Spinularia flagellata, Ekins & Erpenbeck & Wörheide & Hooper, 2023

Spinularia flagellata sp. nov. Ekins, Erpenbeck & Hooper urn:lsid:zoobank.org:act:F7D54F8A-68DF-4602-9C3E-AED029E33337

Figures 1 View FIGURE 1 , 2 View FIGURE 2 & 6 View FIGURE 6 , Tables 3 View TABLE 3 & 4 View TABLE 4

Part Radiella irregularis Ridley & Dendy, 1886 View in CoL , sensu O’Hara et al. 2020: 4

? Part Spinularia sarsii ( Ridley & Dendy, 1886) View in CoL : 488-489

? Part Spinularia sarsii ( Ridley & Dendy, 1887) : 218-220

? Radiella sarsii View in CoL : Burton 1959: 208

Type material: Holotype QM G337555 , Coral Sea Commonwealth Marine Reserve , Queensland, Australia, -23.587, 154.194 to -23.617, 154.1947, 1013–1093 m, Beam Trawl, Coll. Merrick Ekins on RV Investigator, Cruise IN2017_ V03 , sample 121-232, 13/VI/2017. GoogleMaps

Paratypes QM G337175 , off Byron Bay , New South Wales, Australia, -28.0544, 154.083 to -28.097, 154.081, 999–1013 m, Beam Trawl, Coll. Merrick Ekins on RV Investigator, Cruise IN2017_ V03 , sample 100-114.1, 9/ VI /2017 GoogleMaps ; QM G339363, same collection details as G337175, sample 100-115 ; QM G337548, same collection details as QM G337555, sample 121-144 .

Other Material: QM G316338 , North Norfolk Ridge, Pacific Ocean Seamounts , -26.43233333, 167.1811667, 750–774 m, Beam Trawl, Coll. NORFANZ expedition on GoogleMaps RV Tangaroa , 43-016, MF140, 18/ V /2003 , 5 specimens; QM G339456 , same collection details as QM G316338 ; QM G339454 , Lord Howe Plateau, Pacific Ocean Seamounts , -32.445, 161.7825, 1130–1147 m, Beam Trawl, Coll. NORFANZ expedition on GoogleMaps RV Tangaroa, TAN 308/77-039, MF328, 25/ V /2003 , 13 specimens.

Etymology: named for the whip-like shape of the principal tylostyles, flagellum L. whip.

Diagnosis: Discoid Spinularia with a small fringe, a single layer of bouquet forming tylostyles in the ectosome and long very thin whip like tylostyles.

Morphology: Flattened discoid, with a hispid concave upper surface, a convex smooth lower surface ( Fig. 6 A–D View FIGURE 6 ) and a marginal spicule fringe ( Fig. 6 L View FIGURE 6 ). The holotype is 15 mm in width, including the 2.3 mm basal fringe, whilst the body height is 7.2 mm. The paratypes are identical in shape and similar in size i.e. 14–15.4 mm in width and 4.3–7.2 mm in height with the fringe of 3 mm. The holotype has a single central papilla (1 mm in height). The sponge is white to cream in colour immediately after collection and in ethanol. The sponge is firm, but flexible on the lower surface due to the protective styles, but soft and compressible on the upper surface.

Skeleton: The choanosomal skeleton consists of randomly orientated disorganised smaller tylostyles ( Fig. 6 D, K View FIGURE 6 ). The principal tylostyles originate below the ectosome, from bouquets in the upper choanosome, forming a palisade in the ectosome ( Fig. 6 D, K View FIGURE 6 ). The lower ectosomal skeleton also contains the long fringe styles on the lower surface, which radiate from the centre of the basal surface forming the fringe ( Fig. 6 D View FIGURE 6 ).

Spicules: The large fringe tylostyles forming the fringe range from 1510–3500 μm in length and 14.7–48.8 μm in width ( Fig. 6 E, F View FIGURE 6 ).The principal tylostyles have a very long drawn out thin sinuous tip resembling a whip, these are 696–2430 × 7.4–26.6 μm ( Fig. 6 G, H View FIGURE 6 ). These whip-like tylostyles are very fragile, and can easily be overlooked as the fine ends are usually broken off during collection. The small tylostyles from the choanosome are prominently fusiform ( Fig. 6 I View FIGURE 6 ). The uncommon raphides are also present lying loosely in the choanosome ( Fig. 6 J View FIGURE 6 ). All spicule measurements are summarised in Table 4 View TABLE 4 .

Distribution: Coral Sea and Tasman Sea seamounts, bathyal depth.

Ecology: Mud substrate.

Molecular data: 28S-C region barcode of holotype QM G337555 (ENA Accession number OY741343). This sample is genetically different from all other samples analysed in this study .

Remarks: This new species is remarkably similar in morphology to Radiella nidula sp. nov., both being very small discs with fringing spicules and often occur together in the same habitats. The new species differs from R. nidula sp. nov., by the shape and size of the principal tylostyles, the wider smaller tylostyles, the whip like styles and the presence of raphides giving generic separation from Radiella . It also differs by having a simpler skeleton, i.e. it only has the single layer of bouquet forming tylostyles in the ectosome and by molecular differences in 28S (see Fig. 3 View FIGURE 3 ).

This new species probably includes one of the specimens of Ridley & Dendy’s (1886), that was collected from Cape York Australia i.e. BMNH 1887.5.2.40. Ridley & Dendy (1887), indicate this Cape York specimen differs from the other specimens by the more convex shape and having shorter choanosomal tylostyles. It is also visibly different by the smaller more compact fringe and the presence of a single papillae from all Northern Hemisphere specimens of S. sarsii as illustrated in Fig. 29 E, F in Plotkin et al. (2018). However, examination of the spicules and skeleton of the paralectotype would be required to complete this determination, as the spicule measurements in Plotkin et al. (2018) have been pooled from 13 specimens and it is unclear if this contains any type material. These specimens were previously listed as Radiella irregularis in O’Hara et al. (2020).

Specimen QM G316338 also contain a small number of subtylostyles. Radiella straticulata has not infrequent subtylostyles as well. One of the five specimens of QM G316338 and QM G339456 also differ from the other specimens listed here by being attached to rock/coral fragments 3–5 mm in size ( Fig. 6 M View FIGURE 6 ) .