Egmundella producta ( G.O. Sars, 1874 )

Egmundella producta ( G.O. Sars, 1874)

Calycella producta G.O. Sars, 1874: 118 , pl. 5 figs 6-8. ‒ Hincks, 1874a: 134. ‒ Verrill, 1879: 17. ‒ Storm, 1879: 26. ‒ Broch, 1907: 7.

Lovenella producta . ‒ Segerstedt, 1889: 12. ‒ Jäderholm, 1909: 79. ‒ Kramp, 1935: 140, fig. 57E. ‒ Fraser, 1937: 96, pl. 19 fig. 102. ‒ Fraser, 1944: 175, pl. 31 fig 149. ‒ Schuchert, 2000: 423. ‒ Schuchert, 2001: 54, fig. 39. ‒ Calder, 2012: 22 View Cited Treatment , fig. 21.

Campanulina producta . ‒ Bonnevie, 1899: 73. ‒ Bonnevie, 1901:10. ‒ Broch, 1903: table. ‒ Stechow, 1922: 146.

not Lovenella producta . ‒ Fraser, 1911: 44, pl. 3 figs 7-10. ‒ Fraser, 1914: 159, pl. 18 fig. 64. [in part Egmundella gracilis Stechow, 1921 View in CoL ]

? Lovenella producta . ‒ Fraser, 1938: 40.

? not Campanulina producta . ‒ Leloup, 1940: 8, pl. 1 fig. 4.

? Egmundella grimaldii Leloup, 1940: 7 View in CoL , pl. 1 fig. 3.

? not Opercularella producta . ‒ Vervoort, 1966: 111, fig. 12a. ‒

Verwoort, 1985: 279.

Material examined:

Syntypes, UZMO B1378 , Sars collection, as Calycella producta ; Norway, Bodø and Lofoten , 80-100 f (= 146-183); identified by G. O. Sars, numerous hydranths, relatively well preserved.

MHNG-INVE-91796; Norway, North of Litlesotra Island, 60.4083°N 05.1167°W, 100 m depth, on tube of Sabella pavonia ; collected 22.04.2015; with 3 gonothecae; part of this material processed to permanent microslide preparations; DNA isolate 1097 made from a few hydranths, 16S sequence KU512889; DNA isolate 1098 made from a gonotheca content, 16S sequence identical to KU512889.

MHNG-INVE-25136; Iceland, 64.842°N 24.217°W, 220 m depth, temperature 7.1°C; collection date 0 5.09.1990. ZMUC BIOFAR 100; Faroe Islands, 61.5878°N 6.2847°W, 283 m depth, temperature 6.8°C; collected 24.07.1987; without gonothecae.

ZMUC BIOFAR 165; Faroe Islands, 62.1844°N 4.9667°W, 184 m depth, temperature 7.9°C, on hydroids; collected 07.05.1988; without gonothecae.

ZMUC BIOFAR 517; Faroe Islands, 60.6039°N 11.6364°W, 1099 m depth, temperature 5.6°C; collected 27.07.1989; without gonothecae.

ZMUC BIOFAR 523; Faroe Islands, 60.7114°N 12.6075°W, 606 m depth, temperature 8.5°C, on polychaete tube made of sand grains; collected 28.07.1989; without gonothecae.

ZMUC BIOFAR 524; Faroe Islands, 0.7364°N 12.6222°W, 702 m depth, temperature 7.9°C, on hydroid Symplectoscyphus tricuspidatus ; collected 28.07.1989; without gonothecae.

Description: Colony stolonal, stolons tubular, diameter 90-140 μm, irregularly corrugated, ramified, creeping, forming a reticulated network. Stolons usually bear on upper surface a row of widely spaced nematothecae, number variable between colonies, nematothecae about 60-100 μm high, on short pedicels, bodies egg-shaped, distally truncate, lumen filled with large haplonemes ( Fig. 1 B). The hydrothecae are not evenly distributed and tend to arise in clusters of 3-6, total height of hydrotheca and pedicel very variable 3-6 mm ( Fig. 1 A), diameters of pedicels 80-90 μm. Pedicels straight, smooth for the most part but regularly some short, annulated stretches present, this especially at base. Hydrotheca elongate, height 0.5-0.8 mm from diaphragm to operculum tip, walls thin, widest at base of operculum (diameter 0.28-0.32 mm), tapering towards below, and basally merging imperceptibly into pedicel, with no node at base of hydrotheca. Operculum low, conical, formed by about 10-12 triangular flaps. In fresh and alcohol preserved material, the operculum is not delimited from the hydrothecal wall by a crease line. A crease line can appear when the operculum is inwardly folded into the hydrotheca ( Fig. 1 A). Towards base of hydrotheca a very fine, membranous, funnelshaped diaphragm, which is only discernible while there is a living polyp in the hydrotheca.

Gonothecae arise directly from stolons ( Fig. 1 C, E), fanshaped, strongly flattened ( Fig. 1 F), the thickness of the gonotheca in the proximal part is about 1/8 to 1/10 of the height, thinning out towards the periphery, with a large opening spanning from one side to the other ( Fig. 1 E-F), margin of opening irregularly serrated, possibly resulting from rupture of perisarc at maturity, lower walls of gonotheca undulated, pedicel short. Size of gonotheca variable, observed range (n=3, newly collected material) was 1.5 x 1.7 mm to 4.4 x 4.6 mm (height x maximal width). Only largest gonotheca contained soft tissue, represented by a very young and an advanced gonophore, gonophore a medusoid or a medusa.

Nematocysts:

- large merotrichous and atrichous haplonemes ( Fig. 3 View Fig. 3 A-B, E-F), concentrated in nematothecae but also present in hydranths, stolons and gonophores, (31-35) x (3.5-4) μm, straight or curved, thread of discharged capsules thin, tapering inconspicuously, some capsules without barbs ( Fig. 3 View Fig. 3 F), some with a stretch of about 30 μm beset with strong barbs, about 40 μm away from capsule ( Fig. 3 View Fig. 3 E).

- spindle shaped isorhizas ( Fig. 3 View Fig. 3 C), concentrated in tentacles, but also elsewhere, (7.5-9) x (1.5-2) μm, in light microscopy lacking visible spines.

- rare, small, unidentifiable capsules ( Fig. 3 View Fig. 3 D), (4-5) x (1-1.5) μm, may be developmental stages.

Biology: Grows on a variety of substrates like other hydroids (especially Tubularia indivisa ), tubes of polychaetes, and ascidians. Depth range of reliablyidentified material 6-750 m, usually below 80 m in boreal regions.

Distribution: In cool temperate to cold waters of the North Atlantic, rarely reported from the high Arctic: Norway ( Sars, 1874; Storm, 1879; Bonnevie, 1899, 1901), Sweden ( Segerstedt, 1889), Denmark ( Kramp, 1935), North Sea ( Broch, 1903), Iceland ( Schuchert, 2000, 2001), North-western Atlantic ( Verrill, 1879; Fraser, 1944).

The identities of records from deep waters of the Gulf of Gascogne and the Azores ( Leloup, 1940; Vervoort, 1985) are uncertain.

Not reported so far from the Russian Arctic Sea ( Antsulevich, 2015) or other high arctic waters ( Ronowicz et al., 2015), except for one record by Broch (1907) from the Jones Sound (south of Ellesmere Island, Canada). Type localities: Norway, Nordland county, Bodø and Lofoten Islands, 146-366 m depth, on Tubularia indivisa and a serpulid tube.

Remarks: The presence or absence of nematothecae in campanulinid hydroids is usually considered to be a genus level difference ( Levinsen, 1893; Jäderholm, 1909; Stechow, 1921; Bouillon et al., 2006). The genus Lovenella Hincks, 1868 has as type species Campanularia clausa Lovén, 1836 by monotypy, a species with no stolonal nematothecae.

Contemporary authors (e. g. Cornelius, 1995a; Schuchert, 2001; Calder, 2012) did nevertheless not apply this and continued to use the combination Lovenella producta ( G.O. Sars, 1874) , despite the fact that nematothecae were always found. The reason for doing so was because the species remained incompletely described and it was assumed that the type material does not have stolonal nematothecae as these were not mentioned by Sars (1874). However, the re-examination of the syntypes showed that stolonal nematothecae are present in both of them. According to Bouillon et al. (2006) ‒ currently the most comprehensive and widely accepted taxonomic system of the Hydrozoa ‒ the species must thus be placed in the genus Egmundella Stechow, 1921 ( Stechow, 1921: 225; type species Egmundella gracilis Stechow, 1921 by original designation).

A comparison with the syntype specimens made it evident that the new material from Norway is indistinguishable from them, the hydrothecae being only slightly shorter. The syntype material, as already stated by Sars (1874), is composed of specimens from at least two localities (Bodø and Lofoten Islands), each attached to a different substrate ( Tubularia indivisa stem fragments and a serpulid tube fragment, respectively). The material is relatively well preserved, though most hydrothecae are damaged. The stolons bear numerous nematothecae, although their local density is variable. Since they were not mentioned by Sars (1874), it is assumed that he must have overlooked them. Considering the quality of the optical instruments available at his time, this is not surprising, as they are inconspicuous structures that need a careful examination to be discovered.

Sars (1874) stated that the type material had no gonothecae. However, I found one small (1 mm), developing gonotheca on the colony growing on the serpulid tube. The gonotheca is comparatively smaller, but otherwise morphologically similar to those observed in the new material ( Fig. 1 C, 2C). The gonotheca in the type material seems to be a younger stage than the one depicted in Fig. 1 C and apparently there is no opening yet. There is a visible gonophore inside it, but no internal structures could be identified.

Unfortunately, the content of the gonotheca in the new material could not be identified with sufficient precision. The material had to be preserved immediately because the tissues started to deteriorate due to damage suffered during the collecting process. Only the largest gonotheca contained soft tissue, represented by one advanced gonophore and a very young one. The gonophore was provisionally identified as a medusoid with developed gonads, but it is not excluded that it could further develop into a medusa with tentacles. New observations based on living colonies are needed.

The shape of the gonothecae observed in the material of the present study matches only partially Storm’s (1879) description. Storm mentions a short aperture, while in the present material there is a wide distal opening. Without any illustration of Storm’s material it is difficult to assess its validity and significance. Also Vervoort (1985, as Verwoort) described gonothecae in material he tentatively identified as L. producta : “... hyaline, sacshaped body, about as long as the hydrothecal pedicel and attached to the stolon by means of a very short collarshaped pedicel. The lateral wall is slightly wrinkled; terminally it is open, with a slightly folded apical portion ...”. Also this description does not match well the gonothecae found here, notably there is no mention of the gonothecae being flattened. Vervoort’s material from deep waters of the Bay of Biscay originated from beyond the southern limit of the distribution of E. producta and it lacked nematothecae. I therefore think that Vervoort’s hydroid was not E. producta , an opinion likely shared by Vervoort himself, because he added a question mark in front of the binomen.

Egmundella grimaldii Leloup, 1940 , from deep waters of the Bay of Biscay, is rather similar to E. producta , but has very short hydranth pedicels. More material from this region is also needed to evaluate if it not just a mere growth variant of E. producta .

The reliability of the records of E. producta from the Pacific is also difficult to evaluate, and this is not only due to the infertile state of the known specimens. Fraser (1911, 1914) described L. producta colonies from British Columbia, but later Stechow (1921) re-examined part of this material and found nematothecae. Stechow attributed these samples with nematothecae to a new species, Egmundella gracilis Stechow, 1921 . The colonies lacking nematothecae were left in L. producta . The NE Pacific E. gracilis differs from the Atlantic E. producta by the presence of nematothecae on the hydranth pedicels, a situation never met with in the latter species. I think that reproductive colonies of E. gracilis and L. producta sensu Fraser must be re-sampled in the Vancouver Island region before a reliable conclusion on their status can be made. In this context, also Oplorhiza diaphragmata Naumov, 1960 needs a re-evaluation. Although O. diaphragmata has been allocated to a different genus, I suspect that it is conspecific with E. gracilis .

There are about 12 species of either Egmundella Stechow, 1921 or Oplorhiza Allman, 1877 ( Bouillon et al., 2006) , two genera which are hardly separable and it is a matter of personal opinion whether they should be kept distinct or not. For more details on how to distinguish these two genera and also other similar ones see Bouillon et al. (2006). For these 12 species of Egmundella or Oplorhiza , gonothecae are only known for Egmundella humilis Fraser, 1936 , E. polynema Fraser, 1948 , E. sibogae Billard, 1940 , and Oplorhiza diaphragmata Naumov, 1960 (see Hirohito, 1995; Fraser, 1948; Billard, 1940; Naumov, 1969, respectively). The Japanese E. humilis produces a free medusa, but the adult is unknown. Egmundella sibogae is supposed to produce either a medusoid or a medusa. The gonothecae of both these species are more or less cylindrical and thus very unlike the ones observed for E. producta . The gonothecae of O. diaphragmata are shaped like high, narrow, inverted cones. These three species have thus gonothecae forms which are quite different from E. producta and they are certainly separate species.

Although I advocate here for a genus change to Egmundella producta , this may nevertheless be only a temporary solution. Molecular phylogenies will almost certainly make it necessary to revise the scope of many genera of the Campanulinidae (comp. Leclère et al., 2009). In this context, not too much energy should therefore be wasted in discussions on the generic limits and subdivisions of the Campanulinidae based on morphological traits with very low complexity and high variability.

Much emphasis has been placed by some authors (e.g. Stechow, 1922; Miranda et al., 2013) on the presence of a crease line delimiting the operculum from the hydrotheca wall. In the present material of E. producta , no such crease line could be found in intact hydrothecae of living material or material kept in liquid fixative (including the type specimens). A crease line becomes visible once the operculum is tucked inside the hydrotheca (due to collecting process?), or it appeared after the material had been dehydrated for permanent microslide preparations [see also Cornelius (1995a: 168) for similar observations]. Thus, the presence of crease lines may, in some cases, be a mere preparation artefact. This should not be taken as a general invalidation of this character, but a cautionary note when using permanent slide preparations only. Some species, e. g. Calycella syringa ( Linnaeus, 1767) or Tetrapoma quadridentatum ( Hincks, 1874b) (see Schuchert, 2001 for descriptions), always have a distinct crease line delimiting the operculum base. In these cases, it is a stable and important taxonomic character that may not be neglected.

More generally, shrinkage artefacts in slide preparations can be quite dramatic as was observed for the gonothecae in the present material. The dimensions of the single gonotheca processed into a permanent slide preparation shrunk about 10-19%. Shrinkage was unequal for different regions and appeared most pronounced where the perisarc is very thin, but limited in the basal regions with comparatively thicker perisarc ( Fig. 1 D). Shrinkage takes certainly always place to some degree in all permanent microslide preparations and this compromises, to some extent, the precision and comparability of measurements.