Actiniaria Hertwig, 1882

Order Actiniaria Hertwig, 1882 View in CoL

Suborder Enthemonae View in CoL Rodríguez and Daly in Rodríguez et al., 2014 Superfamily Metridioidea Carlgren, 1893 View in CoL Family Andvakiidae Danielssen, 1890 View in CoL Genus Telmatactis Gravier, 1916 View in CoL [Japanese common name: Mamire-isoginchaku-zoku] Telmatactis profundigigantica View in CoL sp. nov. [Japanese name: Ryugu-no-goten] ( Figs 2–5 View Fig View Fig View Fig View Fig )

Material examined. Holotype. NSMT-Co 1820: dissected specimen, tissues embedded in paraffin, histological sections prepared, nematocysts prepared; collected on 5 April 2006, collected at southeast off Ishigaki Island (24°18.41′N, 124°16.49′E; Fig. 1A View Fig ), at 206 m depth, using ROV in survey by Okinawa Churaumi Aquarium by Keiichi Sato , kept alive in aquarium of Okinawa Churaumi Aquarium , and fixed by Takato Izumi on 10 September 2018 GoogleMaps . Paratype. CMNH-ZG10156 : whole specimen (smaller polyp than holotype); collected on 5 April 2006, at 203 m depth, using ROV in the survey of Okinawa Churaumi Aquarium by Keiichi Sato, kept alive in aquarium of Okinawa Churaumi Aquarium , and fixed by Takato Izumi from the aquarium tank on 30 November 2021 .

The other materials (only living aspects in video without specimens). [ Polyp no.1]: living images in a movie; captured on 19 September 2017, at a depth of 205 m, northeast off Ie island (26°44.78′N, 127°45.44′E; Fig. 1B View Fig ), using ROV in the survey of Okinawa Churaumi Aquarium by Takuo Higashiji; [Polyp no.2]: living images in a movie; captured on 7 January 2019, at a depth of 262 m, off Motobu Town (26°38.82′N, 127°47.36′E; Fig. 1C View Fig ), Okinawa Island , using ROV in the survey of Okinawa Churaumi Aquarium by Takuo Higashiji GoogleMaps .

Description (sizes of the holotype specimen). External feature: column barrel-like shape, not differentiated into parts, flexible with high degree of expansibility, height approximately 100–120 mm, diameter ca. 100 mm in the widest part and ca. 80–90 mm in basal disc of the live specimens, and height 90 mm, diameter 95 mm in the widest part and 60 mm in basal disc of preserved specimens. Body pale brownish or reddish orange ( Fig. 2A View Fig ); surface of body with transversal wrinkles but without papillae, apertures or mesenterial insertions. Aboral end basal disc, flattened and slightly wider than the diameter of column, apparently sticky and strongly adheres to substrate thus hard to detach from substrate without damage ( Fig. 2C View Fig ). Oral disc with 96 tentacles in five cycles: 6-6-12-24-48 tentacles ( Fig. 2A, B View Fig ). No morphological differences between the tentacles in each cycle; tentacles in first to forth cycle slightly longer (ca. 40–50 mm in length) than tentacles in fifth cycle (ca. 25–30mm in length) when fully expanded. Tentacles apparently capitate with large robust acrosphere-like knobs on the tips ( Fig. 2A, B View Fig ). Some tentacles particularly double-or triple-headed: two or three acrospheres on the tip of one axis of tentacle ( Fig. 2D View Fig ). Approximately 5–10% of tentacles double- or triple-headed. Except for these tentacles, the other tentacles mostly uniform with one acrosphere on the tip ( Fig. 2A View Fig ). Surface of tentacle axis smooth, with obscure longitudinal wrinkles but without any other remarkable structures. Surface of acrosphere smooth and without any structures. Coloration of tentacles slightly pale orange, some parts translucent, with dark brown or red stripes or patches in living specimens ( Fig. 2A View Fig ). Acrospheres same color or comparatively dark orange in living. Tentacles, especially acrospheres, very sticky due to presence of dense nematocysts (see internal anatomy). Oral disc diameter ca. 70–80mm, uniformly brownish orange, in live specimens. Mouth at the center of oral disc, strongly swollen; conchula absent ( Fig. 2A, B View Fig ).

Internal anatomy: ninety-six mesenteries: 48 pairs in four cycles (6-6-12-24). Six pairs of perfect mesenteries in first cycle, and the other imperfect. 12 mesenteries in the first cycle macrocnemes with parietal muscles, retractor muscles, reproductive tissues, filaments and acontia ( Fig. 3F View Fig ). The other imperfect macrocnemes, without distinct retractors but with some reproductive tissues, filaments and acontia. All mesenteries continuing along the whole-body length ( Fig. 2C View Fig ). All tentacles arise from each endocoel and exocoel. Tentacular longitudinal muscles ectodermal, distinct ( Fig. 3B, D View Fig ); tentacular circular muscles indistinct ( Fig. 3A, E View Fig ). Acrosphere on tentacle tips apparently thickened, with densely arranged several rows of large basitrichs ( Fig. 3A, C View Fig ; Table 1). Retractor muscles restricted, limited at the center of each macrocneme, with approximately 40–55 simple to slightly-branched muscular processes ( Fig. 3F View Fig ); parietal muscles of macrocnemes distinct but comparatively weak, triangular shape, with 7–12 multiply-branched muscular processes on each side ( Fig. 3H View Fig ). Mesoglea in the body wall thicker than the ectoderm and the endoderm of body wall, actinopharynx and mesenteries ( Fig. 3F View Fig ), but thinner than ectoderm of the tentacle ( Fig. 3B–E View Fig ). Actinopharynx smooth, grooved, approximately 2/3 of the column length. Two indistinct siphonoglyph both on the dorsal and ventral side of actinopharynx, always connected to actinopharynx and sustained by the dorsal and ventral pairs of directive mesenteries. Sphincter muscle mesogleal, strongly developed. Filaments limited near the aboral end. Dioecious; mature reproductive tissue contains several oocytes in the mesoglea of each mesentery in holotype ( Fig. 3F, G View Fig ).

Cnidom: spirosysts, basitrichs, microbasic p -mastigophores (or microbasic amastigophores). See Fig. 4 View Fig and Table 1 for size and distribution.

Ecological remarks. Living images of this species were captured several times by ROV during surveys of Okinawa Churaumi Aquarium. Telmatactis profundigigantica sp. nov. inhabits on the rocks spattered on sandy bottoms and sometimes buried in demosponges ( Fig. 5A View Fig ). This species could be the strong predator in the deep sea: we observed T. profundigigantica sp. nov. directly preyed on a Pomacentridae fish in the aquarium. It is observed that many shrimps of Plesionika sp. are crowded around this anemone ( Fig. 5B View Fig ): they could live symbiotically to be protected from the enemies by this strong predator.

Not only are the basitrichs of the tentacles of this species comparatively large and robust ( Table 1), but the toxin of this species can also cause serious stings to humans. In one case, a staff member of Okinawa Churaumi Aquarium was stung by the tentacle tip of this species, and the tissue of the lesion became hollowed out with leucocytes being destroyed, and several days of hospitalization were needed. Based on these symptoms, the toxin of this species is likely severe hemolysin enough to harm human health, which is known from some sea anemones ( Gimenez et al. 2014; Jouiaei et al. 2015). Also in Japanese waters, there are a few anemones known to have hemolytic venom: e.g., Phyllodiscus semoni Kwietniewski, 1897 is known to have hemolytic peptide venom in addition to inflaming one ( Nagai et al. 2002) and several cases of sting injury from P. senomi were reported from the south area of Japan ( Uchida and Soyama 2001). In addition, some anemones like Anthopleura Duchassaing de Fonbressin and Michelotti, 1860 and Actinia Linnaeus, 1767 are known to have hemolytic venom in Japan ( Shiomi 1997; Kohno et al. 2009). However, all anemones with hemolytic venom known to date are living in the shallow zone, and thus it is a rare case that a deep-sea anemone has such severe venom enough to harm human health. Overall, there still have been few case studies of the venoms and stings of anemones in Japan (e.g., Nagai et al. 2002; Kohno et al. 2009) although some information on stings is also found in field guides (e.g., Uchida and Soyama 2001). Thus, we believe the severe hemolytic symptoms observed here and this species will be important in future further analyses of the toxicity of anemones in Japan.

Etymology. This new species is characterized by its comparatively far larger size and its deep-sea habitat. Thus, the species epithet is an adjective, composed of “profund-” (Latin profundus = deep) + “gigantica” [latinized Ancient Greek giganticus (gigantikos) = huge].

Derivation of Japanese name. Ryugu (= castle under the deep sea) + no (= of) + goten (= palace). Associated the reddish color to the palaces of Okinawa covered with red roof tiles.

Distribution. Off Okinawa Island and Ishigaki Island, Nansei Islands.

Taxonomic remarks. The morphological features of this anemone are corresponded to the latest diagnosis of Telmatactis in den Hartog (1995) as below: body wall without any structures; clavate 96 tentacles; mesogleal sphincter; two siphonoglyphs on actinopharynx; and presence of acontia. In this genus, Telmatactis profundigigantica sp. nov. is characterized by three characters: (1) enormously large body sizes ( Fig. 2A–C View Fig ); (2) numerous tentacles ( Fig. 2A View Fig ) with some peculiar multiple-headed ones ( Fig. 2D View Fig ); and (3) large tentacle basitrichs ( Fig. 3C View Fig ). As mentioned below, Telmatactis is distributed across a broad area of the world, and thus in this study we have mainly compared with the species of Telmatactis living in the western Pacific.

(1) Telmatactis profundigigantica sp. nov. is much far larger than the other species from the Pacific. The height of this species is at least 90 mm even when formalin-fixed, and this is approximately two times larger than the maximum size of any other Telmatactis species from the Pacific, with the next largest species, T. allantoides ( Bourne, 1918) or T. ambonensis ( Kwietniewski, 1898) : these species 55 mm in height ( Kwietniewski 1898; Bourne 1918). Of course, living polyps of T. profundigigantica sp. nov. is far larger than formalin-fixed specimen (see description part), thus the size of this species is significant in this genus.

(2) Among the species of Telmatactis in the Pacific, the maximum tentacle number reported until now is 74 for T. stephensoni Carlgren, 1950 , and T. ambonensis with 70 tentacles following ( Kwietniewski 1898; Carlgren 1950). Therefore, the number of tentacles of T. profundigigantica sp. nov. (= 96) is higher. In addition, until now, there have been no records of such double-headed tentacles in this species ( Fig. 2D View Fig ) among this genus. Not only the double-headed tentacles in the type specimens, but there are also observed a few tentacles (one or two in 96 tentacles) with triple-capitated heads in living polyps kept living in Okinawa Churaumi Aquarium. Considering that the number of tentacles is almost fixed, it is not possible that the strange tentacle is the half-way condition during the fission of the tentacle. Thus, these multiple-headed tentacles should be also a characteristic feature of T. profundigigantica sp. nov.

(3) The basitrichs on the acrosphere of this species are significantly large on this genus: the largest record as far as known of the size of basitrichs on tentacle tip was 77.4 µm, observed in T. cricoides (Duchassaing, 1850) [ den Hartog (1995); though the name of the cnidae is described as spirulae, the picture of cnidae (fig. 7) is same as basitrichs in the nomenclature we use]. Even the mean of large basitrichs in acrospheres (86.1 µm; Table 1) is larger than the largest record, it can be therefore said that the significant size of cnidae is also the diagnostic character of T. profundigigantica sp. nov. It is known that capitated tentacle tips of sea anemones including acrospheres often contain extremely large sizes of nematocysts in several groups. For example, Haloclava hercules Izumi, 2021 , a species of Haloclavidae , has very gigantic nematocysts almost reaching 300 µm in its clavate tentacle tips ( Izumi 2021). Among actiniarians, therefore, it can be said that basitrichs in the actinopharynx of T. profundigigantica sp. nov. are not so extraordinarily large even though the sizes are apparently large among members of the genus Telematics.

In addition, almost all records of Telmatactis until now are from comparatively shallow waters. For example, all records in den Hartog (1995) are shallower than 10 m, and there are no records deeper than 30 m in the other descriptions [including field guides; Uchida and Soyama (2001)]. Thus, the habitat of T. profundigigantica sp. nov., 203–262 m in depth, is exceptionally the deepest record of this genus.