Hymedesmia (Hymedesmia) spinata, Calcinai, Barbara, Bavestrello, Giorgio, Bertolino, Marco, Pica, Daniela, Wagner, Daniel & Cerrano, Carlo, 2013

Hymedesmia (Hymedesmia) spinata View in CoL n. sp.

( Figs. 12 View FIGURE 12 A–J; 13) ( Tabs. 5 View TABLE 5 ; 6)

Holotype material. MSNG 56262: sample Bugor 513: Indonesia, North Sulawesi, Siladen Island, Siladen Barat, 23 m, 11 September 2007.

Paratype material. MSNG 56263: sample Bugor 311: Indonesia, North Sulawesi, Siladen Island, Siladen Barat, 25 m, 18 January 2007.

Other examined material: sample Bugor 309: Indonesia, North Sulawesi, Siladen Island, Siladen Barat, depth not stated, 18 January 2007; sample Indo 23: Indonesia, North Sulawesi, Siladen Island, Siladen Barat, depth not stated, 8 October 2008; sample Bugor 410 (bis2): Indonesia, North Sulawesi, Siladen Island, 26 m, September 2007.

Comparative material ( Fig. 14 A View FIGURE 14. A – D –I): Hymedesmia (Hymedesmia) prostrata Thiele, 1903 holotype material ZMB Por 3160 (only two spicule slides available); Hymedesmia (Hymedesmia) dichela ( Hentschel, 1911) syntype material ZMB Por 4438.

Diagnosis. Hymedesmia (H.) spinata n. sp. is characterised by two types of chelae and acanthostyles in a single category, widely variable in length and in the density of spination; smaller chelae have a characteristic apical spine on each ala.

Description. Epibiotic on Carijoa riisei ( Fig. 12 View FIGURE 12 A–C), which is completely encrusted by the sponge (1–2 mm thick), leaving only the polyp openings free ( Fig. 12 View FIGURE 12 C). Elevated, scattered oscules are evident. The holotype consists of several ramified fragments of C. riisei up to 8 cm long ( Fig. 12 View FIGURE 12 B); the paratype covers some branches of C. riisei , up to 10 cm long. Consistency is soft and the surface smooth; brown in situ ( Fig. 12 View FIGURE 12 A), whitish or orange when preserved in ethanol ( Fig. 12 View FIGURE 12 B, C).

Skeleton. Ectosomal skeleton as a thin dermal membrane with scattered tornotes and chelae tangentially disposed ( Fig. 12 View FIGURE 12 D). Choanosomal skeleton hymedesmoid; acanthostyles erect with heads on the substrate; scattered isotornotes and chelae in between. Tracts of tornotes run towards the surface connecting to ectosome ( Fig. 12 View FIGURE 12 E).

Spicules. Isotornotes straight with acerate extremities ( Fig. 12 View FIGURE 12 F), 177.5 – 245 x 2 – 5 μm. Acanthostyles in a single category, very variable in size and in the distribution of spines, 52.5 – 237.5 x 2.5 – 10 μm. Smaller acanthostyles strongly spined and with the tips ending in verticils of small spines ( Fig. 12 View FIGURE 12 G) are more frequent ( Fig. 13 View FIGURE 13 ); larger acanthostyles with no evident head, few spines and smooth tip ( Fig. 12 View FIGURE 12 H) are uncommon ( Fig. 13 View FIGURE 13 ); numerous intermediate forms with spined and smooth tips occur. Bhattacharya analysis of the acanthostyle lengths shows the presence of three distinct size categories ( Fig. 13 View FIGURE 13 and Tab. 5 View TABLE 5 ). Only the first and smallest category (with a mean of 81.15 μm) is, however, represented with a considerable number of spicules. Two other groups, both with fewer spicules, cannot be considered different size classes ( Fig. 13 View FIGURE 13 and Tab. 5 View TABLE 5 ). Arcuate chelae in two shapes and sizes: isochelae I with typical shape ( Fig. 12 View FIGURE 12 I), 22.5 – 27.5 μm; isochelae II, with a very thin curved shaft and inconspicuous alae (about 1/7 of the total length), 12.5 – 17.5 μm. A spine at the apex of each ala is visible under SEM ( Fig. 12 View FIGURE 12 J). Refer to Tab. 6 View TABLE 6 for complete measurements.

Remarks. As pointed out by Goodwin et al. (2011) a range in skeletal organisations has been documented from Hymedesmia and Phorbas , the thinner specimens having a Hymedesmia -like skeleton and the thicker a Phorbas - like architecture. Given the presence of acanthostyles erect on the substrate and supporting tornotes, we believe this species should be assigned to Hymedesmia .

Sixteen species of Hymedesmia (Hymedesmia) have been reported from the Indo-Pacific area (van Soest et al. 2011), 15 of which are characterised by a single category of chelae. Among these, the following have chelae sizes overlapping with our specimens: H. (H.) lancifera ( Topsent, 1906) and H. (H.) prostrata Thiele, 1903 both of which have chelae ~ 18 μm long, H. (H.) microstrongylata Bergquist & Fromont, 1988 with chelae of 18–30 μm, and H. (H.) stylophora Thomas, 1970 with chelae of 16–25 μm. Hymedesmia (H.) lancifera differs in having centrotylote tornotes with mucronate extremities and smaller acanthostyles (70 – 170 x 4.2 μm); H. (H.) microstrongylata has strongyloxeas and two categories of acanthostyles, with acanthostyle I up to 470 μm; H. (H.) stylophora has smaller acanthostyles (84–117 μm) and styles or subtylostyles as dermal spicules. Hymedesmia (H.) prostrata is very close to the new species ( Fig. 14A–D View FIGURE 14. A – D ); the re-examination of the holotype (slides of the skeleton) confirmed that it differs mainly in having one type of chelae ( Fig. 14D View FIGURE 14. A – D ) in a large size range (10 – (15.9 ± 3.9) – 22.5 μm), two types of acanthostyles of similar shape (187–240 μm and 80–117.5 μm, respectively; Fig. 14B, C View FIGURE 14. A – D ) and anisotornotes ( Fig. 14A View FIGURE 14. A – D ) (about 187.5–205 μm).

Among the species of Hymedesmia (Hymedesmia) from the Indo-Pacific area, only H. (H.) dichela ( Hentschel, 1911) possesses two categories of chelae; moreover it possesses acanthostyles and anisotornotes similar in shape and size to the new species ( Fig. 14 View FIGURE 14. A – D E–I). Nevertheless, the examination of the syntype reveals that in Hentschel’s species the tornotes have different extremities (anisotornotes, 150 – (189.3 ± 18.9) – 212.5 x 2 – (3 ± 1.2) – 5 μm) ( Fig. 14 View FIGURE 14. A – D E), acanthostyles (65 – (139.2 ± 62.3) – 230 x 5 – (6.1 ± 1.3) – 7.5 μm) always have smooth tips, not ending in verticils of spines ( Fig. 14 View FIGURE 14. A – D F), and chelae I (20 – (21.5 ± 1.8) – 25 μm) and II (10 – (12.5 ± 1.5) – 15 μm) are similar in shape ( Fig. 14 View FIGURE 14. A – D H, I); in particular chelae II, with SEM observations, do not have apical spines.

Etymology. Named after the presence of an apical spine on each ala of chelae II.