Radicipes gracilis 1884

Radicipes gracilis (Verrill, 1884) Figs. 2 E–F, 9, 10 Lepidogorgia gracilis Verrill, 1884: 220; 1885: 512, 533, pl. 2, fig. 10, 10a.—VerSluyS, 1902: 16.— ThomSon & HenderSon, 1906: 27 (tabular key). Strophogorgia fragilis Wright & Studer, 1889: 4, pl. 2, fig. 2, pl. 5a. fig. 4. Lepidogorgia...

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Bibliographic Details
Main Author: Perez, Carlos D.
Format: Text
Language:unknown
Published: Zenodo 2017
Subjects:
Biodiversity
Taxonomy
Animalia
Cnidaria
Anthozoa
Alcyonacea
Chrysogorgiidae
Radicipes
Radicipes gracilis
Arctic
Newfoundland
Lofoten
Canada
Pacific
Indian
Mid-Atlantic Ridge
Perez
Stearns
Champagne
Gronland
Holdfast
Auster
Holte
Beazley
Barentshav*
Eggakanten
Labrador region
North Atlantic
Northwest Atlantic
Online Access:https://dx.doi.org/10.5281/zenodo.5634511
https://zenodo.org/record/5634511
id ftdatacite:10.5281/zenodo.5634511
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
Cnidaria
Anthozoa
Alcyonacea
Chrysogorgiidae
Radicipes
Radicipes gracilis
spellingShingle Biodiversity
Taxonomy
Animalia
Cnidaria
Anthozoa
Alcyonacea
Chrysogorgiidae
Radicipes
Radicipes gracilis
Perez, Carlos D.
Radicipes gracilis 1884
topic_facet Biodiversity
Taxonomy
Animalia
Cnidaria
Anthozoa
Alcyonacea
Chrysogorgiidae
Radicipes
Radicipes gracilis
description Radicipes gracilis (Verrill, 1884) Figs. 2 E–F, 9, 10 Lepidogorgia gracilis Verrill, 1884: 220; 1885: 512, 533, pl. 2, fig. 10, 10a.—VerSluyS, 1902: 16.— ThomSon & HenderSon, 1906: 27 (tabular key). Strophogorgia fragilis Wright & Studer, 1889: 4, pl. 2, fig. 2, pl. 5a. fig. 4. Lepidogorgia fragilis .—VerSluyS, 1902: 16-17.— ThomSon & HenderSon, 1906: 27. Radicipes gracilis.— Kükenthal, 1919: 548; 24: 412.— Verrill, 1922: 42, fig 10, 10a.— Deichmann, 1936: 237.— MadSen, 1944: 46 –49, text-figS. 37–41.— Bayer, 1979: 882, fig. 2c.— Bayer & Macintyre, 2001: 342 (mineralogy).— Watling & AuSter, 2005: 28 (liSted).— McFadden et al. , 2006: 525, figS. 1–3.— Wareham & Edinger, 2007: 295, 298, 302, fig. 1J.— CogSWell et al. , 2009: fig. 10G.— Buhl-MortenSen et al. , 2010: 43 (mentioned). — Pante & France, 2010: 597.— Watling et al. , 2011: 59 (liSted).— Baker, et al. , 2012: 239, 240, 244.— Pante & France, 2012: figS. 2–3, Supplemental table 1 (liSted).— Cordeiro et al. , 2015: 94, 95 (tabular key).— Buhl-MortenSen et al. , 2015: 39 –61, figS. 2f, 3i, 4, 5. ? Lepidogorgia challengeri. — JungerSen, 1915: 1184. Radicipes fragilis .— Kükenthal, 1924: 143. — Tixier-Durivault & d’Hondt, 1975: 1410. —Braga-HenriqueS et al. , 2013: 4026 (liSted).— Cordeiro et al. , 2015: 95 (tabular key). Lepidogorgia verrilli. — ThomSon, 1927: 20 –21, pl. 3, fig. 18, pl. 5, fig. 20. Types and Type Localities . Radicipes gracilis : USNM 9118 (syntype), Alb- 2072, 41°53'N, 65°35'W (off Massachusetts), 1569 m; USNM 8877, USNM 9350, USNM 26030, USNM 30283, USNM 33570, YPM 8768 and YPM 10045 (syntypes), Alb- 2037, 38°53'N, 69°23'30"W, 3166 m (off Massachusetts); part of the syntype series (from Alb -2036) is lost. Strophogorgia fragilis : BM 1889.5.27.4 (holotype, one specimen), Chall- 70: 38°25’N, 35°50’W (west of Azores), 3063 m. Material Examined . Del- 23, 39°55'55"N, 67°11'W, 1155 m (USNM 1111944, YPM 35442 and YPM 36838); Alb- 2569, 39°26'N, 68°03'30"W, 3259 (USNM 11913 and YPM 10049); Del- 29, 39°53'N, 67°23'W, 1395 (USNM 1110402); Alb -2209, 39°34'45"N, 71°31'30"W, 1975 m (USNM 8193 and YPM 10051); Alb -2570, 39°54'05"N, 67°05'30"W, 3316 m (USNM 11914); Alb -2575, 41°07'N, 65°26'30"W, 3128 m (USNM 11908); Alb -2563, 39°18'30"N, 71°23'30"W, 2601 m (USNM 11929 and YPM 10106); Del -14, 39°53'N, 67°26'24"W, depth unknown (USNM 100900); Del -47-Bear, 39°52'58"N, 67°25'58"W, 1195-1402 (USNM 1010390); Del-24 , 39°52'12"N, 67°20'18.6"W, 1428–1650 m (YPM 36783); Pisces -16, 40°10'54"N, 67°26'40.2"W, 1961 m (YPM 72083). Description . Colonies golden, stiff, tall, up to 90 cm in height, coiled in clockwise or counterclockwise manner; aXis 2.2 mm, maXimum diameter. Young colonies brittle and iridescent. Holdfast calcareous, profusely branched, usually thinner than aXis. Coenenchyme thin, fragile and easily detachable from aXis. At least one quarter of lower part of colony devoid of polyps. Distance between polyps about 1.5 mm in proXimal portions to 10.0 mm distally. Polyps 2.5–5.0 mm long, cylindrical to slightly trumpet-shaped (Fig. 2 E–F), disposed in a single longitudinal line (polypar side), spaced 4.0–10.0 mm apart in a frequency of three to five per centimeter (usually three). Eight longitudinal rows of rods in the body wall of completely developed polyps, with adaXials usually less developed, 0.18–0.7 mm long and 0.02–0.06 mm wide. Longest rods of body wall aligned with abaXial side, but no large supporting rods in abaXial side. AbaXial line from the lower portion of polyp to distal portion with four to siX juXtaposed pairs of rods in alternate lines, relatively homogeneous in size. Sclerite size decreases from abaXial to outer lateral rows. Inner lateral and adaXial rows composed of loosely placed rods, sometimes naked. Oral portion with rods similar in size to those from lower portion of polyp. Infrabasal and adaXial portions filled with flattened rods, slightly 8-shaped, 0.15–0.26 mm long and 0.04–0.05 mm wide (Figs. 9 A, 10A). Infrabasal and abaXial rods with slightly flattened tips becoming more rounded and sparse in oral portion. AbaXial row of rods eXtending through coenenchyme between polyps, connecting them. Coenenchymal sclerites rare or completely absent, when present, similar to those of infrabasal and adaXial portions. Tentacular rods 0.07–0.18 mm long and 0.01–0.04 mm wide, becoming flatter in proXimal-distal wall (Figs. 9 B, 10C). Pinnules filled with small scales, 0.1–0.13 mm in length and 0.01–0.04 mm in width (Figs. 9 C, 10B). Comparisons . Colonies of R. gracilis differ from the Atlantic species R. challengeri and R. kopelatos by having larger polyps (Table 1) and by having their body wall densely filled with sclerites (Fig. 2). Although the longest polyps in R. kopelatos reach up to 3.3 mm, most polyps in a colony are very short in comparison to those in R. gracilis , usually half their length. As well, the aXis diameter in R. gracilis is usually thicker. The Pacific species Radicipes stonei has a similar polyp shape, but differs in having one or two long supporting rods in the lower abaXial side, having irregular infrabasal flattened rods, and having body wall rods with at least one flat tip. Remarks . Radicipes gracilis is the most frequently recorded species in the genus, with at least 12 records presented herein and several others gleaned from the literature (Fig. 3, Supplementary file). Most studies have treated mid-Atlantic ( R. fragilis ) and western Atlantic ( R. gracilis ) populations as separate species. Nonetheless, no revisions including eXaminations of both types have been carried out until now. The type remains of R. fragilis consist of just a fragment of tissue (no aXis) with several polyps. But this is enough to determine that the types are indistinguishable (compare Fig. 2 E,E’ with 2F and Fig. 9 with Fig. 10). Several misconceptions about the morphological features of R. gracilis can be seen in the available literature. Thomson & Henderson (1906), for eXample, implied that the species has more coenenchymal sclerites than R. pleurocristatus (see Thomson & Henderson, 1906: p. 27, comparative table of species of Lepidogorgia ). According to Madsen (1944) and Cordeiro et al. (2015), the main differences between the two species can be seen in the measurements of the polyps, twice as long in R. gracilis , and the longer body wall rods in R. fragilis (Cordeiro et al. , 2015). We understand that the ‘polyp distinction’ is due to the measurements given by Madsen (1944), which included tentacles in the total polyp length determination, whereas no other author has included the tentacles to describe this character. Actually, both species have the same polypar length range, from 2.5 to 4.0 mm, not 5.0 to 10.0 mm as stated by Madsen. Rods from the body wall were slightly longer in the R. fragilis type (up to 0. 75 mm long, whereas usually just up to 0.5 mm in western Atlantic specimens). Even though we only eXamined one mid-Atlantic colony, we consider it to be the same species, considering the sclerite size to be more related to age of the colony and seXual maturation. It remains to be seen if the sequenced mid-Atlantic specimen ‘ VER 2041’ (Pante et al. , 2012) fits our R. gracilis definition, or R. challengeri, or is a different species. Considering Pante’s phylogenies, in the first case, one could consider treating R. gracilis as a cryptic species compleX or one could suggest the reestablishment of R. fragilis as a valid name. Our eXaminations however do not allow us to keep both as valid. Distribution . In western Atlantic from North Carolina to Canada; Mid-Atlantic Ridge, Seamounts and Portugal (Azores), from 500–3259 m. : Published as part of Perez, Carlos D., 2017, A revision of the genus Radicipes Stearns, 1883 (Anthozoa: Octocorallia: Chrysogorgiidae), pp. 1-26 in Zootaxa 4319 (1) on pages 14-17, DOI: 10.11646/zootaxa.4319.1.1, http://zenodo.org/record/893037 : {"references": ["Verrill, A. E. (1884) Notice of the remarkable marine fauna occupying the outer bankS off the Southern coaSt of NeW England, No. 9. Brief contributionS to zoology from the MuSeum of Yale College. No. 55. American Journal of Science, 28 (3), 213 - 220.", "ThomSon, J. A. & HenderSon, W. D. (1906) An account of the AlcyonarianS collected by the Royal Indian Survey Ship InveStigator in the Indian Ocean. Part 1. The Alcyonarians of the Deep Sea. Indian MuSeum, Calcutta, 132 pp.", "Wright, E. P. & Studer, T. (1889) Report on the Alcyonaria collected by H. M. S. Challenger during the yearS 1873 - 1876. Report on the Scientific Results of H. M. S. Challenger during the years 1873 - 76, Zoology, 31 (64), 1 - 314.", "Kukenthal, W. (1919) Gorgonaria. Wissenschaftliche Ergebnisse der Tiefsee-Expedition Valdivia, 13 (2), 1 - 946.", "Verrill, A. E. (1922) Alcyonaria and Actinaria. Report of the Canadian Arctic Expedition, 8 (G), 1 - 164.", "Deichmann, E. (1936) The Alcyonaria of the WeStern part of the Atlantic Ocean. Memoirs of the Museum of Comparative Zoology, 53, 253 - 308.", "MadSen, F. J. (1944) Octocorallia. Danish Ingolf-Expedition, 5 (13), 1 - 65.", "Bayer, F. M. (1979) Distichogorgia sconsa, a neW genuS and neW SpecieS of chrySogorgiid octocoral (Coelenterata: Anthozoa) from the Blake Plateau off northern Florida. Proceedings of the Biological Society of Washington, 92 (4), 876 - 882.", "Bayer, F. M. & Macintyre, I. G. (2001) The mineral component of the axiS and holdfaSt of Some gorgonacean octocoralS (Coelenterata: Anthozoa), With Special reference to the family Gorgoniidae Proceedings of the Biological Society of Washington, 114 (1), 309 - 345.", "Watling, L. & AuSter, P. (2005) DiStribution of deep-Water Alcyonacea off the northeaSt coaSt of the United StateS. In: FreiWald, A. & Murray, R. J. (EdS.), Cold-Water Corals and Ecosystems. Springer-Verlag, Berlin, Heidelberg, pp. 279 - 296. httpS: // doi. org / 10.1007 / 3 - 540 - 27673 - 4 _ 13", "McFadden, C., France, S. C., Sanchez, J. A. & AlderSlade, P. (2006) A molecular phylogenetic analySiS of the Octocorallia (Cnidaria: Anthozoa) baSed on mitochondrial protein-coding SequenceS. Molecular Phylogenetics and Evolution, 41, 513 - 527.", "Wareham, V. E. & Edinger, E. N. (2007) DiStribution of deep-Sea coralS in the NeWfoundland and Labrador region, NorthWeSt Atlantic Ocean. In: George, R. Y. & CairnS, S. D. (EdS.), Conservation and adaptive management of seamount and deep-sea coral ecosystems. RoSenStiel School of Marine and AtmoSpheric Science, UniverSity of Miami, pp. 289 - 313.", "CogSWell, A. T., Kenchington, E. L. R., Lirette, C. G., MacISaac, K., BeSt, M. M., Beazley, L. I. & VickerS, J. (2009) The current State of knoWledge concerning the diStribution of coral in the Maritime ProvinceS. Canadian Technical Report of Fisheries and Aquatic Sciences, 2855, 1 - 66.", "Buhl-MortenSen, L., Buhl-MortenSen, P., Holte, B., Dannheim, J., Kroger, K., Dolan, M. & Picard, K. (2010) Dyreliv pa havbunnen TromSoflaket og Eggakanten. In: Buhl-MortenSen L., HodneSdal, H. & ThorSneS, T. (EdS.), Til bunns i Barentshavet og havomradene utenfor Lofoten-ny kunnskap fra MAREANO for Okosystembasert forvaltning, NorgeS geologiSke underSokelSe, Trondheim, pp. 36 - 41.", "Pante, E. & France, S. C. (2010) Pseudochrysogorgia bellona n. gen., n. Sp.: a neW genuS and SpecieS of chrySogorgiid octocoral (Coelenterata, Anthozoa) from the Coral Sea. Zoosystema, 32 (4), 595 - 612.", "Watling, L., France, S., Pante, E. & SimpSon, A. (2011) Biology of deep-Water octocoralS. In: LeSSer, M. (Ed.), Advances in Marine Biology. ElSevier Academic preSS, London, pp. 41 - 122.", "Baker, K. D., Wareham, V. E., Snelgrove, P. V. R., Haedrich, R. L., Fifield, D. A., Edinger, E. N. & GilkinSon, K. D. (2012) DiStributional patternS of deep-Sea coral aSSemblageS in three Submarine canyonS off NeWfoundland, Canada. Marine Ecology Progress Series, 445, 235 - 249.", "Pante, E., France, S., Couloux, A., Cruaud, C., McFadden, C. S., Samadi, S. & Watling, L. (2012) Deep-Sea origin and in-Situ diverSification of chrySogorgiid octocoralS. PLoS ONE, 7 (6), e 38357.", "Cordeiro, R. T. S., CaStro, C. B. & Perez, C. D. (2015) Deep-Water octocoralS (Cnidaria: Octocorallia) from Brazil: Family ChrySogorgiidae Verrill, 1883. Zootaxa, 4058 (1), 081 - 100.", "Buhl-MortenSen, L., OlafSdottir, S. H., Buhl-MortenSen, P., BurgoS, J. M. & RagnarSSon, S. A. (2015) DiStribution of nine cold- Water coral SpecieS (Scleractinia and Gorgonacea) in the cold temperate North Atlantic: effectS of bathymetry and hydrography. Hydrobiologia, 759, 39 - 61.", "JungerSen, H. F. E. (1915) Alcyonaria, Antipatharia og Madreporaria. ConSpectuS Faunae Groenlandicae. Meddelelser Gronland, 23, 1156 - 1212.", "Kukenthal, W. (1924) Gorgonaria. Das Tierreich, 47, 1 - 478.", "Tixier-Durivault, A. & d'Hondt, M. J. (1975) LeS OctocoralliaireS de la champagne BiacoreS. Bulletin du Museum National d'Histoire Naturelle, 174 (252), 1361 - 1433.", "ThomSon, J. A. (1927) AlcyonaireS provenant deS campagneS ScientifiqueS du Prince Albert Ier de Monaco. Resultats des Campagnes Scientifiques Albert I, 73, 1 - 77."]}
format Text
author Perez, Carlos D.
author_facet Perez, Carlos D.
author_sort Perez, Carlos D.
title Radicipes gracilis 1884
title_short Radicipes gracilis 1884
title_full Radicipes gracilis 1884
title_fullStr Radicipes gracilis 1884
title_full_unstemmed Radicipes gracilis 1884
title_sort radicipes gracilis 1884
publisher Zenodo
publishDate 2017
url https://dx.doi.org/10.5281/zenodo.5634511
https://zenodo.org/record/5634511
long_lat ENVELOPE(-69.117,-69.117,-68.517,-68.517)
ENVELOPE(162.817,162.817,-78.317,-78.317)
ENVELOPE(-136.483,-136.483,60.788,60.788)
ENVELOPE(70.203,70.203,-49.626,-49.626)
ENVELOPE(-66.590,-66.590,-66.803,-66.803)
ENVELOPE(-59.467,-59.467,-63.817,-63.817)
ENVELOPE(17.297,17.297,68.895,68.895)
ENVELOPE(-60.733,-60.733,-62.967,-62.967)
geographic Arctic
Newfoundland
Lofoten
Canada
Pacific
Indian
Mid-Atlantic Ridge
Perez
Stearns
Champagne
Gronland
Holdfast
Auster
Holte
Beazley
geographic_facet Arctic
Newfoundland
Lofoten
Canada
Pacific
Indian
Mid-Atlantic Ridge
Perez
Stearns
Champagne
Gronland
Holdfast
Auster
Holte
Beazley
genre Arctic
Barentshav*
Eggakanten
Labrador region
Lofoten
Newfoundland
North Atlantic
Northwest Atlantic
genre_facet Arctic
Barentshav*
Eggakanten
Labrador region
Lofoten
Newfoundland
North Atlantic
Northwest Atlantic
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spelling ftdatacite:10.5281/zenodo.5634511 2023-05-15T15:21:22+02:00 Radicipes gracilis 1884 Perez, Carlos D. 2017 https://dx.doi.org/10.5281/zenodo.5634511 https://zenodo.org/record/5634511 unknown Zenodo http://zenodo.org/record/893037 http://publication.plazi.org/id/722F5417FFC6FF979951FFB1FF982974 http://zoobank.org/Fc97523C-3Fe9-4Bd1-9A3B-174E0969E78A https://zenodo.org/communities/biosyslit https://dx.doi.org/10.11646/zootaxa.4319.1.1 http://zenodo.org/record/893037 http://publication.plazi.org/id/722F5417FFC6FF979951FFB1FF982974 https://dx.doi.org/10.5281/zenodo.893041 https://dx.doi.org/10.5281/zenodo.893055 https://dx.doi.org/10.5281/zenodo.893043 https://dx.doi.org/10.5281/zenodo.893057 http://zoobank.org/Fc97523C-3Fe9-4Bd1-9A3B-174E0969E78A https://dx.doi.org/10.5281/zenodo.5634510 https://zenodo.org/communities/biosyslit Open Access info:eu-repo/semantics/openAccess Biodiversity Taxonomy Animalia Cnidaria Anthozoa Alcyonacea Chrysogorgiidae Radicipes Radicipes gracilis Taxonomic treatment article-journal Text ScholarlyArticle 2017 ftdatacite https://doi.org/10.5281/zenodo.5634511 https://doi.org/10.11646/zootaxa.4319.1.1 https://doi.org/10.5281/zenodo.893041 https://doi.org/10.5281/zenodo.893055 https://doi.org/10.5281/zenodo.893043 https://doi.org/10.5281/zenodo.893057 https://do 2022-02-08T12:23:07Z Radicipes gracilis (Verrill, 1884) Figs. 2 E–F, 9, 10 Lepidogorgia gracilis Verrill, 1884: 220; 1885: 512, 533, pl. 2, fig. 10, 10a.—VerSluyS, 1902: 16.— ThomSon & HenderSon, 1906: 27 (tabular key). Strophogorgia fragilis Wright & Studer, 1889: 4, pl. 2, fig. 2, pl. 5a. fig. 4. Lepidogorgia fragilis .—VerSluyS, 1902: 16-17.— ThomSon & HenderSon, 1906: 27. Radicipes gracilis.— Kükenthal, 1919: 548; 24: 412.— Verrill, 1922: 42, fig 10, 10a.— Deichmann, 1936: 237.— MadSen, 1944: 46 –49, text-figS. 37–41.— Bayer, 1979: 882, fig. 2c.— Bayer & Macintyre, 2001: 342 (mineralogy).— Watling & AuSter, 2005: 28 (liSted).— McFadden et al. , 2006: 525, figS. 1–3.— Wareham & Edinger, 2007: 295, 298, 302, fig. 1J.— CogSWell et al. , 2009: fig. 10G.— Buhl-MortenSen et al. , 2010: 43 (mentioned). — Pante & France, 2010: 597.— Watling et al. , 2011: 59 (liSted).— Baker, et al. , 2012: 239, 240, 244.— Pante & France, 2012: figS. 2–3, Supplemental table 1 (liSted).— Cordeiro et al. , 2015: 94, 95 (tabular key).— Buhl-MortenSen et al. , 2015: 39 –61, figS. 2f, 3i, 4, 5. ? Lepidogorgia challengeri. — JungerSen, 1915: 1184. Radicipes fragilis .— Kükenthal, 1924: 143. — Tixier-Durivault & d’Hondt, 1975: 1410. —Braga-HenriqueS et al. , 2013: 4026 (liSted).— Cordeiro et al. , 2015: 95 (tabular key). Lepidogorgia verrilli. — ThomSon, 1927: 20 –21, pl. 3, fig. 18, pl. 5, fig. 20. Types and Type Localities . Radicipes gracilis : USNM 9118 (syntype), Alb- 2072, 41°53'N, 65°35'W (off Massachusetts), 1569 m; USNM 8877, USNM 9350, USNM 26030, USNM 30283, USNM 33570, YPM 8768 and YPM 10045 (syntypes), Alb- 2037, 38°53'N, 69°23'30"W, 3166 m (off Massachusetts); part of the syntype series (from Alb -2036) is lost. Strophogorgia fragilis : BM 1889.5.27.4 (holotype, one specimen), Chall- 70: 38°25’N, 35°50’W (west of Azores), 3063 m. Material Examined . Del- 23, 39°55'55"N, 67°11'W, 1155 m (USNM 1111944, YPM 35442 and YPM 36838); Alb- 2569, 39°26'N, 68°03'30"W, 3259 (USNM 11913 and YPM 10049); Del- 29, 39°53'N, 67°23'W, 1395 (USNM 1110402); Alb -2209, 39°34'45"N, 71°31'30"W, 1975 m (USNM 8193 and YPM 10051); Alb -2570, 39°54'05"N, 67°05'30"W, 3316 m (USNM 11914); Alb -2575, 41°07'N, 65°26'30"W, 3128 m (USNM 11908); Alb -2563, 39°18'30"N, 71°23'30"W, 2601 m (USNM 11929 and YPM 10106); Del -14, 39°53'N, 67°26'24"W, depth unknown (USNM 100900); Del -47-Bear, 39°52'58"N, 67°25'58"W, 1195-1402 (USNM 1010390); Del-24 , 39°52'12"N, 67°20'18.6"W, 1428–1650 m (YPM 36783); Pisces -16, 40°10'54"N, 67°26'40.2"W, 1961 m (YPM 72083). Description . Colonies golden, stiff, tall, up to 90 cm in height, coiled in clockwise or counterclockwise manner; aXis 2.2 mm, maXimum diameter. Young colonies brittle and iridescent. Holdfast calcareous, profusely branched, usually thinner than aXis. Coenenchyme thin, fragile and easily detachable from aXis. At least one quarter of lower part of colony devoid of polyps. Distance between polyps about 1.5 mm in proXimal portions to 10.0 mm distally. Polyps 2.5–5.0 mm long, cylindrical to slightly trumpet-shaped (Fig. 2 E–F), disposed in a single longitudinal line (polypar side), spaced 4.0–10.0 mm apart in a frequency of three to five per centimeter (usually three). Eight longitudinal rows of rods in the body wall of completely developed polyps, with adaXials usually less developed, 0.18–0.7 mm long and 0.02–0.06 mm wide. Longest rods of body wall aligned with abaXial side, but no large supporting rods in abaXial side. AbaXial line from the lower portion of polyp to distal portion with four to siX juXtaposed pairs of rods in alternate lines, relatively homogeneous in size. Sclerite size decreases from abaXial to outer lateral rows. Inner lateral and adaXial rows composed of loosely placed rods, sometimes naked. Oral portion with rods similar in size to those from lower portion of polyp. Infrabasal and adaXial portions filled with flattened rods, slightly 8-shaped, 0.15–0.26 mm long and 0.04–0.05 mm wide (Figs. 9 A, 10A). Infrabasal and abaXial rods with slightly flattened tips becoming more rounded and sparse in oral portion. AbaXial row of rods eXtending through coenenchyme between polyps, connecting them. Coenenchymal sclerites rare or completely absent, when present, similar to those of infrabasal and adaXial portions. Tentacular rods 0.07–0.18 mm long and 0.01–0.04 mm wide, becoming flatter in proXimal-distal wall (Figs. 9 B, 10C). Pinnules filled with small scales, 0.1–0.13 mm in length and 0.01–0.04 mm in width (Figs. 9 C, 10B). Comparisons . Colonies of R. gracilis differ from the Atlantic species R. challengeri and R. kopelatos by having larger polyps (Table 1) and by having their body wall densely filled with sclerites (Fig. 2). Although the longest polyps in R. kopelatos reach up to 3.3 mm, most polyps in a colony are very short in comparison to those in R. gracilis , usually half their length. As well, the aXis diameter in R. gracilis is usually thicker. The Pacific species Radicipes stonei has a similar polyp shape, but differs in having one or two long supporting rods in the lower abaXial side, having irregular infrabasal flattened rods, and having body wall rods with at least one flat tip. Remarks . Radicipes gracilis is the most frequently recorded species in the genus, with at least 12 records presented herein and several others gleaned from the literature (Fig. 3, Supplementary file). Most studies have treated mid-Atlantic ( R. fragilis ) and western Atlantic ( R. gracilis ) populations as separate species. Nonetheless, no revisions including eXaminations of both types have been carried out until now. The type remains of R. fragilis consist of just a fragment of tissue (no aXis) with several polyps. But this is enough to determine that the types are indistinguishable (compare Fig. 2 E,E’ with 2F and Fig. 9 with Fig. 10). Several misconceptions about the morphological features of R. gracilis can be seen in the available literature. Thomson & Henderson (1906), for eXample, implied that the species has more coenenchymal sclerites than R. pleurocristatus (see Thomson & Henderson, 1906: p. 27, comparative table of species of Lepidogorgia ). According to Madsen (1944) and Cordeiro et al. (2015), the main differences between the two species can be seen in the measurements of the polyps, twice as long in R. gracilis , and the longer body wall rods in R. fragilis (Cordeiro et al. , 2015). We understand that the ‘polyp distinction’ is due to the measurements given by Madsen (1944), which included tentacles in the total polyp length determination, whereas no other author has included the tentacles to describe this character. Actually, both species have the same polypar length range, from 2.5 to 4.0 mm, not 5.0 to 10.0 mm as stated by Madsen. Rods from the body wall were slightly longer in the R. fragilis type (up to 0. 75 mm long, whereas usually just up to 0.5 mm in western Atlantic specimens). Even though we only eXamined one mid-Atlantic colony, we consider it to be the same species, considering the sclerite size to be more related to age of the colony and seXual maturation. It remains to be seen if the sequenced mid-Atlantic specimen ‘ VER 2041’ (Pante et al. , 2012) fits our R. gracilis definition, or R. challengeri, or is a different species. Considering Pante’s phylogenies, in the first case, one could consider treating R. gracilis as a cryptic species compleX or one could suggest the reestablishment of R. fragilis as a valid name. Our eXaminations however do not allow us to keep both as valid. Distribution . In western Atlantic from North Carolina to Canada; Mid-Atlantic Ridge, Seamounts and Portugal (Azores), from 500–3259 m. : Published as part of Perez, Carlos D., 2017, A revision of the genus Radicipes Stearns, 1883 (Anthozoa: Octocorallia: Chrysogorgiidae), pp. 1-26 in Zootaxa 4319 (1) on pages 14-17, DOI: 10.11646/zootaxa.4319.1.1, http://zenodo.org/record/893037 : {"references": ["Verrill, A. E. (1884) Notice of the remarkable marine fauna occupying the outer bankS off the Southern coaSt of NeW England, No. 9. Brief contributionS to zoology from the MuSeum of Yale College. No. 55. American Journal of Science, 28 (3), 213 - 220.", "ThomSon, J. A. & HenderSon, W. D. (1906) An account of the AlcyonarianS collected by the Royal Indian Survey Ship InveStigator in the Indian Ocean. Part 1. The Alcyonarians of the Deep Sea. Indian MuSeum, Calcutta, 132 pp.", "Wright, E. P. & Studer, T. (1889) Report on the Alcyonaria collected by H. M. S. Challenger during the yearS 1873 - 1876. 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Zootaxa, 4058 (1), 081 - 100.", "Buhl-MortenSen, L., OlafSdottir, S. H., Buhl-MortenSen, P., BurgoS, J. M. & RagnarSSon, S. A. (2015) DiStribution of nine cold- Water coral SpecieS (Scleractinia and Gorgonacea) in the cold temperate North Atlantic: effectS of bathymetry and hydrography. Hydrobiologia, 759, 39 - 61.", "JungerSen, H. F. E. (1915) Alcyonaria, Antipatharia og Madreporaria. ConSpectuS Faunae Groenlandicae. Meddelelser Gronland, 23, 1156 - 1212.", "Kukenthal, W. (1924) Gorgonaria. Das Tierreich, 47, 1 - 478.", "Tixier-Durivault, A. & d'Hondt, M. J. (1975) LeS OctocoralliaireS de la champagne BiacoreS. Bulletin du Museum National d'Histoire Naturelle, 174 (252), 1361 - 1433.", "ThomSon, J. A. (1927) AlcyonaireS provenant deS campagneS ScientifiqueS du Prince Albert Ier de Monaco. Resultats des Campagnes Scientifiques Albert I, 73, 1 - 77."]} Text Arctic Barentshav* Eggakanten Labrador region Lofoten Newfoundland North Atlantic Northwest Atlantic DataCite Metadata Store (German National Library of Science and Technology) Arctic Newfoundland Lofoten Canada Pacific Indian Mid-Atlantic Ridge Perez ENVELOPE(-69.117,-69.117,-68.517,-68.517) Stearns ENVELOPE(162.817,162.817,-78.317,-78.317) Champagne ENVELOPE(-136.483,-136.483,60.788,60.788) Gronland ENVELOPE(70.203,70.203,-49.626,-49.626) Holdfast ENVELOPE(-66.590,-66.590,-66.803,-66.803) Auster ENVELOPE(-59.467,-59.467,-63.817,-63.817) Holte ENVELOPE(17.297,17.297,68.895,68.895) Beazley ENVELOPE(-60.733,-60.733,-62.967,-62.967)

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