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4. A tenuis relationship: traditional taxonomy obscures systematics and biogeography of the 'Acropora tenuis' (Scleractinia: Acroporidae) species complex.

Author

Bridge, Tom C L, Cowman, Peter F, Quattrini, Andrea M, Bonito, Victor E, Sinniger, Frederic, Harii, Saki, Head, Catherine E I, Hung, Julia Y, Halafihi, Tuikolongahau, Rongo, Teina, and Baird, Andrew H

Subjects
*BIOLOGICAL classification, *CORAL reef conservation, *CORAL reef management, *SINGLE nucleotide polymorphisms, *CLADISTIC analysis
Abstract

Molecular phylogenetics has fundamentally altered our understanding of the taxonomy, systematics and biogeography of corals. Recently developed phylogenomic techniques have started to resolve species-level relationships in the diverse and ecologically important genus Acropora , providing a path to resolve the taxonomy of this notoriously problematic group. We used a targeted capture dataset (2032 loci) to investigate systematic relationships within an Acropora clade containing the putatively widespread species Acropora tenuis and its relatives. Using maximum likelihood phylogenies and genetic clustering of single nucleotide polymorphisms from specimens, including topotypes, collected across the Indo-Pacific, we show ≥ 11 distinct lineages in the clade, only four of which correspond to currently accepted species. Based on molecular, morphological and geographical evidence, we describe two new species; Acropora rongoi n. sp. and Acropora tenuissima n. sp. and remove five additional nominal species from synonymy. Systematic relationships revealed by our molecular phylogeny are incongruent with traditional morphological taxonomy and demonstrate that characters traditionally used to delineate species boundaries and infer evolutionary history are homoplasies. Furthermore, we show that species within this clade have much smaller geographical ranges and, consequently, population sizes than currently thought, a finding with profound implications for conservation and management of reef corals. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Key Questions for Research and Conservation of Mesophotic Coral Ecosystems and Temperate Mesophotic Ecosystems

Author

Turner, Joseph A., Andradi-Brown, Dominic A., Gori, Andrea, Bongaerts, Pim, Burdett, Heidi L., Ferrier-Pagès, Christine, Voolstra, Christian R., Weinstein, David K., Bridge, Tom C. L., Costantini, Federica, Gress, Erika, Laverick, Jack, Loya, Yossi, Goodbody-Gringley, Gretchen, Rossi, Sergio, Taylor, Michelle L., Viladrich, Nuria, Voss, Joshua D., Williams, Joel, Woodall, Lucy C., Eyal, Gal, Riegl, Bernhard M., Series Editor, Dodge, Richard E., Series Editor, Loya, Yossi, editor, Puglise, Kimberly A., editor, and Bridge, Tom C.L., editor

Published
2019
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11. Octocorals of the Indo-Pacific

Author

Benayahu, Yehuda, Bridge, Tom C. L., Colin, Patrick L., Liberman, Ronen, McFadden, Catherine S., Pizarro, Oscar, Schleyer, Michael H., Shoham, Erez, Reijnen, Bastian T., Weis, Michal, Tanaka, Junichi, Riegl, Bernhard M., Series Editor, Dodge, Richard E., Series Editor, Loya, Yossi, editor, Puglise, Kimberly A., editor, and Bridge, Tom C.L., editor

Published
2019
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12. The Great Barrier Reef and Coral Sea

Author

Bridge, Tom C. L., Beaman, Robin J., Bongaerts, Pim, Muir, Paul R., Ekins, Merrick, Sih, Tiffany, Riegl, Bernhard M., Series Editor, Dodge, Richard E., Series Editor, Loya, Yossi, editor, Puglise, Kimberly A., editor, and Bridge, Tom C.L., editor

Published
2019
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14. Social–environmental drivers inform strategic management of coral reefs in the Anthropocene

Author

Darling, Emily S., McClanahan, Tim R., Maina, Joseph, Gurney, Georgina G., Graham, Nicholas A. J., Januchowski-Hartley, Fraser, Cinner, Joshua E., Mora, Camilo, Hicks, Christina C., Maire, Eva, Puotinen, Marji, Skirving, William J., Adjeroud, Mehdi, Ahmadia, Gabby, Arthur, Rohan, Bauman, Andrew G., Beger, Maria, Berumen, Michael L., Bigot, Lionel, Bouwmeester, Jessica, Brenier, Ambroise, Bridge, Tom C. L., Brown, Eric, Campbell, Stuart J., Cannon, Sara, Cauvin, Bruce, Chen, Chaolun Allen, Claudet, Joachim, Denis, Vianney, Donner, Simon, Estradivari, Fadli, Nur, Feary, David A., Fenner, Douglas, Fox, Helen, Franklin, Erik C., Friedlander, Alan, Gilmour, James, Goiran, Claire, Guest, James, Hobbs, Jean-Paul A., Hoey, Andrew S., Houk, Peter, Johnson, Steven, Jupiter, Stacy D., Kayal, Mohsen, Kuo, Chao-yang, Lamb, Joleah, Lee, Michelle A. C., Low, Jeffrey, Muthiga, Nyawira, Muttaqin, Efin, Nand, Yashika, Nash, Kirsty L., Nedlic, Osamu, Pandolfi, John M., Pardede, Shinta, Patankar, Vardhan, Penin, Lucie, Ribas-Deulofeu, Lauriane, Richards, Zoe, Roberts, T. Edward, Rodgers, Ku’ulei S., Safuan, Che Din Mohd, Sala, Enric, Shedrawi, George, Sin, Tsai Min, Smallhorn-West, Patrick, Smith, Jennifer E., Sommer, Brigitte, Steinberg, Peter D., Sutthacheep, Makamas, Tan, Chun Hong James, Williams, Gareth J., Wilson, Shaun, Yeemin, Thamasak, Bruno, John F., Fortin, Marie-Josée, Krkosek, Martin, and Mouillot, David

Published
2019
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18. A tenuis relationship: traditional taxonomy obscures systematics and biogeography of the ‘Acropora tenuis’ (Scleractinia: Acroporidae) species complex

Author

Bridge, Tom C L, primary, Cowman, Peter F, additional, Quattrini, Andrea M, additional, Bonito, Victor E, additional, Sinniger, Frederic, additional, Harii, Saki, additional, Head, Catherine E I, additional, Hung, Julia Y, additional, Halafihi, Tuikolongahau, additional, Rongo, Teina, additional, and Baird, Andrew H, additional

Published
2023
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20. The broad footprint of climate change from genes to biomes to people

Author

Scheffers, Brett R., De Meester, Luc, Bridge, Tom C. L., Hoffmann, Ary A., Pandolfi, John M., Corlett, Richard T., Butchart, Stuart H. M., Pearce-Kelly, Paul, Kovacs, Kit M., Dudgeon, David, Pacifici, Michela, Rondinini, Carlo, Foden, Wendy B., Martin, Tara G., Mora, Camilo, Bickford, David, and Watson, James E. M.

Published
2016

26. Rhipidipathes Milne-Edwards & Haime 1857

Author

Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F., and Bridge, Tom C. L.

Subjects
Cnidaria, Aphanipathidae, Animalia, Biodiversity, Rhipidipathes, Anthozoa, Antipatharia, Taxonomy
Abstract

Genus Rhipidipathes Milne-Edwards & Haime, 1857 Diagnosis. Corallum flabellate; anastomosing among some branches; polypar spines acute or blunt, smooth or tuberculate; circumpolypar spines slightly larger than interpolypar spines; hypostomal spines often equal to the circumpolypar spines but may be reduced in size or absent on some portions of the corallum. Remarks. Although Rhipidipathes is currently in the Aphanipathidae, previous (Brugler et al. 2013; Bo et al. 2018; Terrana et al. 2021) and the present study indicate that the genus is more closely related to species in the Antipathidae. The present study suggests that Rhipidipathes shares a lineage with the genus Blastopathes Horowitz, 2020 (Fig 2). Both genera have distinct morphological differences. For example, Rhipidipathes consists of thin branches that can fuse to create flabellate “fan-like” colonies (Opresko 2004) and Blastopathes consists of thick, stem-like branches that do not fuse and possess branches that sprout from clusters to create “tree-like” colonies (Horowitz et al. 2020). Due to the differences between these “sister” genera, their family-level relationships need to be verified. Type Species: Rhipidipathes reticulata (Esper 1795) Type Locality: East Indian Ocean, Published as part of Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F. & Bridge, Tom C. L., 2022, Five new species of black coral (Anthozoa; Antipatharia) from the Great Barrier Reef and Coral Sea, Australia, pp. 1-35 in Zootaxa 5213 (1) on page 10, DOI: 10.11646/zootaxa.5213.1.1, http://zenodo.org/record/7350036, {"references":["Haime, J. & Milne-Edwards, H. (1857) Histoire naturelle des coralliaires, ou polypes proprement dits; par H. Milne-Edwards ... Histoire naturelle des coralliaires, ou polypes proprement dits. Roret, Paris, 326 pp.","Brugler, M. R., Opresko, D. M. & France, S. C. (2013) The evolutionary history of the order Antipatharia (Cnidaria: Anthozoa: Hexacorallia) as inferred from mitochondrial and nuclear DNA: implications for black coral taxonomy and systematics. Zoological Journal of the Linnean Society, 169, 312 - 361. https: // doi. org / 10.1111 / zoj. 12060","Bo, M., Barucca, M., Biscotti, M. A., Brugler, M. R., Canapa, A., Canese, S., lo Iacono, C. & Bavestrello, G. (2018) Phylogenetic relationships of Mediterranean black corals (Cnidaria: Anthozoa: Hexacorallia) and implications for classification within the order Antipatharia. Invertebrate Systematics, 32, 1102. https: // doi. org / 10.1071 / is 17043","Terrana, L., Flot, J. - F. & Eeckhaut, I. (2021) ITS 1 variation among Stichopathes cf. maldivensis (Hexacorallia: Antipatharia) whip black corals unveils conspecificity and population connectivity at local and global scales across the Indo-Pacific. Coral Reefs, 40, 521 - 533. https: // doi. org / 10.1007 / s 00338 - 020 - 02049 - 8","Horowitz, J., Brugler, M. R., Bridge, T. C. L. & Cowman, P. F. (2020) Morphological and molecular description of a new genus and species of black coral (Cnidaria: Anthozoa: Hexacorallia: Antipatharia: Antipathidae: Blastopathes) from Papua New Guinea. Zootaxa, 4821 (3), 553 - 569. https: // doi. org / 10.11646 / zootaxa. 4821.3.7","Opresko, D. M. (2004) Revision of the Antipatharia (Cnidaria: Anthozoa). Part IV. Establishment of a new family, Aphanipathidae. Zoologische Mededelingen, Leiden, 78, 1 - 15.","Esper, E. J. C. (1795) Die Pflanzenthiere in Abbildungen nach der Natur mit Farben erleuchtet nebst Beschreibungen. in der Raspischen Buchhandlung, Nurnberg, 303 pp."]}

Published
2022
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27. Antipathes morrisi Horowitz & Opresko & Molodtsova & Beaman & Cowman & Bridge 2022, sp. nov

Author

Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F., and Bridge, Tom C. L.

Subjects
Cnidaria, Antipathes morrisi, Antipathes, Antipathidae, Animalia, Biodiversity, Anthozoa, Antipatharia, Taxonomy
Abstract

Antipathes morrisi Horowitz sp. nov. (Figs. 1–3; Supplementary Tables 1–2) Material examined. Holotype, MTQ G80140, Australia, Great Barrier Reef, Orpheus Island, Pioneer Bay North, expedition Voyage of the Kalinda, collected on October 22, 2019, - 18.5998° S, 146.4888° E, 14 m depth, collector Jeremy Horowitz. Diagnosis. Flabellate corallum, up to ~ 1 cm thick; branches and terminal branchlets arranged bilaterally, or anterolaterally; overlapping, and branches anastomose. Terminal branchlets 4 to 10 mm in length, slightly curved distally, distal angles ~45 to almost 90°, 0.11 to 0.25 mm in basal diameter, spaced 2 to 5 mm apart: with a density of ~4 per cm including all rows. Spines smooth, conical, and laterally compressed, 0.085 to 0.19 mm tall. Some spines on branches possess up to four small, cone-shaped apical knobs. Four to five axial rows of spines counted in one view and four to seven spines counted in one cm in one row. Polyps 0.8 to 1 mm in transverse diameter, spaced ~ 0.2 mm apart, with eight to nine polyps per cm. Description of holotype. The entire colony was 60 cm tall by 60 cm wide and 1 cm thick (Fig. 3A), but only a 28 cm tall and 20 cm wide section (MTQ G80140) was collected. The colony is branched to the fourth and rarely fifth order and has branches and terminal branchlets that are mostly distally directed and form one distinct, ~ 1 cm thick flabellate plane with highly anastomosing branches (Fig. 3B). Branches bilaterally arranged projecting in one plane with the smaller branchlets occurring unilaterally or bilaterally in two lateral or rarely anterolateral rows. Branches range from ~0.3 to ~ 1 mm in diameter excluding spine heights. Terminal branchlets are mostly 4 to 10 mm in length, have basal diameters ranging from 0.11 to 0.25 mm, and are spaced 2 to 5 mm apart on one side of a branch resulting in about 8 to 10 terminal branchlets per cm, counting terminal branches on both sides of the branch. Branches and terminal branchlets form ~45 to almost 90° distal angles and can be almost straight or slightly curved upwards. Spines on terminal branchlets are smooth, conical, and laterally compressed. Spines are slightly distally inclined or perpendicular to the axis with convex proximal sides, and tips curved slightly upwards (Fig. 3C). On terminal branchlets with diameters from 0.11 to 0.25 mm, polypar spine heights range from 0.12 to 0.19 mm and abpolypar spine heights range from 0.085 to 0.11 mm (Fig. 3C). On lower order branches, spines are more conical and can possess two to four small conical knobs 0.01 to 0.03 mm tall, concentrated near their apexes that are directed in the same general direction as the spine. On a section of a branch 0.22 mm in diameter, polypar spines are 0.13 mm and abpolypar spines are 0.1 mm (Fig. 3D). Four to five axial rows of spines can be counted in one view of branches and terminal branchlets and four to seven spines can be counted in one cm, in one row. Polyps are yellow to brown in color, oblong in shape, and occur on one side of the colony, in one row. Polyps are 0.8 to 1 mm in transverse diameter and spaced ~ 0.2 mm apart resulting in about nine polyps per cm (Fig. 3E). Comparative diagnosis. Twenty-one out of 67 nominal species possess flabellate planar corallums with anastomoses. Of this number, Antipathes clathrata Pallas, 1766 and Antipathes tristis (Duchassaing, 1870) have very vague original descriptions that lack sufficient taxonomic information to clearly separate these two species. All other species can be distinguished from the new species. Antipathes delicatula Schultze, 1896 and Antipathes ceylonensis (Thomson & Simpson, 1905) are more loosely branched than the new species. Antipathes atlantica Gray, 1857, A. ceylonensis, Antipathes gracilis Gray, 1860, Antipathes indistincta (van Pesch, 1914) and Antipathes rhipidion Pax, 1916 form only rare occasional anastomoses, whereas the new species form a densely anastomosing fan. Antipathes craticulata Opresko, 2015, Antipathes dubia (Brook, 1889) and Antipathes plana Cooper, 1909 have uniserial arrangement of terminal branchlets throughout the corallum in contrast to new species, that demonstrate characteristic biserial arrangement (Fig. 3B). The new species is also different than A. craticulata by having less distinctly curved branches and terminal branchlets. Antipathes hypnoides (Brook, 1889), Antipathes minor (Brook, 1889), Antipathes sibogae (van Pesch, 1914), and Antipathes elegans (Thomson & Simpson, 1905) have polyps less than 0.5 mm in transverse diameter compared with 0.8 to 1.0 mm in the new species. The new species is also different than A. hypnoides by having much more regularly spaced terminal branchlets and a lower density of terminal branchlets (4 per cm vs> 9 per cm). Antipathes assimilis (Brook, 1889), Antipathes flabellum Pallas, 1776 (sensu Terrano et al., 2021), Antipathes irregularis (Thomson and Simpson, 1905), Antipathes ternatensis Schultze, 1896, Antipathes zoothallus Pax, 1932 and Antipathes speciosa (Brook, 1889) have rather small spine heights 0.09 mm and less, whereas the new species has polypar spines 0.12-0.19 mm and abpolypar spines 0.008 5 to 0.11 mm. The new species is also different than A. flabellum by having branches projecting perpendicular to the colony plane, narrower distal angles (45° vs 79°), and spines that are more perpendicular. The new species has some similarities with Antipathes aculeata (Brook, 1889) including fused branches and short spines with sharp and sometimes forked tips. However, the new species differs from A. aculeata regarding the colony thickness where the new species is only 1 cm thick because branches and terminal branchlets are arranged bilaterally forming a distinct fan-shape while A. aculeata forms a dense mass of branches resembling a bush. Also, the new species has a smaller terminal branchlet basal diameter compared to A. aculeata (0.11 to 0.25 mm vs 0.3 mm). The new species also has some features similar with Arachnopathes ericoides (Pallas, 1776) like fused branches and short branchlets slightly curved upwards; however, as with A. aculeata, the new species forms a fan while Ar. ericoides forms a thick and dense mass, like A. aculeata. Additionally, Ar. ericoides has spines that can be forked and inclined in different directions, including downwards, and can lack longitudinal rows (Terrana et al. 2020) while the new species has spines that are not forked but can be slightly multi-knobbed, not proximally directed, and form distinct longitudinal rows along branches and terminal branchlets. This new species is phylogenetically similar to A. falkorae sp. nov. and Ar. ericoides; however, A. morrisi sp. nov. and Ar. ericoides have fused branches while A. falkorae sp. nov. does not contain any fused branches (see description below). A. falkorae sp. nov. also contains longer and straighter branches that form fronds rather than the single fan characteristic of A. morrisi sp. nov. The morphological differences are sufficient to separate the species and the phylogenetic comparison does not include holotype or topotype specimens for most species being compared with the new species in the Antipathidae, which should be done in future studies that are devoted to species delimitations. Etymology. In recognition of the Morris Family Foundation that funds research at the Orpheus Island Research Station where the new species was first found and collected. Distribution. Known only from the Great Barrier Reef at 14 m depth., Published as part of Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F. & Bridge, Tom C. L., 2022, Five new species of black coral (Anthozoa; Antipatharia) from the Great Barrier Reef and Coral Sea, Australia, pp. 1-35 in Zootaxa 5213 (1) on pages 4-5, DOI: 10.11646/zootaxa.5213.1.1, http://zenodo.org/record/7350036, {"references":["Pallas, P. (1766) s. n. In: Elenchus zoophytorum sistens generum adumbrationes generaliores et specierum cognitarum succintas descriptiones, cum selectis auctorum synonymis. Apud Petrum van Cleef, IIagae-Comitum the Hagae, pp. 451 - 451.","Duchassaing, de F. (1870) s. n. In: Revue des zoophytes des spongiaires des Antilles. V. Masson, Paris, pp. 23 - 24.","Schultze, L. (1896) Beitrag Zur Systematik Der Antipatharien. Abhandlungen der Senckenbergischen Naturforschenden Gesellschaft, 23, 1 - 40.","Thomson, J. & Simpson, J. J. (1905) Report on the Antipatharia collected by Prof. Herdman at Ceylon in 1902. Supplemental Report No. XXV to the Report to the Government of Ceylon on the Pearl Oyster Fisheries of the Gulf of Manaar, Part 4, 93 - 106.","Gray, J. E. (1857) Synopsis of the families and genera of axiferous zoophytes or barked corals. Proceedings of the Zoological Society of London, 25, 278 - 294. https: // doi. org / 10.1111 / j. 1096 - 3642.1857. tb 01242. x","Gray, J. E. (1860) Notice of some new corals from Madeira discovered by JY Johnson, Esq. The Annals and magazine of natural history; zoology, botany, and geology being a continuation of the Annals combined with Loudon and Charlesworth's Magazine of Natural History, 6, 311.","Pesch, A. J. van (1914) The Antipatharia of the Siboga Expedition. Siboga-Expeditie, 17, 1 - 258.","Pax, F. (1916) Eine neue Antipathes-Art aus Westindien. Zoologische Jahrbucher, Supplement 11, 433 - 436.","Opresko, D. M. (2015) New species of black corals (Cnidaria: Anthozoa: Antipatharia) from New Zealand and adjacent regions. New Zealand Journal of Zoology, 42, 145 - 164. https: // doi. org / 10.1080 / 03014223.2015.1051550","Brook, G. (1889) Report on the Antipatharia. Report on the scientific results of the voyage of H. M. S. Challenger, 32, 1 - 222.","Cooper, C. F. (1909) Antipatharia. Reports of the Percy Sladen Trust Expedition to the Indian Ocean. In: Transactions of the Linnean Society of London, Zoology Series 2, 12, 301 - 323.","Pax, F. (1932) Beitrag zur Kenntnis der japanischen Dornchenkorallen. Zoologische Jahrbucher, 63, 407 - 450.","Terrana, L., Bo, M., Opresko, D. M. & Eeckhaut, I. (2020) Shallow-water black corals (Cnidaria: Anthozoa: Hexacorallia: Antipatharia) from SW Madagascar. Zootaxa, 4826, 1 - 62. https: // doi. org / 10.11646 / zootaxa. 4826.1.1"]}

Published
2022
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28. Rhipidipathes helae Horowitz & Opresko & Molodtsova & Beaman & Cowman & Bridge 2022, sp. nov

Author

Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F., and Bridge, Tom C. L.

Subjects
Cnidaria, Rhipidipathes helae, Aphanipathidae, Animalia, Biodiversity, Rhipidipathes, Anthozoa, Antipatharia, Taxonomy
Abstract

Rhipidipathes helae Horowitz sp. nov. (Figs. 1–2 and 5; Tables 1 and Supplementary Table 1) Material examined: MTQ G80117, Australia, Great Barrier Reef, Bowl Slide, Schmidt Ocean Institute R / V Falkor Northern Depths of the Great Barrier Reef expedition FK200930, ROV SuBastian dive S0394, collected on October 5, 2020, 18.3865° S, 147.6705° E, 119 m depth, collector Jeremy Horowitz. Diagnosis: Corallum flabellate, branched; branches and branchlets extensively anastomosing. Terminal branchlets 0.5 to 1 cm in length and 0.08 mm in diameter, arranged bilaterally, are irregularly alternate, opposite, or subopposite, and slightly protrude from the colony plane. Spines on branches perpendicular or distally inclined. Circumpolypar spines 0.23 to 0.29 mm tall and hypostomal and interpolypar spines maximum of 0.11 mm tall. Spines on terminal branchlets are distinctly curved apically and rarely basally. Five to six axial rows of spines can be counted in one view. Surface of spines extensively tuberculated, especially from about the midpoint to the apex. Polyps roundish, 0.8 mm in transverse diameter. Interpolypar space 0.1 to 0.2 mm, with 10 polyps per cm. Description of holotype: Colony flabellate and about 20 cm wide and 20 cm high based on estimations from in situ images (Figs. 5A–B). Collected sample about 7 cm wide and 9 cm tall. Longest branches are ~ 8 cm in length and have 0.1 cm basal diameter. Terminal branchlets are 0.5 to 1 cm in length, arranged bilaterally, and are either irregularly alternate, opposite, or subopposite. Branchlets often not strictly bilateral but slightly protrude from the general plane of the colony forming ~120° interior angles. Most terminal branchlets form ~80° distal angles and are slightly curved distally (Fig. 5B). There is extensive fusing among branches and terminal branchlets (Fig. 5C). Four anastomosing branches/branchlets can be counted in a 5 cm 2 fragment of a colony. Terminal branchlet basal diameter is 0.08 mm, distance between neighboring terminal branchlets ranges from 1 to 3 mm, and about 10 branchlets can be counted per cm of a branch, counting branches in both rows. On a branch 0.2 mm thick, polypar spines are anisomorphic with circumpolypar spines ranging from 0.23 to 0.29 mm tall and hypostomal and interpolypar spines reduced to 0.11 mm. Abpolypar spines are uniform in height, ranging from 0.13 to 0.15 mm (Fig. 5D). Polypar spines on branches are positioned mostly perpendicular to the axis or slightly distally inclined and abpolypar spines are more distally directed than polypar spines, creating ~45° distal angles (Figs. 5D–E). Six to 10 conical and apically directed tubercles can be counted in lateral view of the polypar spines, including those on the edges (Fig. 5E) and three to six tubercles can be counted in lateral view of abpolypar spines, with the proximal surface of all spines being mostly smooth (Figs. 5C–D). Tubercles become elongated and strongly appressed to the surface of the spine as they increase in size, reaching a maximum size of 0.03 mm (measuring the distance from the base of the tubercle to the apex of the tubercle). Tip of largest tubercles up to 0.004 mm above the spine surface (Fig. 5E). On thin branchlets (0.08 to 0.095 mm in diameter), circumpolypar spines are 0.13 mm tall, oriented perpendicular to the axis, and are distinctly curved upward (Fig. 5D, right image). On thin branchlets abpolypar spines are 0.11 mm tall, distally directed and are curved upward. On thin branchlets, a maximum of three tubercles can be counted in one lateral view of the surface of polypar and abpolypar spines, with the proximal surface of all spines being mostly smooth. On branches and terminal branchlets, five to six uneven axial rows of spines can be counted in one view. Polyps are pink, roundish with equally developed tentacles, and sagittal tentacles positioned slightly lower than lateral tentacles (Fig. 5B). On terminal branchlets and branches, polyps occur in one row; however, polyps can be arranged in several rows along thicker branches near the base of the colony. Polyps are ~ 0.8 mm in the transverse diameter and spaced 0.1 to 0.2 mm apart, resulting in 10 polyps per cm. Tentacles are approximated from in situ images to be 0.15 mm in length, when extended. Comparative diagnosis. This is the third nominal species in the genus Rhipidipathes. Rhipidipathes reticulata (Esper 1795) and Rhipidipathes colombiana (Opresko & Sánchez 1997) are similar in most features (See Table 1 for comparison of three species); however, R. colombiana has limited anastomosing branchlets, hypostomal spines that are only minimally reduced in size, and spines with almost no tubercles while R. reticulata has greater anastomosing branchlets, reduced hypostomal spines, and possesses tubercles on polypar spines. The new species is morphologically and phylogenetically most similar to R. reticulata by having highly anastomosing branchlets and terminal branches, reduced hypostomal spines and clear presence of tubercles on spines. The new species is different from R. reticulata by having thinner terminal branchlets (0.08 vs 0.22 mm in the type) and has spines on terminal branchlets that are distinctly curved, mostly upward but sometimes downward, not found in R. reticulata. See comparison of spines on a terminal branchlet between R. helae sp. nov. (Fig. 5D, right image) that possesses upward curved spines and R. reticulata holotype (Fig. 5F) that possesses straight spines. Additionally, the new species has a greater number of tubercules on polypar and abpolypar spines than R. reticulata (six to 10 vs three to seven tubercles in one view of a polypar spine, and three to six vs zero to three tubercles in one view of an abpolypar spine). Etymology: From the Norse, “hel”, goddess of death, who is depicted wearing a headdress of curved deer antlers that resemble the distinctively curved spines of the new species. Distribution. Known only from the Great Barrier Reef at 119 m depth., Published as part of Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F. & Bridge, Tom C. L., 2022, Five new species of black coral (Anthozoa; Antipatharia) from the Great Barrier Reef and Coral Sea, Australia, pp. 1-35 in Zootaxa 5213 (1) on pages 10-13, DOI: 10.11646/zootaxa.5213.1.1, http://zenodo.org/record/7350036, {"references":["Opresko, D. M. & Sanchez, J. A. (1997) A new species of antipatharian coral (Cnidaria: Anthozoa) from the Caribbean Coast of Colombia. Caribbean Journal of Science, 33, 75 - 81.","Esper, E. J. C. (1795) Die Pflanzenthiere in Abbildungen nach der Natur mit Farben erleuchtet nebst Beschreibungen. in der Raspischen Buchhandlung, Nurnberg, 303 pp.","Opresko, D. M. & Baron-Szabo, R. C. (2001) Re-descriptions of the antipatharian corals described by E. J. C. Esper with selected English translations of the original German text. Senckenbergiana biologica, 81, 1 - 21."]}

Published
2022
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29. Hexapathes bikofskii Horowitz & Opresko & Molodtsova & Beaman & Cowman & Bridge 2022, sp. nov

Author

Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F., and Bridge, Tom C. L.

Subjects
Cnidaria, Cladopathidae, Animalia, Hexapathes bikofskii, Biodiversity, Hexapathes, Anthozoa, Antipatharia, Taxonomy
Abstract

Hexapathes bikofskii Horowitz sp. nov. (Figs. 1–2 and 7; Supplementary Table 1 and Table 2) Material examined: Holotype. MTQ G80122, Australia, Great Barrier Reef, Noddy Reef, expedition Schmidt Ocean Institute R / V Falkor Seamounts, Canyons, and Reefs of the Coral Sea expedition 200802, ROV Subastian dive S0398, collected on October 15, 2020, 13.5174° S, 144.1012° E, 789 m depth, collector Jeremy Horowitz. Paratype. MTQ G80024, Australia, Coral Sea, Herald Cays, expedition Schmidt Ocean Institute R / V Falkor Seamounts, Canyons, and Reefs of the Coral Sea expedition 200802, ROV SuBastian dive S0376, collected on August 08, 2020, - 16.9095° S, 149.1601° E, 638 m depth, collector Jeremy Horowitz. Diagnosis: Colony monopodial, unbranched, and pinnulate. Pinnules arranged in two lateral rows and one anterior row. Basal-most pair of lateral pinnules subopposite, other lateral pinnules alternating. Striatum present from 1 cm above basal plate to first anterior pinnules. Lateral pinnules simple, up to 12 cm long, densities of six to 10 per 3 cm counting both rows. Anterior pinnules simple, 0.8 to 1.2 cm in length, densities of 11 to 15 per 3 cm. Polyps 4 to 6 mm in transverse diameter. Description of holotype (G80122): Colony is monopodial and pinnulate with a slight sickle shape curvature of the stem (Fig. 7A). Grooves and ridges on the stem are present from 1 cm from the basal plate to the first anterior pinnule. Colony is 23 cm tall and 17 cm wide. Unpinnulated section of the stem is 4 cm and the pinnulated section of the stem is 19 cm (Fig. 7A). The specimen has two rows of lateral pinnules where the bottom pair of pinnules are subopposite and positioned perpendicular to the stem. Above the bottom pair of pinnules, pinnules are arranged alternately with distal angles ranging from ~80° at the bottom of the pinnulated section to ~20° at the top; with most pinnules having 45° distal angles. Lateral pinnules are curved forward and then backward so that the pinnule tips face in the opposite direction from the anterior pinnules. Lateral pinnules increase in length from the lowest pair of pinnules, which are ~ 8.5 cm, to midway up the pinnulated section where the longest pinnules are 12 cm, and then decrease towards the apex where the most distal pinnules are ~ 3 cm. Lateral pinnules are ~ 0.5 mm in diameter near the attachment point, and distances between pinnules in each row range from 5 to 10 mm (increasing in distance distally), resulting in 10 lateral pinnules counted near the bottom of the pinnulated section of the stem and six pinnules counted near the top of the pinnulated section, per 3 cm counting lateral pinnules in both rows. Anterior pinnules are simple, in one row and range from 0.8 to 1.5 cm in height, with most up to 1 cm in height. Distance between anterior pinnules range from 2 to 3 mm, resulting in 11 to 13 anterior pinnules counted per 3 cm. Spines on lateral pinnules are 0.025 to 0.1 mm in height, smooth, triangular, and distally directed (Fig. 7B). Lateral pinnule spines are spaced 0.45 to 0.7 mm apart in each row, and two spines can be counted per mm in one row. Four axial rows of spines can be counted in lateral view (Fig. 7B). Spines on anterior pinnules are smooth, triangular to conical, and distally directed. Spine heights are variable, ranging from 0.04 to 0.08 mm, and the distance between spines in one row is about 0.25 mm. Three to four axial rows of spines can be counted in one view of anterior pinnules. Polyps are ~ 4 to 6 mm in the transverse diameter and 6 to 8 polyps counted per three cm. Description of paratype (G80024): The colony is monopodial and pinnulate with a slight sickle shape curvature of the stem (Fig. 7C) and has two rows of distally directed lateral pinnules. Grooves and ridges are present along the stem from 1 cm above basal plate to the first anterior pinnule. Colony is 13 cm tall and 13 cm wide. The unpinnulated section of the stem is 4 cm and the pinnulated section is 9 cm in height. The lowest pair of pinnules are suboppositely arranged and are positioned almost perpendicular to the axis. All other pinnules are alternating and have distal angles ranging from ~20 degrees proximally to ~80 degrees distally. Lateral pinnules increase in length from the lowest pair of pinnules, which are 4 cm, to midway up the pinnulated section where the longest pinnules range from 6. 5 to 8 cm, and then decreasing towards the apex where the highest pair of pinnules are ~ 3 cm (Fig. 7C). Distances between pinnules range from 5 to 9 mm (increasing in distance distally), resulting in eight pinnules (near the top of the pinnulated section of stem) to 10 pinnules (near the bottom of the pinnulated section of stem) per 3 cm, counting lateral pinnules in both rows. Lateral pinnules are 0.3 mm in diameter near the attachment point. Anterior pinnules are simple, in one row with lengths ranging from 0.5 to 1 cm, with most pinnules being close to 1 cm (Fig. 7D). Anterior pinnules begin from the same height on the stem as the second lowest lateral pinnules, and extend to 5 mm above the most distal lateral pinnule. Anterior pinnules are 0.18 mm in diameter near the attachment point, and distances between pinnules range from 2 to 4 mm, resulting in 13 to 15 pinnules per 3 cm. Spines on lateral pinnules 0.05 mm in height and are smooth and triangular (Fig. 7E). Lateral pinnule spines have distances between spines in one row from 0.48 to 0.7 mm and two to three spines can be counted in one mm in one row. Five axial rows of spines can be counted in one view. Spines on anterior pinnules are smooth, triangular to conical, and distally directed (Fig. 7F). Spine heights are variable, and range from 0.02 to 0.07 mm and distances between spines in one row range from 0.32 to 0.45 mm. Three to four axial rows of spines can be counted in one view of anterior pinnules. Polyps are in a poor state of preservation and estimated based on in-situ images to be reddish in color and 6 mm in the transverse diameter. Comparative diagnosis. H. bikofskii sp. nov. is different than other species in Hexapathes by having only one row of simple (unpinnulated) and short (maximum of 1 cm in the new species vs maximum of 6 to 11 cm in currently described Hexapathes spp.) and straight anterior pinnules. See Table 2 for comparison of species in the genus. The new species is like H. australiensis Opresko, 2003 and H. alis Molodtsova, 2006 by having just one row of anterior pinnules; however, the anterior pinnules of both species are subpinnulated while the new species has simple anterior pinnules. The new species is like H. hivaensis Molodtsova, 2006 and H. heterosticha Kinoshita, 1910 by lacking anterior subpinnules; however, both species have two or more rows of anterior pinnules while the new species only has one row of anterior pinnules. Another difference between the new species and currently described species in the genus is the length of the unpinnulated section of the stem (ranging from 2 to 2.5 cm in described species vs 4 cm in the new species). The new species shares other features with H. australiensis for the following morphometrics: 1) distance between lateral pinnules on one side of the stem (0.5 to 1 cm vs 0.4 to 1.1 cm in H. australiensis), both of which have spaces greater than the other three described species, and 2) the basal diameter of lateral pinnules is 0.3 to 0.5 mm in the new species and 0.5 mm in H. australiensis), both of which are smaller than the other three described species. The two specimens representing the new species form a clade sister to H. heterosticha; however, the other species in the genus have yet to be sequenced. Specimens representing species in the genus Hexapathes should be sequenced to further investigate morphological boundaries between species. Etymology: In recognition of lead author’s grandfather, Morton Isaiah Bikofsky, a high school teacher whose passion for science fuelled JH’s interest in research. Distribution. Known only from the Great Barrier Reef and Coral Sea from 638 to 789 m depth.

Published
2022
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30. Antipathes falkorae Horowitz & Opresko & Molodtsova & Beaman & Cowman & Bridge 2022, sp. nov

Author

Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F., and Bridge, Tom C. L.

Subjects
Cnidaria, Antipathes, Antipathidae, Animalia, Biodiversity, Anthozoa, Antipatharia, Antipathes falkorae, Taxonomy
Abstract

Antipathes falkorae Horowitz sp. nov. (Figs. 1–2 and 4; Supplementary Table 1) Material examined. Holotype, MTQ G80067, Australia, Great Barrier Reef, Ribbon Reef Canyons, Schmidt Ocean Institute R / V Falkor, Seamounts, Canyons, and Reefs of the Coral Sea expedition FK200802, ROV SuBastian dive S0385, collected on August 18, 2020, - 15.3968° S, 145.7934° E, 111 m depth, collector Jeremy Horowitz. Diagnosis. Colony fan-like, with unilateral and sparse branching mostly to the second and third order; terminal branchlets 3 to 5 cm long and curved proximally forming 45° distal branch angles. Spines conical, mostly smooth with distinct apical knobs, secondary knobs, and some papillae on the apical section of spines 0.15 to 0.17 mm tall. Four to five axial rows of spines counted in one view. Polyps 0.8 to 1 cm in transverse diameter and eight polyps per cm. Description of holotype. Specimen is fan-like and 21 cm in height (lowermost 5 cm or more of the stem and the holdfast not collected); branched mostly to the second and rarely to the third or fourth order, with stiff and straight or slightly curved vertically directed branches (Figs. 4A–B). Distal branch angles are mostly 45°. Branching is sparse and in one plane, with mostly one and sometimes two or three branches occurring on a given lower order branch. Branching is unilateral with successive orders of branches often arising on the same side as the lower order branches. The five most basal branches are disposed on one side of the stem with subsequent branches disposed on the same side as lower order branches, while the four most apical branches occur on the opposite side of the stem and have higher order branches disposed on the same side as their direct lower order branches (Fig. 4B). The one branch between the five most basal and four most apical branches is disposed on the same side as the basal branches but has secondary branches occurring on both sides of the branch. Terminal branchlets are 3 to 5 cm in length and 0.19 to 0.2 mm in diameter near the base (Fig. 4B). The lowest portion of the stem is 0.9 mm in diameter. Spines on a branch 0.2 mm thick or greater have polypar spines 0.15 to 0.17 mm tall and abpolypar spines 0.1 to 0.15 mm tall (Fig. 4C). On branches 0.20 mm in diameter, spines are about 0.14 mm tall (Fig. 4D), and on terminal branchlets 0.2 mm or less in diameter, spines are at most 0.13 mm tall (Fig. 4E). Spines on large (about 0.2 mm or thicker) branches have extensive apical knobbing with knobs reaching maximum heights of 0.04 mm (Fig. 4F). Where knobbing is most pronounced, spine tips flare outward (at right angles to the direction of the branch axis) and become vertically compressed with small secondary knobs occurring on primary knobs (Fig. 4G). Faint papillae can be seen on and in between well-developed knobs (Fig. 4G). Spines on terminal branchlets less than 0.2 mm in diameter have few or no apical knobs, and are smooth, triangular, slightly distally directed, laterally compressed. Four to five axial rows of spines can be counted in one view; 3.5 to 4 spines can be counted in one mm; and distances between axial rows range from ~0.3 to 0.4 mm. Polyps are yellow to white in color, 0.8 to 1 mm in the transverse diameter with about 0.5 mm space between polyps resulting in about eight polyps in one cm (Fig. 4H). Comparative diagnosis. A. falkorae sp. nov. is most like Antipathes coronata Opresko, 2019 by having straight and vertically directed branches, unilateral branching, slightly larger polypar than abpolypar spines, and apical knobs on the spines. However, the new species has more extensive apical knobbing where on a spine ~ 0.14 mm tall, the new species has five to six primary knobs compared to A. coronata, which has three knobs. The new species also has small protrusions that could be considered secondary knobs on top of primary knobs that are absent on A. coronata. The new species has on average a smaller terminal branchlet diameter than A. coronata (0.2 vs 0.3 mm); however, both species have ~5 axial spine rows visible in a lateral view. The new species also has slightly wider distal branch angles that create more of a fan shape compared to A. coronata. Lastly, the new species has very faint papillae on and in between primary and secondary knobs, which differs from A. coronata that has smooth knobs. Antipathes elegans Thomson & Simpson 1905 and A. gallensis Thomson & Simpson 1905 are also morphologically like A. falkorae sp. nov. where both have apical knobbing on the spines and faint papillae on the surface of the spines; however, the new species is different from both species by having more extensive knobbing (about six knobs per spine vs three to four in A. elegans and A. gallensis) and a presence of secondary knobs that are lacking in these other species. This new species is phylogenetically similar to Ar. ericoides and A. aculeata (Supplementary Table 3); however, the new species does not possess fused branches while Ar. ericoides and A. aculeata have high levels of fused branches. Additionally, the specimens representing A. aculeata are not holotype or topotype specimens, which explains why they do not form a monophyletic relationship. The new species also has a low phylogenetic distance with A. morrisi sp. nov. and a feature that unites the two new species is a presence of apical knobs on the spines. However, A. morrisi sp. nov. has fused branches, unlike A. falkorae sp. nov. Etymology. In recognition of the Schmidt Ocean Institute R/V Falkor, onboard which this and many other black coral species were collected from the Great Barrier Reef and Coral Sea. Distribution. Known only from the Great Barrier Reef at 111 m depth.

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2022
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31. Aphanipathes Brook 1889

Author

Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F., and Bridge, Tom C. L.

Subjects
Cnidaria, Aphanipathes, Aphanipathidae, Animalia, Biodiversity, Anthozoa, Antipatharia, Taxonomy
Abstract

Genus Aphanipathes Brook, 1889 Diagnosis. Colony sparsely to densely, irregularly branched, bushy, sometimes broom-like, with short to long, straight or curved, often ascending branches. Spines with tall and pronounced tubercles. Type Species. Aphanipathes sarothamnoides Brook, 1889 Type Locality. Vanuatu, Published as part of Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F. & Bridge, Tom C. L., 2022, Five new species of black coral (Anthozoa; Antipatharia) from the Great Barrier Reef and Coral Sea, Australia, pp. 1-35 in Zootaxa 5213 (1) on page 13, DOI: 10.11646/zootaxa.5213.1.1, http://zenodo.org/record/7350036, {"references":["Brook, G. (1889) Report on the Antipatharia. Report on the scientific results of the voyage of H. M. S. Challenger, 32, 1 - 222."]}

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2022
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32. Antipathes Pallas 1766

Author

Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F., and Bridge, Tom C. L.

Subjects
Cnidaria, Antipathes, Antipathidae, Animalia, Biodiversity, Anthozoa, Antipatharia, Taxonomy
Abstract

Genus Antipathes Pallas, 1766 Diagnosis (after Opresko 2019). Corallum sparsely to densely branched. Branching bushy, bramble-like, broomlike, or fan-shaped. Terminal branchlets of varying length; arranged irregularly, or bilaterally. Spines triangular or cone-shaped in lateral view; smooth or papillose; apex of spines simple or with one or more lobes or bifurcations. Polyps less than 1 mm in transverse diameter. Type Species. Antipathes dichotoma Pallas, 1766 Type Locality. Mediterranean Sea Remarks. Antipathes dichotoma is the type species of the Antipathidae; however, molecular studies (Bo et al. 2018; Brugler et al. 2013), including this study (Fig. 2), have found that the species is more closely related to species in the Aphanipathidae than the Antipathidae. A formal review with integrated morphological and molecular data of all species in each family is required to resolve this taxonomic issue., Published as part of Horowitz, Jeremy, Opresko, Dennis, Molodtsova, Tina N., Beaman, Robin J., Cowman, Peter F. & Bridge, Tom C. L., 2022, Five new species of black coral (Anthozoa; Antipatharia) from the Great Barrier Reef and Coral Sea, Australia, pp. 1-35 in Zootaxa 5213 (1) on page 4, DOI: 10.11646/zootaxa.5213.1.1, http://zenodo.org/record/7350036, {"references":["Pallas, P. (1766) s. n. In: Elenchus zoophytorum sistens generum adumbrationes generaliores et specierum cognitarum succintas descriptiones, cum selectis auctorum synonymis. Apud Petrum van Cleef, IIagae-Comitum the Hagae, pp. 451 - 451.","Opresko, D. M. (2019) New species of black corals (Cnidaria: Anthozoa: Antipatharia) from the New Zealand region, part 2. New Zealand Journal of Zoology, 47, 149 - 186. https: // doi. org / 10.1080 / 03014223.2019.1650783","Bo, M., Barucca, M., Biscotti, M. A., Brugler, M. R., Canapa, A., Canese, S., lo Iacono, C. & Bavestrello, G. (2018) Phylogenetic relationships of Mediterranean black corals (Cnidaria: Anthozoa: Hexacorallia) and implications for classification within the order Antipatharia. Invertebrate Systematics, 32, 1102. https: // doi. org / 10.1071 / is 17043","Brugler, M. R., Opresko, D. M. & France, S. C. (2013) The evolutionary history of the order Antipatharia (Cnidaria: Anthozoa: Hexacorallia) as inferred from mitochondrial and nuclear DNA: implications for black coral taxonomy and systematics. Zoological Journal of the Linnean Society, 169, 312 - 361. https: // doi. org / 10.1111 / zoj. 12060"]}

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2022
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37. Consensus Guidelines for Advancing Coral Holobiont Genome and Specimen Voucher Deposition

Author

Voolstra, Christian R., primary, Quigley, Kate M., additional, Davies, Sarah W., additional, Parkinson, John Everett, additional, Peixoto, Raquel S., additional, Aranda, Manuel, additional, Baker, Andrew C., additional, Barno, Adam R., additional, Barshis, Daniel J., additional, Benzoni, Francesca, additional, Bonito, Victor, additional, Bourne, David G., additional, Buitrago-López, Carol, additional, Bridge, Tom C. L., additional, Chan, Cheong Xin, additional, Combosch, David J., additional, Craggs, Jamie, additional, Frommlet, Jörg C., additional, Herrera, Santiago, additional, Quattrini, Andrea M., additional, Röthig, Till, additional, Reimer, James D., additional, Rubio-Portillo, Esther, additional, Suggett, David J., additional, Villela, Helena, additional, Ziegler, Maren, additional, and Sweet, Michael, additional

Published
2021
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38. Blastopathes Horowitz & Brugler & Bridge & Cowman 2020, gen. nov

Author

Horowitz, Jeremy, Brugler, Mercer R., Bridge, Tom C. L., and Cowman, Peter F.

Subjects
Cnidaria, Antipathidae, Blastopathes, Animalia, Biodiversity, Anthozoa, Antipatharia, Taxonomy
Abstract

Blastopathes Horowitz gen. nov. (Figures 2–8; Tables 1–2) Diagnosis. Corallum sparsely branched to the third and sometimes fourth order, not pinnulate. Branches long (up to 1.3 m) and spaced far apart (distances between first order branches and second order branches range from 210 cm to 560 cm) and occurring singly or in verticil-like clusters of varying numbers (as many as 10). Stem and branches thick (up to 6 mm diameter) and rigid. Each branch extending out at their base perpendicular to the stem and lower order branches from which they arise, and then curving upward with distal ends being straight or curved. One branch can extend directly upwards from the center of the cluster. Spines triangular or conical, laterally compressed, smooth, up to 0.34 mm tall. Polyps, ~ 1.25 mm in transverse diameter, ~6 polyps per cm in one row. Sagittal tentacles (~ 8 mm in length, extended) are more than twice the length of lateral tentacles (~ 3 mm in length, extended). Remarks. Blastopathes morphologically resembles Allopathes Opresko & Cairns, 1994, which also has stemlike branches coming from a singular location on the corallum (Opresko & Cairns 1994). However; Blastopathes differs from Allopathes by having branch clusters that do not necessarily occur near the base of the stem and in having more than one branch cluster (Figures 2 A–2B). Additionally, the abpolypar spines of Blastopathes are triangular, smooth, and distally slanted while all spines of Allopathes are conical with conical tubercles near the apex (Figures 2 C–2D). Other genera that contain sparse and elongate branches are Pteropathes Brook, 1889, Hillopathes van Pesch, 1910, and in the genus Antipathes, Antipathes dichotoma Palla, 1766; however, none contain branch clusters. Lastly, Blastopathes contains a stiff and non-pinnulate stem and branches that resemble unbranched genera Pseudocirrhipathes Bo et al., 2009, Cirrhipathes de Blainville, 1830, and Stichopathes Brook, 1889, all of which differ from Blastopathes by lacking branches. Molecular results. The mitochondrial igrN sequences for specimens NMAG 1893 and NMAG 1895 consisted of 482 base pairs. The two specimens shared identical sequences across 465 comparable bases. The complete igrN alignment consisted of 47 sequences, 682 bp, and included species from all seven black coral families. In the 682 bp alignment there were 274 parismony informative site (40%). Targeted capture data for 33 specimens that spanned six of the seven families in the Antipatharia, resulted in a total number of raw reads ranging from 44,898 to 3,603,888. One sample (10 raw reads, C705) was removed due to sequencing failure. Quality control and adapter trimming resulting in a mean of 1,606,997 ± 1,640,018 SD trimmed reads per sample. Trimmed reads were assembled into a mean of 927 ± 154 SD contigs per sample. The total number of matched UCE/exon loci was 2,309 with an average base pair length of 752 (ranging from 83 to 18,423 base pairs). The 75% taxon occupancy matrix included 286 loci that were concatenated into an alignment with a total length of 111,929 base pairs. A total of 36,052 parismony informative (PI) sites were identified (32% of total sites), with an average of 126.06 PI sites per locus.Alignment were also constructed for the for the holotype specimen (MTQ G74904) and the two paratype specimens (NMAG 1893 and NMAG 1895). The total number of matched loci across the three samples was 1,290 with an average base pair length of 623 (ranging from 189 to 4,068 bp). A complete (all three samples present in each loci) concatenated matrix included 792 loci, with a total alignment length of 499,264 base pairs. There were 3,855 variable sites (~0.7% of total sites) among the three samples. Despite the difference in species-level sampling, the maximum likelihood phylogenies displayed similar topologies for both alignment types (igrN, UCE/exon). In both cases, the new genus formed a distinct clade within the family Antipathidae and members of the genera Cirrhipathes and Antipathes formed separate monophyletic groups (Figures 3 A–3B). Differences between the two trees include the UCE/exon tree suggesting that Arachnopathes Milne Edwards H., 1857, and Stichopathes also share a common ancestor with Blastopathes, while in the igrN tree Stichopathes is more closely related to another lineage containing members of the Aphanipathidae Opresko, 2004, than to Blastopathes. Etymology. From the Greek “blastos”, germ, sprout, or shoot, in reference to the branch cluster features, and the commonly used suffix “pathes”. From the Latin “Medusa” in reference to thick and upward curving branches, like the snakes on the mythical gorgon’s head. Type material. Holotype, MTQ G74904, Papua New Guinea, Bismarck Sea, West New Britain Province, Kimbe Bay, Vanessa’s Reef, 35m depth, 13 March 2019 (SEM stubs MTQ G74906 to MTQ G74910, schizo- holotype NMAG 1892). Paratypes, NMAG 1893, Papua New Guinea, Bismarck Sea, West New Britain Province, Kimbe Bay, Christine’s Reef, 30m depth, 13 March 2019; MTQ G74911, Papua New Guinea, N Bismarck Sea, West New Britain Province, Kimbe Bay, Lady Di, 37m depth, 15 March 2019 (SEM stub MTQ G74912); MTQ G74913, Papua New Guinea, Bismarck Sea, West New Britain Province, Kimbe Bay Restrf Island, 30m depth, 16 March 2019 (SEM stub MTQ G74915); NMAG 1895, Papua New Guinea, Bismarck Sea, West New Britain Province, Kimbe Bay, Christine Reef, 30m depth, 16 March 2019. Type locality. Kimbe Bay, Papua New Guinea. Latitude: -5.305; Longitude: 150.124 Description. The holotype is a 1.2 m tall specimen that branches to the third order (Figure 4). The stem is 0.6 m in length, 6.3 mm in diameter near the base, and 4 mm in diameter just below the first branch cluster. First branch cluster occurs at the apex of the stem and consists of 10 elongate branches extending in different directions (Figure 5A) of varying lengths (maximum length 1.3 m) and diameters (none thicker than the stem). One first order branch is 0.6 m in length, 4 mm in diameter near the base, and 2 mm in diameter just below a second order branch cluster consisting of ~10 branches (Figure 5B), with a maximum branch length of 50 cm. Another first order branch is 1.3 m in length, 3 mm in diameter near the base, and 0.5 mm at the branch tip and does not produce a branch cluster. Another first order branch extends from the center of the branch cluster and extends 0.9 m directly upwards with a branch thickness of 4 mm near the base and 2 mm just below a second order branch cluster consisting of four branches with a maximum branch length of 65 cm. Another first order branch extends 5 cm, is 2 mm in diameter near the base and increases to 2.5 mm just below what resembles a new branch cluster consisting of three branches of different lengths and thicknesses. The longest of the three branches coming from the 5 cm branch is 0.6 m in length, 1.5 mm in diameter near the base, and 0.5 mm diameter near the tip. The second longest branch is 0.42 m in length, 0.2 mm in diameter near the base, and 0.1 mm near the tip. The shortest of the three branches is 5 cm in length, 0.8 mm in diameter near the base, and The spines (Figures 6 A–6C) on the branches and stem are smooth and laterally compressed. Polypar spines are 0.2 mm– 0.34 mm tall, are conical at right angles to branch axes with rounded apexes, and spines are spaced ~ 0.45 mm in one row (Figure 6A). Abpolypar spines are 0.12 mm– 0.24 mm tall and are triangular with distally slanted proximal edges and perpendicular or proximally slanted distal edges, and spines are spaced ~ 0.38 mm in one row (Figure 6B). Seven to eight, sometimes offset rows of spines can be counted in one view of a branch and stem, and approximately three spines can be counted in 1 mm of a spine row on a branch (Figure 6C) and stem. The polyps (Figures 7 A–7B), olive in color when alive, are arranged in a single row on thin branches (Figure 7A), and in multiple rows on the stem and thick branches (Figure 5A). In-situ measurements reveal that lateral tentacles (~ 3 mm in length, extended) are less than half the length of sagittal tentacles (~ 8 mm in length, extended) (Figure 7A). Polyps range 0.5 mm– 1.38 mm in transverse diameter and are spaced ~ 1 mm apart, resulting in approximately five polyps per 1 cm in one row (Figure 7B). The sizes of contracted and extended polyps are quite variable. ......continued on the next page MTQ—Museum of Tropical Queensland; TMAG—Tasmanian Museum of Art and Gallery; NMNH—Smithsonian National Museum of Natural History; RBINS—Royal Belgian Institute of Natural Sciences; CAS—California Academy of Sciences; ND—Not Deposited; DNA—Data Not Available. The paratypes (Figures 8 A–8E) range from 0.4 m to 0.5 m in height. The stem lengths range from 3 to 10 cm in length from basal plate to the first branch cluster. All paratypes have branch clusters (Figures 8 A–8C), 7 to 8 rows of compressed spines, tall and conical polypar spines, and triangular distally slanted abpolypar spines (Figure 8D), with polypar spine heights ranging from 0.14 mm to 0.3 mm and abpolypar spines ranging from 0.1 mm to 0.2 mm. About five polyps per 1 cm with lateral tentacles less than half the length of sagittal tentacles, with varying polyp sizes like the holotype (Figure 8E).

Published
2020
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39. Tongan socio-environmental spatial layers for marine ecosystem management

Author

Smallhorn-West, Patrick F., primary, Gordon, Sophie E., additional, Dempsey, Alexandra C., additional, Purkis, Sam J., additional, Malimali, Siola'a, additional, Halafihi, Tu'ikolongahau, additional, Southgate, Paul C., additional, Bridge, Tom C. L., additional, Pressey, Robert L., additional, and Jones, Geoffrey P., additional

Published
2021
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44. Parantipathes hirondelle MOLOdTSOVA 2006

Author

Horowitz, Jeremy, Opresko, Dennis M., and Bridge, Tom C. L.

Subjects
Cnidaria, Schizopathidae, Animalia, Parantipathes, Biodiversity, Anthozoa, Antipatharia, Parantipathes hirondelle, Taxonomy
Abstract

Parantipathes cf. hirondelle Molodtsova, 2006 (FIgS. 1 ANd 5) Parantipathes hirondelle Molodtsova, (2006): 142 ���143 (complete synonymy). Material examined: MTQ MATeRIAL (PReSeRVed IN eTHYL ALCOHOL): G35429 ANd G62019 (STATION dATA IN TAbLe 1). Diagnosis (after Molodtsova 2006): CORALLUM MONOPOdIAL OR VeRY SPARSeLY bRANCHed, PINNULATe. PINNULeS UP TO 2 CM IN LeNgTH, fORMINg dISTINCT bILATeRAL ANd ALTeRNATINg SeMISPIRAL gROUPS, WITH THRee TO fOUR PINNULeS PeR gROUP, 33 TO 40 PINNULeS (TOTAL fOR ALL gROUPS) PeR 1 CM. SPINeS SIMPLe, SMOOTH, ROUNded AT THe APeX, TRIANgULAR ANd COMPReSSed; 0.02 MM TO 0.06 MM TALL; ARRANged IN LONgITUdINAL ROWS, fOUR TO fIVe Of WHICH ARe VISIbLe IN LATeRAL VIeW, WITH SIX TO SeVeN SPINeS PeR 1 MM IN eACH ROW. POLYPS eLONgATed, 0.9 MM TO 1.7 MM IN TRANSVeRSe dIAMeTeR, WITH 6 TO 6.5 PeR 1 CM. Description of the CIDARIS Specimens: THe CIDARIS SPeCIMeNS ARe SIMILAR TO THe TYPe Of P. hirondelle IN bOTH THe deNSITY ANd ORIeNTATION Of PINNULeS WHeRe 38 PINNULeS (TOTAL fOR ALL gROUPS) CAN be COUNTed PeR 1 CM COMPARed WITH 33 TO 40 PeR 1 CM IN THe TYPe, ANd IN HAVINg, ON AVeRAge, SIX ROWS Of PINNULeS THAT fORM dISTINCT SeMISPIRAL ALTeRNATINg gROUPS (FIgURe 5A���5b). THe NUMbeR Of PINNULeS PeR gROUP INCReASeS fROM ONe ANd TWO PINNULeS PeR gROUP (CORReSPONdINg TO A TOTAL Of THRee ROWS) bASALLY ON THe STeM TO THRee ANd fIVe PINNULeS PeR gROUP (TOTAL Of 8 ROWS) dISTALLY NeAR THe APeX. IN CONTRAST, THe TYPe Of P. hirondelle HAS NO MORe THAN fOUR PINNULeS PeR gROUP. THe CIDARIS SPeCIMeNS ARe LIke THe TYPe Of P. hirondelle bY ALSO HAVINg LONgeR POSTeRIOR PINNULeS THAN ANTeRIOR PINNULeS. FOR eXAMPLe, THe LeNgTH Of THe LONgeST POSTeRIOR PINNULeS fOR SPeCIMeNS G35429 ANd G62019 ARe ~2 CM ANd 0.5 CM, ANd THe MAXIMUM LeNgTH Of ANTeRIOR PINNULeS ARe ~1 CM ANd 0.3 CM, ReSPeCTIVeLY (FIgUReS 5A ANd 5C). THe SPINeS Of THe CIDARIS SPeCIMeNS ARe SMOOTH, SIMPLe, TRIANgULAR, SOMeTIMeS INCLINed dISTALLY, WITH POLYPAR SPINe HeIgHTS beINg ~0.05 MM ANd AbPOLYPAR SPINe HeIgHTS beINg ~0.03 MM fROM MId-bASe TO TIP (FIgURe 5d). THRee TO fOUR AXIAL ROWS Of SPINeS CAN be SeeN fROM ONe ASPeCT (FIgURe 5d) WITH ~0.25 MM beTWeeN AdjACeNT SPINeS, ReSULTINg IN fIVe TO SIX SPINeS PeR 1 MM (FIgURe 5b). Remarks: CURReNTLY THeRe ARe NINe NOMINAL SPeCIeS IN THe geNUS Parantipathes: P. larix (ESPeR 1790), P. tetrasticha (POURTALeS 1868), P. laricides (VAN PeSH 1914), P. euantha (PASTeRNAk 1958), P. wolffi (PASTeRNAk 1977), P. helicosticha (OPReSkO 1998), P. hirondelle (MOLOdTSOVA 2006), P. dodecasticha (OPReSkO 2015), ANd P. robusta (OPReSkO 2015). THe TAXONOMIC CHARACTeRS Of THe fIRST SeVeN SPeCIeS HAVe beeN THOROUgHLY SUMMARIzed bY MOLOdTSOVA (2006), ANd THe LAST TWO HAVe beeN deSCRIbed ANd COMPARed TO THe fORMeR bY OPReSkO (2015). G35429 ANd G62019 HAVe PINNULeS THAT fORM dISTINCT SeMISPIRAL gROUPS WITH THeIR LONgeST PINNULeS beINg 2 CM ANd 0.5 CM, ReSPeCTIVeLY. THe LONgeST PINNULe LeNgTH IS ReLATIVeLY SMALL fOR Parantipathes SPP., bUT COULd POTeNTIALLY be ANY Of THe NINe SPeCIeS eXCePT fOR P. larix ANd P. tetrasticha, WHICH HAVe MUCH LARgeR MAXIMUM PINNULe LeNgTHS (6 CM TO 12 CM ANd 4 CM, ReSPeCTIVeLY). HOWeVeR, THe RATIO Of THe LONgeR POSTeRIOR PINNULeS COMPARed TO ANTeRIOR PINNULeS IS SIMILAR TO P. hirondelle, ANd WHeN CONSIdeRINg PINNULe ARRANgeMeNT, THe ReMAININg PINNULe CHARACTeRISTICS fIT beST WITH THe deSCRIPTION Of P. hirondelle beCAUSe THe CIDARIS SPeCIMeNS fORM dISTINCT SeMI SPIRAL gROUPS THAT dO NOT ARISe fROM THe SAMe POINT fOR A gIVeN gROUP AS WITH P. laricides ANd P. wolfi. FIVe TO SIX SPINeS CAN be COUNTed PeR 1 MM (FIgURe 5b) ANd THRee TO fOUR ROWS Of SPINeS CAN be COUNTed fROM ONe ASPeCT (FIgURe 5d), WHICH fALLS beTWeeN P. hirondelle (6 TO 7 SPINeS PeR 1 MM ANd fOUR TO fIVe ROWS Of SPINeS PeR ONe ASPeCT) ANd P. helicosticha (2 TO 3.5 SPINeS PeR 1 MM ANd 3 TO 4 ROWS Of SPINeS PeR ONe ASPeCT). HOWeVeR, P. helicosticha IS RePORTed TO HAVe ~25 PINNULeS PeR 1 CM (COUNTINg PINNULeS AROUNd THe STeM) WHILe THe CIDARIS SPeCIMeNS HAVe ~38 PINNULeS, LIke THe TYPe Of P. hirondelle (33-40 PINNULeS PeR 1 CM). THe SPINeS IN THe CIDARIS SPeCIMeNS RANge fROM 0.03 MM TO 0.05 MM IN HeIgHT fROM MId-bASe TO TIP (FIgURe 6d), WHICH fITS WITH P. hirondelle (0.02 MM TO 0.06 MM) ANd eXCLUdeS THe CIDARIS SPeCIMeNS fROM beINg P. dodecasticha ANd P. helicosticha beCAUSe THe LATTeR TWO HAVe SPINe HeIgHTS AS LARge AS 0.18 MM ANd 0.22 MM, ReSPeCTIVeLY. AddITIONALLY, THe CIDARIS SPeCIMeNS ARe UNLIkeLY TO be P. dodecasticha beCAUSe P. dodecasticha HAS AbOUT TWICe THe NUMbeR Of PINNULe ROWS AS THe CIDARIS SPeCIMeNS (12 IN P. dodecasticha COMPARed TO SIX IN THe CIDARIS SPeCIMeNS), ANd A HIgHeR AVeRAge NUMbeR Of PINNULeS PeR gROUP (fIVe TO SIX PINNULeS PeR gROUP IN P. dodecasticha COMPARed TO THRee TO fOUR PINNULeS PeR gROUP IN THe CIDARIS SPeCIMeNS). LASTLY, THe CIDARIS SPeCIMeNS ARe UNLIke THe TYPe Of P. robusta beCAUSe P. robusta CHARACTeRISTICALLY HAS fORked SPINeS NOT fOUNd IN THe CIDARIS SPeCIMeNS. POLYPS ARe NOT PReSeNT ON eITHeR Of THe CIDARIS SPeCIMeNS, THeRefORe, We CANNOT COMPARe POLYP SIze ANd deNSITY WITH THeSe feATUReS IN THe OTHeR SPeCIeS. Distribution: Parantipathes hirondelle HAS beeN RePORTed fROM THe NORTH ATLANTIC OCeAN fROM dePTHS Of 305 M TO 1,401 M, ANd THIS STUdY POTeNTIALLY eXPANdS THe dISTRIbUTION TO THe CORAL SeA, AUSTRALIA (FIgURe 1C), A RANge eXPANSION Of> 15,000 kM., Published as part of Horowitz, Jeremy, Opresko, Dennis M. & Bridge, Tom C. L., 2018, Black corals (Anthozoa: Antipatharia) from the deep (916 m - 2542 m) Coral Sea, north-eastern Australia, pp. 307-326 in Zootaxa 4472 (2) on pages 317-318, DOI: 10.11646/zootaxa.4472.2.5, http://zenodo.org/record/1440225, {"references":["Molodtsova, T. N. (2006) Black corals (Antipatharia: Anthozoa: Cnidaria) of the north-eastern Atlantic. In: Mironov, A. N., Gebruk, A. V. & Southward, A. J. (Eds.), Biogeography of the North Atlantic Seamounts. KMK Press, Moscow, pp. 141 - 151.","Esper, E. J. C. (1790) Die Pflanzenthiere in Abbildungen nach der Natur mit Farben erleuchtet nebst Beschreibunge, Vol. 2. Ntirnberg, 303 pp. https: // doi. org / 10.5962 / bhl. title. 118730","Pourtales, L. F. (1868) Contributions to the fauna of the Gulf Stream at great depths. Bulletin of the Museum of Comparative Zoology at Harvard College, in Cambridge, 1 (7), 121 - 142.","Pesch, A. J. van. (1914) The Antipatharia of the Siboga Expedition. Siboga-Expeditie Monographe, 17, 1 - 258.","Pasternak, F. A. (1958) Die Tiefsee Antipatharien des Kurilen-Kamchatka Grabens. Transactions of the P. P. Shirshov Institte of Oceanology, 27, 180 - 191.","Pasternak, F. A. (1977) Antipatharia. Galathea Report, 14, 157 - 164.","Opresko, D. M. (1998) Three new species of Leiopathes (Cnidaria: Anthozoa: Antipatharia) from Southern Australia. Records of the South Australian Museum, 31 (1), 99 - 111.","Opresko, D. M. (2015) New species of black corals (Cnidaria: Anthozoa: Antipatharia) from New Zealand and adjacent regions. New Zealand Journal of Zoology, 42 (3), 145 - 164. https: // doi. org / 10.1080 / 03014223.2015.1051550"]}

Published
2018
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45. Schizopathes affinis BROOk 1889

Author

Horowitz, Jeremy, Opresko, Dennis M., and Bridge, Tom C. L.

Subjects
Schizopathes, Cnidaria, Schizopathidae, Animalia, Schizopathes affinis, Biodiversity, Anthozoa, Antipatharia, Taxonomy
Abstract

Schizopathes affinis Brook, 1889 (FIgS. 1 ANd 6) Schizopathes affinis, Molodtsova & Opresko (2017): 360 ���361 (complete synonymy). Material examined: MTQ MATeRIAL (PReSeRVed IN eTHYL ALCOHOL): G61837, G61944, G61951, ANd G73230 (STATION dATA IN TAbLe 1). Diagnosis: COLONY MONOPOdIAL, UNbRANCHed, PINNULATe. PINNULeS SIMPLe, ARRANged ALTeRNATeLY IN TWO LATeRAL ROWS ALONg STeM; deCReASINg IN LeNgTH TOWARd APeX Of CORALLUM ANd INCLINed dISTALLY. PINNULeS 8 MM TO 10 MM APART PROXIMALLY, 5 MM TO 6 MM APART NeAR THe TOP Of CORALLUM (APPROXIMATeLY SeVeN PINNULeS TOTAL PeR 3 CM ON LOWeR PART Of CORALLUM ANd AbOUT TeN PeR 3 CM ON UPPeR PART IN HOLOTYPe). POLYPAR SPINeS SMALL, TRIANgULAR, ANd COMPReSSed; MOSTLY 0.03 MM TO 0.05 MM TALL (UP TO 0.08 MM NeAR dISTAL eNd Of PINNULeS); fOUR TO fIVe ROWS VISIbLe IN LATeRAL VIeW; WITH AbOUT SIX SPINeS PeR 1 MM. AbPOLYPAR SPINeS USUALLY SMALLeR THAN POLYPAR SPINeS, AbOUT 0.03 MM OR AbSeNT. POLYPS 3 MM TO 4.5 MM IN TRANSVeRSe dIAMeTeR, WITH AbOUT THRee POLYPS PeR 1 CM. Description of the CIDARIS Specimens: THe CIDARIS SPeCIMeNS Of S. affinis ARe SIMILAR TO THe TYPe IN bOTH THe deNSITY Of THe PINNULeS (INCReASINg fROM AbOUT 4.5 PINNULeS IN TOTAL PeR 3 CM ANd ~7 MM Of dISTANCe beTWeeN PINNULeS PROXIMALLY TO 8 PeR 3 CM ANd ~5 MM Of dISTANCe beTWeeN PINNULeS TOWARdS THe APeX Of THe CORALLUM) (FIgURe 6A), ANd THe SIze Of THe POLYPAR SPINeS (~0.06 MM) beINg LARgeR THAN AbPOLYPAR SPINeS (~0.04 MM) (FIgURe 6b). THe COLONY ALSO ReSeMbLeS THe TYPe SPeCIMeN bY HAVINg A dISTINCT TRIANgULAR SHAPe ANd RATIOS Of THe LONgeST ANd LOWeRMOST PINNULe COMPARed TO THe PINNULATed PORTION Of THe STeM beINg beTWeeN 1 TO 1.3, SIMILAR TO THe TYPe SPeCIMeN WITH A RATIO Of ~0.95. (FIgURe 6A). FOUR ROWS Of SPINeS CAN be SeeN fROM ONe ASPeCT (FIgURe 6b) ANd SPINeS ARe MOSTLY SIMPLe (FIgURe 6C), WITH TWO SPeCIMeNS SHOWINg bIfURCATION Of SOMe POLYPAR SPINeS (FIgURe 6b). Distribution: THIS SPeCIeS HAS beeN RePORTed fROM THe NORTHWeSTeRN ATLANTIC, WeSTeRN PACIfIC, ANd INdIAN OCeANS, ANd SOUTH CHINA SeA, fROM dePTHS Of 1,900 M TO 8,460 M, ANd THIS STUdY eXPANdS THe dISTRIbUTION TO THe CORAL SeA, AUSTRALIA (FIgURe 1C) AT 1,576 M (FIgURe 1C), A RANge eXPANSION Of> 1,000 kM, ANd dePTH RANge eXPANSION Of 333 M. a Type specimen a Type specimen, Published as part of Horowitz, Jeremy, Opresko, Dennis M. & Bridge, Tom C. L., 2018, Black corals (Anthozoa: Antipatharia) from the deep (916 m - 2542 m) Coral Sea, north-eastern Australia, pp. 307-326 in Zootaxa 4472 (2) on pages 318-320, DOI: 10.11646/zootaxa.4472.2.5, http://zenodo.org/record/1440225, {"references":["Brook, G. (1889) Report on the Antipatharia. Rep. Sci. Res. Uoy. H. M. S. Challenger. Zoology, 32 (80), 1 - 222.","Molodtsova, T. N. & Opresko, D. M. (2017) Black corals (Anthozoa: Antipatharia) of the Clarion-Clipperton Fracture Zone. Marine Biodiversity, 47 (2), 349 - 365. https: // doi. org / 10.1007 / s 12526 - 017 - 0659 - 6"]}

Published
2018
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46. Abyssopathes lyriformis , Opresko 2002

Author

Horowitz, Jeremy, Opresko, Dennis M., and Bridge, Tom C. L.

Subjects
Cnidaria, Schizopathidae, Abyssopathes, Animalia, Biodiversity, Anthozoa, Antipatharia, Abyssopathes lyriformis, Taxonomy
Abstract

Abyssopathes lyriformis, Opresko (2002) (FIgS. 1 ANd 2) Abyssopathes lyriformis, Opresko (2002): 421; Molodtsova & Opresko (2017): 355. Material examined: MTQ MATeRIAL (PReSeRVed IN eTHYL ALCOHOL): G62078 (STATION dATA IN TAbLe 1). Diagnosis (AfTeR OPReSkO 2002): CORALLUM MONOPOdIAL ANd PINNULATe. PINNULeS ARRANged IN TWO LATeRAL OR ANTeROLATeRAL ROWS ANd ONe MULTIPLe ANTeRIOR ROW CONTAININg TWO TO THRee TIMeS THe NUMbeR Of PINNULeS IN eITHeR LATeRAL ROW. LATeRAL PINNULeS SIMPLe; ANTeRIOR PINNULeS USUALLY WITH ONe, RAReLY TWO, SeCONdARY PINNULeS. TeRTIARY PINNULeS VeRY RAReLY PReSeNT ON SOMe SeCONdARY ANTeRIOR PINNULeS. BASAL LATeRAL PINNULeS CURVed POSTeRIORLY (AWAY fROM SIde WITH ANTeRIOR PINNULeS), WITH dISTAL eNdS Of THOSe IN ONe ROW dIReCTed TOWARdS THOSe IN OPPOSITe ROW, THUS fORMINg A SOMeWHAT OPeN fUNNeL-LIke STRUCTURe. DISTAL LATeRAL PINNULeS ONLY SLIgHTLY CURVed OR STRAIgHT. PINNULATed SeCTION Of CORALLUM INCLINed TO SUbSTRATe dUe TO ~45° beNd IN STeM NeAR bASe. LATeRAL PINNULeS 4 MM TO 5 MM APART, ReSULTINg IN 14 PINNULeS TOTAL PeR 3 CM. DeNSITY Of ANTeRIOR PINNULeS UP TO 13 PeR 2 CM. SPINeS ON THe LATeRAL PINNULeS CONICAL, COMPReSSed, 0.02 MM TO 0.04 MM LONg; THOSe ON ANTeRIOR PINNULeS ANd SUbPINNULeS UP TO 0.06 MM LONg ANd OfTeN INCLINed dISTALLY. THRee TO fOUR ROWS Of SPINeS SeeN IN LATeRAL VIeW; WITH THRee TO 11 SPINeS PeR 1 MM IN eACH ROW. POLYPS UNkNOWN. Description of the CIDARIS Specimen: THe CIDARIS SPeCIMeN IS LIke THe TYPe IN bOTH THe ~45° ANgLe MAde beTWeeN THe PINNULATed SeCTION Of CORALLUM ANd THe SUbSTRATe (FIgURe 2A) ANd IN THe ARRANgeMeNT Of ANd dISTANCe beTWeeN PRIMARY PINNULeS. FOR eXAMPLe, THe LOWeST SeT Of LATeRAL PINNULeS ARe NeARLY OPPOSITe WITH THe ReST ALTeRNATINg UP THe STeM WITH dISTANCeS Of ~4 MM beTWeeN eACH ON ONe SIde Of THe STeM, ReSULTINg IN TWO TO THRee PINNULeS PeR 1 CM (FIgURe 2b). LATeRAL PINNULe deNSITY IS LIke THe TYPe IN THAT 14 PINNULeS CAN be COUNTed PeR 3 CM PROXIMALLY TO 12 PeR 3 CM APICALLY (COUNTINg PINNULeS ON bOTH SIdeS Of THe STeM) (FIgURe 2b). THRee ROWS Of SPINeS ON LATeRAL PINNULeS CAN be SeeN fROM ONe ASPeCT (FIgURe 2C) WITH AbOUT THRee TO fOUR SPINeS PeR 1 MM IN eACH ROW. SPINeS ARe TRIANgULAR OR ROUNded, COMPReSSed, ANd 0.01 MM TO 0.03 MM TALL (FIgURe 2C). ANTeRIOR PINNULeS ARe PReSeNT IN ASSOCIATION WITH MORe THAN HALf Of THe LATeRAL PINNULeS, RANge beTWeeN 0.05 MM ANd 3 MM IN LeNgTH, ANd HAVe eITHeR NONe OR ONe SeCONdARY PINNULe. THe MAXIMUM deNSITY Of THe ANTeRIOR PINNULeS IS 7 PeR 2 CM WHICH IS LeSS THAN THe 13 PeR 2 CM RePORTed fOR THe TYPe (FIgURe 2A). SPINeS ON ANTeRIOR PINNULeS ARe IRRegULARLY ANgLed, WITH MOST SPINeS eLONgATed ANd INCLINed dISTALLY ANd SOMe LeSS INCLINed/ TRIANgULAR, ALL Of WHICH ARe 0.03 MM TO 0.04 MM TALL (FIgURe 2d). Remarks: Abyssopathes lyriformis IS CLOSeLY ReLATed TO A. lyra, HOWeVeR A. lyriformis HAS SeCONdARY PINNULeS WHILe A. lyra dOeS NOT (OR ONLY RAReLY). A. lyriformis ALSO HAS: 1) A HIgHeR deNSITY Of LATeRAL PINNULeS (14 PeR 3 CM VeRSUS 8 PeR 3 CM; 2) A HIgHeR deNSITY Of ANTeRIOR PINNULeS (13 PeR 2 CM VeRSUS A. lyra HAS SUbeqUAL SPINe SIzeS ON LATeRAL ANd ANTeRIOR PINNULeS. LATeRAL PINNULe deNSITY Of THe CIDARIS SPeCIMeN IS LIke A. lyriformis, HOWeVeR THe ANTeRIOR PINNULe deNSITY IS LOWeR THAN THe TYPe (SeVeN PINNULeS PeR 2 CM). A LOWeR deNSITY Of ANTeRIOR PINNULeS WAS ALSO fOUNd IN A SPeCIMeN IdeNTIfIed AS A. lyriformis deSCRIbed IN MOLOdTSOVA & OPReSkO (2017) (eIgHT TO 12 PeR 2 CM). ALSO, LIke THe CIDARIS SPeCIMeN, MOLOdTSOVA & OPReSkO (2017) RePORTed ANTeRIOR PINNULeS WITH SMALLeR SPINeS THAN THe TYPe. THIS eITHeR ReVeALS PLASTICITY AMONg THeSe feATUReS OR POTeNTIALLY TWO dIffeReNT SPeCIeS, WARRANTINg geNeTIC TeSTS fOR CONfIRMATION. Distribution: THIS SPeCIeS HAS beeN RePORTed fROM THe CeNTRAL PACIfIC, SOUTHeRN, WeST INdIAN, ANd WeST ATLANTIC OCeANS fROM dePTHS Of 3,475 M TO 4,892 M, ANd THIS STUdY eXPANdS THe dISTRIbUTION TO THe CORAL SeA, AUSTRALIA AT 2,542 M (FIgURe 1C), A RANge eXPANSION Of> 4,000 kM ANd dePTH RANge eXPANSION Of> 1,000 M., Published as part of Horowitz, Jeremy, Opresko, Dennis M. & Bridge, Tom C. L., 2018, Black corals (Anthozoa: Antipatharia) from the deep (916 m - 2542 m) Coral Sea, north-eastern Australia, pp. 307-326 in Zootaxa 4472 (2) on pages 311-312, DOI: 10.11646/zootaxa.4472.2.5, http://zenodo.org/record/1440225, {"references":["Opresko, D. M. (2002) Revision of the Antipatharia (Cnidaria: Anthozoa). Part II. Schizopathidae. Zoologische Mededelingen, 76 (22), 411 - 442.","Molodtsova, T. N. & Opresko, D. M. (2017) Black corals (Anthozoa: Antipatharia) of the Clarion-Clipperton Fracture Zone. Marine Biodiversity, 47 (2), 349 - 365. https: // doi. org / 10.1007 / s 12526 - 017 - 0659 - 6"]}

Published
2018
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47. Heteropathes americana , Opresko 2003

Author

Horowitz, Jeremy, Opresko, Dennis M., and Bridge, Tom C. L.

Subjects
Cnidaria, Cladopathidae, Heteropathes, Animalia, Biodiversity, Anthozoa, Antipatharia, Taxonomy, Heteropathes americana
Abstract

Heteropathe s cf. americana, Opresko (2003) (FIgS. 1 ANd 7) Heteropathes americana Opresko (2003): 531 ���536 Material examined: MTQ MATeRIAL (PReSeRVed IN eTHYL ALCOHOL): G73229 (STATION dATA IN TAbLe 1). Diagnosis (AfTeR OPReSkO 2003): CORALLUM MONOPOdIAL ANd PINNULATe; PINNULeS ARRANged IN TWO LATeRAL ROWS ANd ONe OR TWO IRRegULAR ANTeRIOR ROWS. LATeRAL PINNULeS SIMPLe, eLONgATe, ARRANged ALTeRNATeLY ANd INCLINed ANd CURVed dISTALLY ANd eXTeNdINg TO THe TOP Of THe CORALLUM; ANTeRIOR PINNULeS SHORT, SUbPINNULATe, ANd eXTeNdINg OUT NeARLY PeRPeNdICULAR TO THe PLANe CONTAININg THe STeM ANd LATeRAL PINNULeS. ANTeRIOR PINNULeS WITH ONe TO THRee SeCONdARY PINNULeS, THe LOWeRMOST TWO USUALLY ARRANged bILATeRALLY. SeCONdARY PINNULeS MAY be SUbPINNULATe, WITH THe TeRTIARY PINNULeS USUALLY ARISINg fROM UPPeR ANd/OR LOWeR SURfACe Of SeCONdARIeS. SPINeS ON LATeRAL PINNULeS SMALL (AbOUT 0.05 MM OR LeSS), TRIANgULAR, ACUTe, COMPReSSed. SPINeS ON ANTeRIOR PINNULeS LARgeR ON ONe SIde Of AXIS (UP TO 0.13 MM) ANd INCLINed dISTALLY. POLYPS 5 MM TO 6 MM IN TRANSVeRSe dIAMeTeR (fROM dISTAL edge Of dISTAL LATeRAL TeNTACLeS TO THe PROXIMAL edge Of THe PROXIMAL LATeRAL TeNTACLeS). Description of MTQ specimen: MONOPOdIAL WITH PINNULeS ARRANged IN TWO LATeRAL ROWS ANd ONe IRRegULAR ROW Of ANTeRIOR PINNULeS. TOTAL STeM LeNgTH IS 4 CM; HOWeVeR, THe STeM TIP IS bROkeN. LATeRAL PINNULeS ARe SIMPLe, eLONgATe, ARRANged ALTeRNATeLY, eXCePT fOR THe fIRST SeT Of LATeRAL PINNULeS, WHICH ARe NeARLY OPPOSITe, WITH 3 MM SPACeS beTWeeN PINNULeS ON ONe SIde Of THe STeM, ANd ARe CURVed dISTALLY (FIgURe 7A). ANTeRIOR PINNULeS RANge beTWeeN 0.8 CM ANd 1 CM LeNgTH, ARe SPACed 0.1 CM TO 0.2 CM APART ANd HAVe ONe TO TWO ORdeRS Of SUbPINNULeS (FIgURe 7b). FOUR TO fIVe ROWS Of SPINeS CAN be SeeN fROM ONe ASPeCT ON LATeRAL PINNULeS (FIgURe 7C) ANd TWO ROWS Of SPINeS CAN be SeeN fROM ONe ASPeCT ON ANTeRIOR PINNULeS (FIgURe 7d). SPINeS ON LATeRAL PINNULeS ARe SMOOTH, SIMPLe, 0.045 MM IN HeIgHT, ANd ARe TRIANgULAR, ACUTe ANd COMPReSSed (FIgURe 7C). SPINeS ON ANTeRIOR PINNULeS ARe LeSS UNIfORMLY SHAPed, RANgINg fROM TRIANgULAR TO eXTReMeLY dISTALLY INCLINed, VARYINg IN HeIgHT fROM 0.04 MM TO 0.08 MM, ANd ARe geNeRALLY LARgeR THAN SPINeS ON LATeRAL PINNULeS, eSPeCIALLY ON THe OUTeR CONVeX SIde (FIgURe 7e). Remarks: FOUR NOMINAL SPeCIeS ARe CURReNTLY ReCOgNIzed IN THe geNUS: H. heterorhodzos (FORSTeR COOPeR, 1909), H. americana OPReSkO, 2003, H. pacifica OPReSkO, 2005, ANd H. opreski de MATOS, 2014. SPeCIeS IN THe geNUS Heteropathes ARe IdeNTIfIed bASed ON THe ReLATIVe SIze Of SPINeS ON ANTeRIOR PINNULeS ANd SUbPINNULeS ANd dIffeReNCeS IN THe SUbPINNULATION Of THe ANTeRIOR PINNULeS. THe CIDARIS SPeCIMeN IS LeAST SIMILAR WITH H. opreski beCAUSe H. opreski HAS SHORTeR PINNULeS COMPARed TO THe STeM, HAS SeCONdARY PINNULeS ON LATeRAL PRIMARY PINNULeS, ANd MUCH HIgHeR ORdeRS Of SUbPINNULATION ON THe ANTeRIOR PRIMARY PINNULeS (���HeAVILY SUbPINNULATed��� COMPARed TO ONe TO TWO ORdeRS Of SUbPINNULATION fOR THe CIDARIS SPeCIMeN). THe CIDARIS SPeCIMeN IS ALSO UNLIke H. heterorhodzos beCAUSe H. heterorhodzos HAS fIVe TO SIX SeCONdARY PINNULeS ARISINg fROM ONe POINT ON ANTeRIOR PRIMARY PINNULeS WITH NO eVIdeNCe Of TeRTIARY PINNULeS. THeRefORe, THe CIDARIS SPeCIMeN IS LIkeLY TO be eITHeR H. americana OR H. pacifica beCAUSe bOTH SPeCIeS HAVe ONe TO TWO ORdeRS Of ANTeRIOR SUbPINNULeS, LIke G73229. THeSe TWO SPeCIeS dIffeR bASed ON THe LeNgTH Of THe dISTAL eNd Of THe STeM AbOVe THe PINNULATed SeCTION WHeRe H. americana HAS A PINNULATed SeCTION Of ~1 CM fOLLOWed dISTALLY bY>7 CM WITHOUT PINNULATION WHILe H. pacifica HAS PINNULeS eXTeNdINg TO NeAR THe dISTAL eNd Of THe STeM. ALTHOUgH G73229 HAS LONg eYeLASH-SHAPed LATeRAL PINNULeS, LIke H. americana, THe STeM TIP Of THe MTQ SPeCIMeN IS bROkeN WHICH MAkeS IT dIffICULT TO IdeNTIfY THe SPeCIeS bASed ON THe LeNgTH Of THe UPPeRMOST UNPINNULATed SeCTION Of THe STeM. THeSe TWO SPeCIeS ALSO dIffeR IN THe ReLATIVe SIze Of SPINeS beTWeeN LATeRAL ANd ANTeRIOR PINNULeS WHeRe, LIke THe CIDARIS SPeCIMeN, H. americana COLONIeS HAVe SIgNIfICANTLY LARgeR SPINeS ON OUTeR CONVeX SIdeS Of ANTeRIOR PINNULeS WHILe H. pacifica HAS geNeRALLY eqUAL SPINe HeIgHTS beTWeeN PINNULe TYPeS. ALTHOUgH THIS SPeCIMeN MOST ReSeMbLeS H. americana, THe STeM TIP IS bROkeN, ANd THe COLONY LACkS POLYPS, WHICH ARe feATUReS THAT WOULd ALLOW OUR SPeCIeS IdeNTIfICATION TO be MORe defINITIVe. ALSO, THe CIDARIS SPeCIMeN HAS fOUR TO fIVe ROWS Of SPINeS VISIbLe IN ONe VIeW Of LATeRAL PINNULeS ANd TWO ROWS Of SPINeS VISIbLe IN ONe VIeW Of ANTeRIOR PINNULeS, WHICH IS MORe IN LINe WITH H. pacifica (THe H. pacifica TYPe HAS fOUR TO fIVe ANd THRee ROWS Of SPINeS IN ONe VIeW Of LATeRAL ANd ANTeRIOR PINNULeS, ReSPeCTIVeLY), bUT NOT TOO dIffeReNT THAN H. americana THAT IT COULdN���T ReVeAL PLASTICITY fOR THe CHARACTeRISTIC (THe H. americana TYPe HAS fIVe TO eIgHT ANd TWO TO THRee ROWS Of SPINeS IN ONe VIeW Of LATeRAL ANd ANTeRIOR PINNULeS, ReSPeCTIVeLY). Distribution: THIS SPeCIeS IS kNOWN TO OCCUR IN THe NORTHWeST ATLANTIC OCeAN ANd CARIbbeAN SeA beTWeeN THe dePTHS Of 895 M TO 2200 M ANd THIS STUdY POTeNTIALLY eXPANdS THe dISTRIbUTION TO THe CORAL SeA, AUSTRALIA (FIgURe 1C), A RANge eXPANSION Of>15,000 kM. THIS STUdY ALSO POTeNTIALLY eXPANdS THe geNUS (Heteropathes) ANd THe fAMILY (CLAdOPATHIdAe) TO THe CORAL SeA, AUSTRALIA, WITH RANge eXPANSIONS Of> 8,000 kM ANd ~2,000 kM, ReSPeCTIVeLY. CONCLUSION OUR ReSULTS deMONSTRATe THAT THe dIVeRSITY Of bLACk CORALS IN THe deeP CORAL SeA IS HIgHeR THAN THe SINgLe ReCORd Of Abyssopathes lyra BROOk (1889) ReCORded PReVIOUSLY. ALL fIVe SPeCIeS IdeNTIfIed IN OUR COLLeCTION RePReSeNT NeW ReCORdS fOR THe RegION. THe LARge RANge eXPANSIONS (> 15,000 kM) HIgHLIgHT THe LACk Of SAMPLINg IN THe deeP-SeA, ANd We COULd ReASONAbLY eXPeCT SPeCIeS RANgeS TO CONTINUe TO eXPANd AS MORe deeP-SeA HAbITATS ARe SURVeYed. OUR ReSULTS SHOW THAT THe SPeCIeS RePORTed HeRe HAVe MUCH LARgeR geOgRAPHIC RANgeS THAN ReCORded PReVIOUSLY, ANd PROVIde fURTHeR eVIdeNCe THAT MANY bLACk CORALS ARe COSMOPOLITAN. HOWeVeR, IT IS IMPORTANT TO ReMeMbeR THAT THeSe SPeCIeS WeRe IdeNTIfIed bASed ON TRAdITIONAL MORPHOLOgICAL TAXONOMY, ANd THAT geNeTIC STUdIeS ARe Needed TO VeRIfY WHeTHeR MORPHOLOgICAL SPeCIeS ARe COMPRISed Of MULTIPLe CRYPTIC SPeCIeS COMPLeXeS THAT ARe dIffICULT TO dIffeReNTIATe MORPHOLOgICALLY. THIS STUdY ALSO deMONSTRATeS THe UTILITY Of MUSeUM COLLeCTIONS fOR dOCUMeNTINg THe OCCURReNCe Of POORLYkNOWN SPeCIeS. THe SPeCIMeNS RePORTed HeRe WeRe HOUSed, ALONg WITH OTHeR MATeRIAL COLLeCTed ON THe CIDARIS eXPedITIONS, IN THe MTQ COLLeCTION fOR ALMOST 30 YeARS. THe CIDARIS eXPedITIONS ReMAIN THe MOST COMPLeTe SAMPLINg Of bIOdIVeRSITY IN THe deeP WeSTeRN CORAL SeA, bUT MUCH Of THe MATeRIAL STILL AWAITS eXAMINATION fROM ReSeARCHeRS WITH SUffICIeNT TAXONOMIC eXPeRTISe. DeSPITe ReCeIVINg LITTLe ATTeNTION fOR 30 YeARS, THeSe SPeCIMeNS HAVe NOW PROVIded NeW INSIgHTS INTO THe dIVeRSITY ANd TAXONOMY Of bLACk CORALS IN THe deeP SeA. THeRefORe, OUR ReSULTS deMONSTRATe THe VALUe Of MUSeUM COLLeCTIONS fOR dOCUMeNTINg bIOdIVeRSITY, PARTICULARLY IN POORLY-kNOWN HAbITATS SUCH AS THe deeP SeA. SUCH kNOWLedge CAN PROVIde IMPORTANT INSIgHTS INTO THe CONSeqUeNCeS Of RAPId eNVIRONMeNTAL CHANge ON SPeCIeS dISTRIbUTIONS, ANd PROVIde VALUAbLe INfORMATION TO INfORM CONSeRVATION ANd MANAgeMeNT., Published as part of Horowitz, Jeremy, Opresko, Dennis M. & Bridge, Tom C. L., 2018, Black corals (Anthozoa: Antipatharia) from the deep (916 m - 2542 m) Coral Sea, north-eastern Australia, pp. 307-326 in Zootaxa 4472 (2) on pages 322-324, DOI: 10.11646/zootaxa.4472.2.5, http://zenodo.org/record/1440225, {"references":["Opresko, D. M. (2003) Revision of the Antipatharia (Cnidaria: Anthozoa). Part III. Cladopathidae. Zoologische Mededelingen, 77 (31), 495 - 536.","Cooper, C. F. (1909) Antipatharia. Reports of the Percy Sladen Trust Expedition to the Indian Ocean. Transactions of the Linnean Society of London, 2 (12), 301 - 323. https: // doi. org / 10.1111 / j. 1096 - 3642.1909. tb 00144. x","Opresko, D. M. (2005) New genera and species of antipatharian corals (Cnidaria: Anthozoa) from the North Pacific. Zoologische Mededelingen, 79 (22), 129 - 165.","De Matos, V., Braga-Henriques, A., Santos, R. S. & Ribeiro, P. A. (2014) New species of Heteropathes (Anthozoa: Antipatharia) expands genus distribution to the NE Atlantic. Zootaxa, 3827 (2), 293 - 300. https: // doi. org / 10.11646 / zootaxa. 3827.2.10","Brook, G. (1889) Report on the Antipatharia. Rep. Sci. Res. Uoy. H. M. S. Challenger. Zoology, 32 (80), 1 - 222."]}

Published
2018
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48. Bathypathes patula Brook 1889

Author

Horowitz, Jeremy, Opresko, Dennis M., and Bridge, Tom C. L.

Subjects
Cnidaria, Schizopathidae, Animalia, Biodiversity, Bathypathes, Anthozoa, Antipatharia, Taxonomy, Bathypathes patula
Abstract

Bathypathes patula Brook, 1889 (FIgS. 1, 3–4) Bathypathes patula, Molodtsova (2006): 141 –142 (complete synonymy). Bathypathes seculata Opresko (2005): 130 –133. Material examined: MTQ MATeRIAL (PReSeRVed IN eTHYL ALCOHOL): G35428, G35430, G61917, G73228, G61948, G61966, G61967, G61977, G61978, G61979, G61980, G61981, ANd G62049 (STATION dATA IN TAbLe 1). Diagnosis (after Molodtsova 2006 -emended): COLONY MONOPOdIAL, PINNULATe; SICkLe-SHAPed STeMS. PINNULeS SIMPLe; ARRANged ALONg THe STeM IN TWO LATeRAL OR ANTeROLATeRAL ROWS, RANgINg fROM 7 MM TO 9 MM APART IN eACH ROW. PINNULeS INCReASe IN LeNgTH fROM THe LOWeST PAIR Of PINNULeS, ReACH MAXIMUM LeNgTH AT AbOUT THe MId-PAIR TO jUST AbOVe THe MId-PAIR, ANd THeN deCReASe IN LeNgTH TOWARdS THe APeX. SPINeS SIMPLe, SMOOTH WITH bLUNT TIPS, TRIANgULAR OR SLIgHTLY COMPReSSed OR eLONgATed, 0.03 MM TO 0.075 MM TALL, eITHeR AT 90° TO THe SURfACe Of THe PINNULe OR SLIgHTLY SLANTed dISTALLY, WITH bIfURCATION Of A feW SPINeS; THRee TO fIVe ROWS VISIbLe IN LATeRAL VIeW WITH AbOUT THRee SPINeS PeR 1 MM. POLYPS UP TO 9 MM IN TRANSVeRSe dIAMeTeR, ARRANged IN A SINgLe ROW. IN AddITION TO THe AbOVe dIAgNOSIS, We Add THe fOLLOWINg: RATIO Of THe LeNgTH Of THe LONgeST PINNULe TO LeNgTH Of THe PINNULATed PORTION Of THe STeM LARgeST AMONg YOUNg COLONIeS (1.5 TO 2 fOR COLONIeS WITH PINNULATed PORTION Of STeM LeNgTHS LeSS THAN 10 CM) ANd deCReASINg WITH Age (Description of the CIDARIS Specimens: TWO COLONIeS ReSeMbLe B. patula ANd 11 COLONIeS ReSeMbLe B. seculata bASed ON THe deSCRIPTION Of THe HOLOTYPeS. THeSe SPeCIMeNS HAVe CURVed TO SICkLe-SHAPed STeMS WHeN VIeWed fROM THe SIde (FIgUReS 3A–b) THAT RANge fROM 3.3 CM TO 24 CM IN TOTAL LeNgTH. THe LeNgTH Of THe LONgeST PINNULe RANgeS fROM 1.6 CM TO 10.5 CM ANd THIS PINNULe IS POSITIONed AT, OR jUST AbOVe, THe MId PAIR Of PINNULeS (FIgUReS 3A–b). THe LeNgTH Of THe UNPINNULATed STeM RANgeS fROM 2.2 CM TO 7.9 CM ANd THe LeNgTH Of THe PINNULATed STeM RANgeS fROM 1.1 CM TO 16.1 CM. THe RATIO Of THe LeNgTH Of THe LONgeST PINNULe TO THe TOTAL COLONY SIze RANgeS beTWeeN 0.32 ANd 1.15. TWO COLONIeS HAVe RATIOS CLOSe TO, OR LeSS THAN, 0.5 ANd 11 COLONIeS HAVe RATIOS CLOSe TO, OR gReATeR THAN, 0.9, IdeNTIfYINg THeM AS eITHeR B. patula OR B. seculata, ReSPeCTIVeLY. THe RATIO Of THe LeNgTH Of THe LONgeST PINNULe TO THe LeNgTH Of THe PINNULATed PORTION Of THe STeM RANgeS beTWeeN 0.48 ANd 1.94. THe PINNULe deNSITY ON eACH SIde Of THe STeM RANgeS beTWeeN THRee ANd fIVe PINNULeS PeR 3 CM; HOWeVeR, THIS RANge MIgHT be AS MUCH AS SIX PINNULeS PeR 3 CM AS ONe SPeCIMeN HAS A PINNULATed PORTION 2 CM IN LeNgTH WITH fOUR PINNULeS ON eACH SIde Of THe STeM. STeM THICkNeSS jUST AbOVe THe bASAL PLATe RANgeS beTWeeN 0.1 MM ANd 0.9 MM. THe STRIATUM ON THe STeM VARIeS IN POSITION ANd LeNgTH, STARTINg ANYWHeRe beTWeeN THe LOWeST POINT Of THe STeM TO MIdWAY UP THe UNPINNULATed PORTION Of THe STeM, ANd eNdINg ANYWHeRe fROM MIdWAY UP THe UNPINNULATed PORTION Of THe STeM TO THe APeX Of THe COLONY. THe NUMbeR Of RIdgeS ON THe STRIATUM RANgeS beTWeeN TWO ANd SIX fROM ONe VIeW, ANd THe dISTINCTIVeNeSS Of THe STRIATUM RANgeS fROM NOT dISTINCT TO VeRY dISTINCT. THRee TO SeVeN ROWS Of SPINeS CAN be COUNTed IN ONe VIeW ON THe PINNULeS, ANd THe SPINeS ARe ARRANged IRRegULARLY IN eITHeR SPIRALS OR IN AXIAL ROWS (FIgUReS 3C–d). THe dIffeReNCe beTWeeN POLYPAR ANd AbPOLYPAR SPINeS ARe VISIbLe IN SOMe SPeCIMeNS, WHeRe POLYPAR SPINeS ARe ~0.07 MM ANd AbPOLYPAR SPINeS ARe ~0.03 MM (FIgURe 3d). SPINeS ARe SMOOTH WITH bLUNT TIPS, eLONgATed, ANd ARe eITHeR AT 90° TO THe SURfACe Of THe PINNULe OR SLIgHTLY SLANTed dISTALLY (FIgURe 3e), WITH ONe SPeCIMeN SHOWINg SOMe bIfURCATION Of THe SPINeS (FIgURe 3f). AMONg THe feW SPeCIMeNS THAT HAVe WeLL PReSeRVed POLYPS, THe TRANSVeRSe dIAMeTeR IS ~6 MM, THe TeNTACLeS ReACH A MAXIMUM LeNgTH Of 3 MM, ANd THe INTeRPOLYPAR SPACe IS ~2 MM. POLYP deNSITY IS ~1.5 PeR 1 CM (FIgURe 3g). Remarks: THe dISCOVeRY Of 11 SPeCIMeNS IdeNTIfIed AS B. seculata bASed ON SIMILARITIeS WITH THe TYPe SPeCIMeN ALLOWS US TO INVeSTIgATe WHeTHeR THe PRIMARY MORPHOMeTRIC CHARACTeR THAT defINeS THe TAXONOMIC bOUNdARY beTWeeN B. seculata ANd B. patula (RATIO Of PINNULe LeNgTH TO STeM LeNgTH) CAN be eXPLAINed bY COLONY Age, USINg LeNgTH Of THe PINNULATed PORTION Of THe STeM AS A PROXY fOR Age. PRIOR TO THIS PUbLICATION, B. seculata WAS defINed AS HAVINg A LeNgTH Of LONgeST PINNULe TO STeM LeNgTH RATIO Of 0.9, ANd B. patula ~ 0.3 TO 0.5. WHeN COMPARINg THe LeNgTH Of THe LONgeST PINNULe TO THe PINNULATed PORTION Of THe STeM (THIS IS A MOdIfIed RATIO TO ACCOUNT fOR VARIATIONS IN THe LeNgTH Of THe UNPINNULATed PORTION Of THe STeM) AMONg THe 11 B. seculata ANd TWO B. patula SPeCIMeNS IN OUR COLLeCTION, THe B. seculata ANd B. patula HOLOTYPe SPeCIMeNS, ANd 8 B. patula SPeCIMeNS deSCRIbed IN THe LITeRATURe, ReSULTS SHOW A SIgNIfICANT ReLATIONSHIP beTWeeN THIS RATIO ANd COLONY SIze (F 1,21 = 51.87, PB. seculata HAS A TOTAL COLONY SIze Of 9 CM ANd A RATIO Of 1.5, ANd B. patula SPeCIMeNS IN THe LITeRATURe HAVe TOTAL COLONY SIzeS THAT RANge fROM 6 CM TO 25 CM ANd RATIOS RANgINg fROM 1.6 TO 0.48. PRIOR TO THIS STUdY, THe dIffeReNT RATIOS ANd COLONY SIzeS beTWeeN THe B. seculata TYPe SPeCIMeN ANd B. patula SPeCIMeNS SUggeSTed POTeNTIALLY dIffeReNT SPeCIeS. HOWeVeR, WHeN CONSIdeRINg SPeCIMeNS fROM OUR COLLeCTION (TAbLe 2), THeRe IS A STRONg NegATIVe CORReLATION beTWeeN RATIO ANd COLONY SIze (FIgURe 4), WHICH MeANS THAT THe RATIO deCReASeS WITH INCReASINg COLONY SIze ANd B. seculata IS THeRefORe A jUVeNILe B. patula. We PROPOSe THAT THe NegATIVe CORReLATION beTWeeN RATIO ANd COLONY SIze IS dUe TO PINNULeS HAVINg SLOWeR gROWTH RATeS THAN THe STeM, a Type specimen WHICH IS WHY AS COLONY SIze geTS LARgeR, THe RATIO Of THe PINNULe TO COLONY SIze deCReASeS. ALLOMeTRIC gROWTH AMONg CORALS HAS beeN SHOWN TO MAXIMIze THeIR CHANCeS Of SURVIVAL ANd RePROdUCTION (DORNeLAS et al. 2017), ANd HAS PReVIOUSLY beeN dOCUMeNTed IN THe bLACk CORAL Leiopathes (ANTIPATHARIA: LeIOPATHIdAe) (LARTAUd et al. 2016). THe AdVANTAge THAT OUR Bathypathes SPeCIMeNS HAVe bY gROWINg ALLOMeTRICALLY CAN ReLATe TO A LAW Of MOdULAR ORgANISMS, WHeRe PROPORTIONAL gROWTH RATeS deCReASe WITH SIze dUe TO geOMeTRIC, STRUCTURAL, ANd eNeRgeTIC CONSTRAINTS (DORNeLAS et al. 2017). ANOTHeR feATURe THAT WAS THOUgHT TO be dIffeReNT beTWeeN THe TWO SPeCIeS IS THe POSITION Of THe LONgeST PINNULe, WHeRe THe LONgeST PINNULe fOR B. patula IS POSITIONed MId-WAY UP THe PINNULATed PORTION Of THe STeM (BROOk 1889) WHILe THe LONgeST PINNULe fOR B. seculata IS POSITIONed AT THe APeX (OPReSkO 2005). HOWeVeR, THe MAjORITY Of SPeCIMeNS IdeNTIfIed AS B. seculata ANd B. patula HAVe THeIR LONgeST PAIR Of PINNULeS NeAR THe MId-PAIR OR jUST AbOVe THe MId-PAIR Of PINNULeS. OTHeR MORPHOLOgICAL feATUReS SIMILAR AMONg THeSe SPeCIMeNS INCLUde: PINNULe deNSITY (THRee TO fIVe PeR 3 CM ON ONe SIde Of THe STeM), SPINe deNSITY (~3 SPINeS PeR 1 MM), SPINe HeIgHT (0.03 MM TO 0.075 MM), SPINe SHAPe (bLUNT TIP, eLONgATed, ANd TRIANgULAR OR SLANTed), ANd SPINe ARRANgeMeNT (THRee TO fIVe AXIAL ROWS PeR VIeW, SOMeTIMeS IRRegULAR OR SPIRAL) (TAbLe 2). ONe dIffeReNCe beTWeeN THeSe 13 SPeCIMeNS THAT CAN NOT be eXPLAINed bY COLONY SIze IS THe POSITION, dISTINCTIVeNeSS, ANd LeNgTH Of THe STRIATUM. FOR eXAMPLe, THe SMALLeST SPeCIMeN (G35430) HAS AN INdISTINCT STRIATUM THAT COVeRS THe WHOLe STeM, THe SeCONd SMALLeST SPeCIMeN (G61917) HAS VeRY dISTINCT STRIATUM THAT IS AbOUT 1.6 CM IN LeNgTH ANd STARTS AT THe bASe ANd eNdS MIdWAY-UP THe UNPINNULATed PORTION Of THe STeM, ANd A MId-SIzed SPeCIMeN (G61948) HAS VeRY dISTINCT STRIATUM 6 CM IN LeNgTH THAT STARTS AbOUT 0.5 CM fROM THe bASe ANd eXTeNdS TO THe fIRST SeT Of PINNULeS (TAbLe 2). ANOTHeR UNeXPLAINAbLe dIffeReNCe AMONg THeSe SPeCIMeNS IS THe LeNgTH Of THe UNPINNULATed PORTION Of THe STeM. ALTHOUgH THeRe SeeMS TO be A geNeRAL deCReASe IN THe RATIO beTWeeN THe LeNgTH Of THe UNPINNULATed PORTION Of THe STeM ANd TOTAL STeM LeNgTH, WHeRe THe SMALLeST SIzed SPeCIMeN HAS A RATIO Of ~0.66, ANd THe LARgeST SIzed SPeCIMeN (G61980) HAS A RATIO Of ~0.33, THe CHANge IN RATIO WITH COLONY SIze dOeS NOT SeeM TO be CONSISTeNT AMONg ALL THe SPeCIMeNS. FOR eXAMPLe, SPeCIMeNS G61917, G62049, G61979, G61978, ANd G61948 HAVe TOTAL STeM LeNgTHS Of 5.8 CM, 7.5 CM, 7.75 CM, 8.6 CM, ANd 11 CM, ReSPeCTIVeLY, WITH RATIOS RANgINg fROM 0.46 TO 0.41; HOWeVeR, ONe SPeCIMeN fROM Siboga STATION 74A (VAN PeSCH 1914) ANd G61966 HAVe TOTAL STeM LeNgTHS Of 6 CM ANd 7 CM ANd RATIOS Of 0.58 ANd 0.35, ReSPeCTIVeLY. GIVeN THAT STRIATUM CHARACTeRISTICS ANd LeNgTH Of THe UNPINNULATed PORTION Of THe STeM SeeM TO be HIgHLY VARIAbLe CHARACTeRISTICS, ANd NO OTHeR dISTINCT dIffeReNCeS CAN be fOUNd beTWeeN OUR B. seculata ANd B. patula SPeCIMeNS, THe HOLOTYPe SPeCIMeNS, ANd B. patula SPeCIMeNS deSCRIbed IN THe LITeRATURe, We HeRebY SYNONYMIze B. seculata WITH B. patula. Distribution: SPeCIMeNS ASSIgNed TO THIS SPeCIeS HAVe beeN RePORTed fROM THe PACIfIC, ATLANTIC, ANd INdIAN OCeANS fROM dePTHS Of 100 M TO 5,500 M. THIS STUdY eXPANdS THe kNOWN dISTRIbUTION TO THe CORAL SeA, AUSTRALIA (FIgURe 1C). DeSPITe THe MANY ReCORdS Of Bathypathes patula LISTed IN OBIS, MOST ARe bASed ON in-situ ObSeRVATIONS WITHOUT THe SPeCIMeNS HAVINg beeN COLLeCTed. GIVeN THAT IT IS dIffICULT TO IdeNTIfY THIS SPeCIeS bASed ON in situ ObSeRVATION ALONe, We ARe UNAbLe TO CONfIdeNTLY CALCULATe THe dISTANCe Of THe RANge eXPANSION., Published as part of Horowitz, Jeremy, Opresko, Dennis M. & Bridge, Tom C. L., 2018, Black corals (Anthozoa: Antipatharia) from the deep (916 m - 2542 m) Coral Sea, north-eastern Australia, pp. 307-326 in Zootaxa 4472 (2) on pages 312-317, DOI: 10.11646/zootaxa.4472.2.5, http://zenodo.org/record/1440225, {"references":["Brook, G. (1889) Report on the Antipatharia. Rep. Sci. Res. Uoy. H. M. S. Challenger. Zoology, 32 (80), 1 - 222.","Molodtsova, T. N. (2006) Black corals (Antipatharia: Anthozoa: Cnidaria) of the north-eastern Atlantic. In: Mironov, A. N., Gebruk, A. V. & Southward, A. J. (Eds.), Biogeography of the North Atlantic Seamounts. KMK Press, Moscow, pp. 141 - 151.","Opresko, D. M. (2005) New genera and species of antipatharian corals (Cnidaria: Anthozoa) from the North Pacific. Zoologische Mededelingen, 79 (22), 129 - 165.","Pesch, A. J. van. (1914) The Antipatharia of the Siboga Expedition. Siboga-Expeditie Monographe, 17, 1 - 258."]}

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2018
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