Pectis antarctica Haeckel, 1879

Horia R. Galea, Cornelia Roder, Christoph Walcher, Marco Warmuth, Eberhard Kohlberg & Philipp F. Fischer, 2016, Glaciambulata neumayeri gen. et sp. nov., a new Antarctic trachymedusa (Cnidaria: Hydrozoa), with a revision of the family Ptychogastriidae, European Journal of Taxonomy 252, pp. 1-30 : 19-24

publication ID	https://doi.org/10.5852/ejt.2016.252
publication LSID	urn:lsid:zoobank.org:pub:F4F9AFF3-C4D3-4BFE-B4C8-516C14758DAE
DOI	https://doi.org/10.5281/zenodo.5628743
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treatment provided by	Plazi (2016-12-25 22:32:34, last updated 2024-11-27 01:40:20)
scientific name	Pectis antarctica Haeckel, 1879
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Treatment

Fig. 5 View Fig. 5 , Table 2 View Table 2

Pectis antarctica Haeckel, 1879: 266 .

Voragonema laciniata Bouillon et al., 2001: 841 View in CoL , Fgs 4–5 (syn. nov.).

Pectis antarctica – Haeckel 1881a: 13, pls 5–6; 1881b: 15, pls 5–6. — Browne 1903: 29. — Maas 1906a: 484. — Kramp 1957: 46. — Beyer 1959: 128.

Ptychogastria antarctica View in CoL – Maas 1906a: 493; 1906b: 19. — Mayer 1910: 375. — Vanhöffen 1912: 386. — Thiel 1932b: 478. — Kramp 1947: 5; 1957: 46; 1961: 241; 1968: 111, 174. — Bouillon & Boero 2000: 68. — Bouillon et al. 2006: 112.

Voragonema laciniata View in CoL – Lindsay & Pagès 2010: 36–37.

Remarks

According to Haeckel (1879, 1881a, 1881b), Pectis antarctica is a hydromedusa exhibiting the following characters: 1) bell nearly hemispherical; 2) exumbrella Fnely ribbed radially; 3) mesoglea moderately thick in the upper half, and comparatively thinner in the lower half; 4) eight radial canals connecting with the ring canal, the latter giving rise to 11–13 centripetal canals in each octant; 5) eight ovoid, convoluted gonads, extending along the proximal half of the radial canals; 6) a quadrangular manubrium provided with 8 pairs of outer, hollow, hemispherical pouches; 7) a strong, muscular velum; 8) a great number of solid marginal tentacles not arising in distinct clusters, but showing a certain regularity in their arrangement around the bell margin; 9) a continuous ring of nematocysts between the velum and the lowest row of tentacles; 10) the occurrence of a number of free, small, club-shaped statocysts with single, spherical statoliths.

In light of these characters, especially the presence of centripetal canals, also found in Ptychogastria polaris Allman, 1878 , Maas (1906a) transferred Haeckel’s species to the genus Ptychogastria Allman, 1878 . He acknowledged only “relative” differences in the arrangement of the marginal tentacles, and noted a remarkable reduction of the “mesenteries” (sic!) compared to both Pt. polaris and Pt. asteroides ( Haeckel, 1879) .

According to Browne (1903), the type specimen of Pe. antarctica “had been thoroughly dissected by Haeckel and just a few pieces placed back into a bottle”, an observation later conFrmed by Kramp (1957), who added that the “tiny fragments […] give no idea of the original appearance of the medusa”.

Earlier, Kramp (1947) acknowledged that “ Ptychogastria antarctica (Haeckel) differs too much from P. polaris to be placed in the same genus, or even in the same family”. Later, he added: “if Haeckel’s account […] is correct, this species is entirely different from P. polaris (including opposita )” ( Kramp 1957). He noted that “the numerous and closely packed tentacles were not arranged in groups as in P. polaris . The ring of tentacles seems to be homogenous, equally thick and dense”.

Although his remark is entirely justiFed, a couple of morphological features resulting from Haeckel’s (1881b) account are noteworthy:

1) unlike Ptychogastria , the gonads of which occur in pairs on either side of the manubrial lobes, those of Pe. antarctica are not only conFned to the radial canals, but they also exhibit a radically different shape, being “wide, folded, thick-walled” and slightly pendant distally ( Haeckel 1881b: pl. 5 Fg. 2);

2) the mesoglea of Pe. antarctica is “very much thickened in the centre of the apex, and projects into the fundus of the gastral cavity in the form of a short, conical, gelatinous appendage”, leaving no doubts that this corresponds in fact to a gastric peduncle, even though the illustrations given by Haeckel (1881b: pl. 5 Fgs 2, 4) are misleading.

It is realized that, taken together, the morphological characters displayed by Pe. antarctica are distinctive features of the genus Voragonema Naumov, 1971 . Among the four species assigned to it (see Lindsay & Pagès 2010), V. laciniata Bouillon et al., 2001 , originating from the Weddell Sea, shows striking resemblances with the present species, and both are thought to be coterminous.

The “eight narrow mesogonia” apparently occurring in Pe. antarctica represent, with little doubt, nothing more than the proximal parts of the gonads. The observation that the tentacles are “rather arranged in eight larger and thirty-two smaller groups” ( Haeckel 1881b) around the umbrella margin, is possibly not totally unfounded. Indeed, Lindsay & Pagès (2010) noted a “regular pattern” in the arrangement of tentacles in P. tatsunoko , and it is quite possible that a similar situation may occur in Haeckel’ species as well.

Last but not least, Haeckel’s statement that “All the tentacles of this genus are solid; their endodermal axis consists of large, clear chordal cells which are sometimes placed in a discoid row one behind the other” is more problematic in its interpretation. Indeed, we cannot be sure whether or not Haeckel made sections through both the large, outermost and the shorter, innermost tentacles, given that only the latter are reportedly hollow in Pectis ( Lindsay & Pagès 2010, as Voragonema ). It has been proved, indeed, that Haeckel’s observations on the hollow nature of the tentacles of Pt. asteroides were totally unfounded ( Picard 1955), even though he provided an illustration ( Haeckel 1881b: pl. 7 Fg. 4), of apparently irrefutable evidence, to support his statement. It is also interesting to note that Bouillon et al. (2001) noted only hollow tentacles in P. laciniata , although it was shown that two types, solid and hollow, occur in this species ( Lindsay & Pagès 2010).

Reversal of precedence for the speciFc name could not be applied for the following reasons: the senior synonym, antarctica , has been used several times as a valid name after 1899 (see synonymy), so the conditions relative to Art. 23.9.1.1. are not met; the junior synonym, laciniata , has been used only Fve times in the literature ( Bouillon et al. 2001, 2006; Stepanjants et al. 2006; Lindsay & Pagès 2010; Mahuzier & Sylvestre 2016), instead of at least 25 times, and Art. 23.9.1.2. is not fulFlled.

Consequently, prevailing usage of laciniata could not be maintained, and this name should be assigned to synonymy with antarctica . For a modern description of this species, refer to Bouillon et al. (2001, as V. laciniata ).

Ecology

Almost nothing, except for the depth range of its habitat, is known about the ecology of this species. It was recorded from 1583 m ( Bouillon et al. 2001) and ca 2300 m ( Haeckel 1881b).

Distribution

Recorded so far from two localities, one situated 500–600 km off eastern Antarctica (60°52’ S, 80°20’ E; Haeckel 1881b) and the other in the Weddell Sea (73°27.5’ S, 22°43.1’ W; Bouillon et al. 2001).

Discussion

A new hydromedusa is described based on specimens from westernAntarctica. Some of its morphological features, viz. the number of radial canals, the number and arrangement of gonads, the lack of a gastric peduncle, the numerous tentacles occurring in superimposed rows, and the presence of free statocysts, place it within the family Ptychogastriidae Mayer, 1910 . Unlike both Ptychogastria Allman, 1878 and Tesserogastria Beyer, 1959 , this medusa has a Fattened, watch glass-shaped umbrella, and is devoid of a velum. These features justify the creation of a new, presently monotypic genus, Glaciambulata , to accommodate these new character combinations.

The revision of the genus Ptychogastria provided herein demonstrates that Pectis antarctica Haeckel, 1879 , a species assigned to it by a number of authors, does not belong here. Indeed, its Fnely ribbed exumbrella, the pigmented subumbrella, the presence of a gastric peduncle and of centripetal canals, the number and arrangement of gonads, the types and arrangement of the marginal tentacles, and the occurrence of free statocysts, are characters of the contemporary rhopalonematid genus Voragonema Naumov, 1971 . Moreover, it is demonstrated that V. laciniata Bouillon et al., 2001 is coterminous with P. antarctica , thus clarifying the morphology and the taxonomic status of this poorly-known species, 137 years after its discovery. The binomen Pectis antarctica is retained in light of the Principle of Priority of ICZN.

References

Allman G. J. 1878. Appendix No. XI. Hydrozoa. In: Feilden H. W. (ed.) Narrative of a voyage to the Polar Sea during 1875 - 6 in H. M. ships Alert and Discovery by Capt. G. S. Nares 2: 290 - 292. Sampson Low, Marston, Searle & Rivington, London. http: // dx. doi. org / 10.5962 / bhl. title. 6828

Beyer F. 1959. A new, bottom-living trachymedusa from the Oslofjord. Description of the species, and a general discussion of the life conditions and fauna of the fjord deeps. Nytt Magasin for Zoologi 6: 121 - 143.

Bouillon J. & Boero F. 2000. Phylogeny and classiFcation of Hydroidomedusae. Synopsis of the families and genera of the Hydroidomedusae of the world, with a list of the worldwide species. Thalassia Salentina 24: 47 - 296.

Bouillon J., Pages F. & Gili J. M. 2001. New species of benthopelagic hydromedusae from the Weddel Sea. Polar Biology 24: 839 - 845. http: // dx. doi. org / 10.1007 / s 003000100289

Bouillon J., Gravili C., Pages F., Gili J. M. & Boero F. 2006. An introduction to Hydrozoa. Memoires du Museum national d'Histoire naturelle 194, Museum national d'Histoire naturelle, Paris. http: // dx. doi. org / 10.1086 / 586983

Browne E. T. 1903. Report on some medusae from Norway and Spitzbergen. Bergens Museum Arbog 1903: 1 - 36.

Haeckel E. 1879. Das System der Medusen. Erster Theil einer Monographie der Medusen. Mit einem Atlas von vierzig Tafeln. Gustav Fisher, Jena. http: // dx. doi. org / 10.5962 / bhl. title. 46856

Haeckel E. 1881 a. Monographie der Medusen. Zweiter Theil. Erste Halfte: Die Tiefsee-Medusen der Challenger-Reise. Zweite Halfte: Der Organismus der Medusen. Gustav Fischer, Jena. http: // dx. doi. org / 10.5962 / bhl. title. 46856

Haeckel E. 1881 b. Report on the deep-sea medusae dredged by H. M. S. Challenger, during the years 1873 - 1876. Report on the ScientiFc Results of the Voyage of H. M. S. Challenger during the years 1873 - 76, Zoology 4 (2): 1 - 154. http: // dx. doi. org / 10.5962 / bhl. title. 6513

Kramp P. L. 1947. Medusae. III. Trachylina and Scyphozoa. Danish Ingolf Expedition 5 D (14): 1 - 66.

Kramp P. L. 1957. Hydromedusae from the Discovery collections. Discovery Reports 29: 1 - 128. http: // dx. doi. org / 10.5962 / bhl. part. 12484

Lindsay D. & Pages F. 2010. Voragonema tatsunoko (Trachymedusae: Rhopalonematidae), a new species of benthopelagic medusa, host to the hyperiid amphipod Mimonectes spandli (Physosomata: Mimonectidae). Zootaxa 2671: 31 - 39.

Maas O. 1906 a. Die arktischen Medusen (ausschlieβlich der Polypenmedusen). Fauna Arctica 4 (3): 479 - 526.

Mahuzier S. & Sylvestre J. P. 2016. Cap sur le grand continent blanc. Quae, Versailles.

Mayer A. G. 1910. Medusae of the world. Vol. II. The hydromedusae. Carnegie Institution of Washington Publication 109: 231 - 498. http: // dx. doi. org / 10.5962 / bhl. title. 5996

Naumov D. V. 1971. Gydroidnye i stsifoidnye medusy iz Kurilo-Kamchatskogo zhelova (Hydromedusae and Scyphomedusae from the Kurile-Kamchatka Trench). Trudy Instituta Okeanologii 92: 9 - 17.

Picard J. 1955. Nouvelles recherches sur les hydromeduses des herbiers mediterraneens de posidonies. Recueil des Travaux de la Station Marine d'Endoume 15: 59 - 71.

Stepanjants S., Coretese G., Kruglikova SB. & Bjorklund K. R. 2006. A review of bipolarity concepts: history and examples from Radiolaria and Medusozoa (Cnidaria). Marine Biology Research 2 (3): 200 - 241. http: // dx. doi. org / 10.1080 / 17451000600781767

Thiel M. E. 1932 b. Die Hydromedusen-Fauna des Nordlichen Eismeeres in tiergeographischer Betrachtung. Archiv fur Naturgeschichte, n. ser. 1 (3): 435 - 514.

Vanhoffen E. 1912. Die craspedoten Medusen der deutschen Sudpolar-Expedition. Deutsche Sudpolar- Expedition 1901 - 1903, Zoologie 5 (3): 351 - 396.

Figures

Fig. 5. — Pectis antarctica Haeckel, 1879. A – B. Medusa in lateral (A) and oral (B) views. C. Longitudinal section through the manubrium. D. Lateral view of the manubrium showing the outer, gastric pouches. E. Lateral view of Voragonema laciniata Bouillon et al., 2001. F – G. Manubrium of V. laciniata in oral (F) and lateral (G) views. [A – D redrawn after Haeckel (1881 b); E – G redrawn after Bouillon et al. (2001)]. Scale bars: A, B, E = 1 cm; F, G = 5 mm.

Tables

Table 2 (continued on next page). Morphological comparison between the nominal species Pectis antarctica Haeckel, 1879 and Voragonema laciniata Bouillon et al., 2001.

	P. antarctica Haeckel, 1879	V. laciniata Bouillon et al., 2001
References	Haeckel (1881b)	Bouillon et al. (2001), Lindsay & Pagès (2010)
Distribution	60°52′ S, 80°20′ E (500–600 km off eastern Antarctica )	Weddell Sea, Antarctica
Umbrella	Dome-shaped to “almost hemispherical; about 1½ times as broad as high”, ca. 24 mm high and 36 mm wide “Exumbrella Fnely radially ribbed” “The gelatinous substance of the umbrella […] is nearly of equal thickness in the upper aboral half of the umbrella”; “much thinner in the lower oral half, hardly one-fourth or one- Ffth as thick as in the upper half” “The ectodermal epithelium of […] the subumbrella consists of cells of dark brown pigment” “The underlying annular system of the subumbrella forms numerous compact circular folds”	Dome-shaped to hemispherical, almost as high (30 mm) as wide (35 mm) Exumbrella transparent, with numerous Fne, meridional ridges Mesoglea 4 mm thick in the apex, thinning out towards umbrella margin Subumbrella dark red-brownish colored Musculature of subumbrella consisting of both circular and crossed oblique-radial muscles
Gastric peduncle	The mesoglea “is very much thickened in the centre of the apex, and projects into the fundus of the gastral cavity in the form of a short, conical, gelatinous appendage”	Large, circular from above and slightly octagonal from the subumbrellar cavity
Canal system	“The eight radial canals […] which run from the basis of the stomach to the umbrella margin, and there open into the circular canal, as well as the circular canal itself […], and the blind centripetal canals proceeding from it, are not cylindrical tubes, but Fattened band- like vessels which are sharply distinguished by then milk-white colour from the dark violet subumbrella”; “11-13 blind radial canals (3 larger and 8-10 smaller) between each two radial canals […] have the form of a pointed equilateral triangle”; “number and	8, white-cream colored, straight; peduncular part 5 mm long and 1.5 mm wide; proximal half of the subumbrellar part narrow, 0.5 mm wide, distal half broader, 1.3 mm wide. Ring canal wide, giving rise to 11–13 conically-shaped, irregular in length and width, centripetal canals in each octant
	arrangement […] not perfectly regular”
Manubrium	“The central oesophagus hangs down from the fundus of the umbrella cavity till past the middle of it in the shape of a quadrangular tube […]” “Oral cavity with with 8 pairs of hemispherical side pouches”. “These form hemispherical, or, more properly, semioval evaginations of the gastral wall, and hang together in pairs in such a way that eight pairs appear as oral bifurcated terminal shoots of the eight gastral grooves”	Short, broad, square, slightly longer than the peduncle, with thick muscular walls. Gastric peduncle and manubrium taken together about half the height of the sumbumbrella cavity. Manubrial cavity divided into eight longitudinally folded gastric pouches that open into the radial canals. The presence of septal pouches presumably increases the absorption surface of the endoderm.