoliform Group”, however, it is equally conceivable that it forms part of a different annelidicolous lineage including the Erebonasteridae and Praxellinicolidae. Maldanid polychaetes are typically, but not exclusively, utilized by members of the Clausiidae (O’Reilly 1995; Kim et al. 2013), and occasionally by species of the Clausidiidae (Bocquet et al. 1963), but it is unlikely that P. kroyeri has a close affiliation to either of these families. Based on the unique characters discussed above it is here fixed as the type of a new family, Praxillinicolidae, which has independently entered into an ectoparasitic association with maldanid hosts. : Published as part of Huys, Rony, 2016, Enigmas from the past: M'Intosh's (1885) annelidicolous copepods from the voyage of H. M. S. 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Archives de Zoologie experimentale et generale, 102 (notes et revue 1), 20 - 40."]} Text Antarc* Antarctic Antarctic Ocean Arctic Arctic Ocean Kamchatka laptev Laptev Sea North East Atlantic Copepods DataCite Metadata Store (German National Library of Science and Technology) Arctic Antarctic Arctic Ocean Laptev Sea Pacific Antarctic Ocean Martínez ENVELOPE(-62.183,-62.183,-64.650,-64.650) Rouse ENVELOPE(67.150,67.150,-67.750,-67.750) Bandera ENVELOPE(-67.950,-67.950,-67.183,-67.183) Leahy ENVELOPE(-118.333,-118.333,-73.833,-73.833)

Praxillinicola kroyeri M'Intosh 1885

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