Mycale (Zygomycale) parishi ( Bowerbank, 1875 )

Mycale (Zygomycale) parishi ( Bowerbank, 1875) View in CoL

( Fig. 30 View FIGURE 30 A–M) ( Tab. 14 View TABLE 14 )

Examined material. Samples Port Allen 1, Port Allen 2, Port Allen 3: Hawai’i, Kaua’i Island, Port Allen Harbour, depth between 1–10 m, 0 2 June 2005; sample HK 10: Hawai’i, O’ahu Island, Hawai’i Kay, depth between 0.5–3 m, 31 May 2007; sample Carrambali 01: Indonesia, Bali Island, Garden eels I, 17 m, 18 October 2007.

Comparative material: holotype of Mycale (Aegogropila) pectinicola Hentschel, 1911 ZMB Por 4404 ( Fig. 31 View FIGURE 31 A-I).

Description. Pulpy sponge, about 2–3 mm thick, covering branches of Carijoa riisei up to the anthocodial bases and sometimes joining branches of the octocoral ( Fig. 30 View FIGURE 30 A, B). Consistency elastic and with macroscopically smooth surface ( Fig. 30 View FIGURE 30 B); with stereo-microscope examination, the surface is microhispid due to protruding mycalostyles. Beige alive ( Fig. 30 View FIGURE 30 A), in ethanol pinkish ( Fig. 30 View FIGURE 30 B). The Hawaiian specimens are nine ramified fragments of the octocoral, ~ 10 cm in length ( Fig. 30 View FIGURE 30 A); the Indonesian specimens are two fragments, up to 10 cm, joined by the sponge tissue.

Skeleton. Tracts of mycalostyles forming an ectosomal reticulum with triangular meshes ( Fig. 30 View FIGURE 30 C). Choanosome consisting of plumoreticulate, ascending, interconnecting tracts, irregularly arranged ( Fig. 30 View FIGURE 30 D). Anisochelae I arranged in rosettes in the choanosome. Spongin scarce.

Spicules. Mycalostyles often flexuous and with a slightly ovoid head ( Fig. 30 View FIGURE 30 E, L), 230 – 360 x 5 – 10 µm. Sigmas in two size classes: sigmas I “C” or “S” shaped ( Fig. 30 View FIGURE 30 F), 45 – 107.5 x 2.5 – 7.5 µm; sigmas II “C” shaped ( Fig. 30 View FIGURE 30 G, L), 14–43 µm. Palmate anisochelae in two size classes: anisochelae I are arranged in rosettes with straight shaft and short alae ( Fig. 30 View FIGURE 30 H), 40–62.5 µm; anisochelae II slightly curved ( Fig. 30 View FIGURE 30 I), 12–27.5 µm. Isochelae with very short lateral alae ( Fig. 30 View FIGURE 30 J), 7–15 µm. Toxas in a large size range ( Fig. 30 View FIGURE 30 K), 27.5–145 µm. Raphides arranged also in trichodragmas ( Fig. 30 View FIGURE 30 M), 20–50 µm. Refer to Tab.14 View TABLE 14 for complete measurements.

Distribution and remarks. Malacca Strait ( Bowerbank 1875), Mergui Archipelago ( Carter 1887), Australia ( Ridley 1884), Philippines ( Ridley & Dendy 1887 ), Indonesia and Palau (Hooper et al. 2000), Vietnam ( Azzini et al. 2007) and Hawai’i ( Bergquist 1967).

According to van Soest et al. (2011) three species belong to this subgenus: M. (Z.) angulosa (Duchassaing & Michelotti, 1864) , M. (Z.) parishi ( Bowerbank, 1875) and M. (Z.) ramulosa Carballo & Cruz-Barraza, 2010 . Mycale (Aegogropila) pectinicola Hentschel, 1911 was described with mycalostyles, additional isochelae, two classes of anisochelae, two classes of sigmas and microxeas ( Fig. 31 View FIGURE 31 A–I); the examination of its holotype confirmed the presence of isochelae ( Fig. 31 View FIGURE 31 F), but also of numerous toxas ( Fig. 31 View FIGURE 31 G) and micracanthoxeas ( Fig. 31 View FIGURE 31 I) not originally observed by Hentschel (1911). Because of the presence of isochelae, this species has to be moved to the subgenus Zygomycale .

Mycale (Z.) pectinicola View in CoL differs from our specimens by: i) the shape of the isochelae, which are characterised by a tooth on the central ala, variable in length ( Fig. 31 View FIGURE 31 F, Hentshel 1911: 300 Fig. 8 View FIGURE 8 d); ii) microxeas instead of raphides; iii) the presence of micracanthoxeas. The dimensions of toxas in M. (Z.) pectinicola View in CoL are slightly smaller ( Tab. 14 View TABLE 14 ). The Atlantic species M. (Z.) angulosa (Duchassaing & Michelotti, 1864) View in CoL is quite similar to M. (Z.) parishi View in CoL ; the latter shows a large variation in spiculation, which is not reported for M. (Z.) angulosa (van Soest 1984) View in CoL . Mycale (Z.) ramulosa View in CoL differs from M. (Z.) parishi View in CoL mainly in the presence of micracanthoxeas.

Our specimens are similar to M. (Z.) parishi View in CoL in skeletal organisation and spicule complement. No differences in general morphology or in spiculation were recorded between the Hawaiian and Indonesian specimens ( Tab. 14 View TABLE 14 ). Mycale (Z.) parishi View in CoL is a thinly encrusting species, known to grow over other organisms (molluscs, bryozoans). In Hawai’i it was recorded mainly in the fouling communities of harbours (see Carlton & Eldredge 2009).

The re-examination of the type of M. (A.) hentscheli (see M. (A.) furcata ) and of M. (Z.) pectinicola revealed the existence of other two species of Mycale with micracanthoxeas, besides the six species known thus far ( Carballo & Cruz-Barraza 2010): M. (C.) micracanthoxea , M. (C.) urizae , M. (A.) bamfieldensis , M. (A.) escarlatei , M. (A.) lilianae and M. (Z.) ramulosa . Four of these ( M. (A.) hentscheli , M. (Z.) ramulosa , M. (Z.) pectinicola and M. (A.) bamfieldensis are described in the Indo-Pacific ocean.

It is interesting to note that micracanthoxeas are not a character restricted to genera Carmia and Aegogropila ( Carballo & Hajdu 1998) , but are also present in two species of Zygomycale . This subgenus is mainly based on the presence of isochelae, but some authors considered it synonymous with Aegogropila , recognizing the character “isochelae” as plesiomorphic (see comments in van Soest & Hajdu 2002b). The discovery of micracanthoxeas in two species of Zygomycale adds further controversy to the currently accepted subgeneric classification of Mycale , stressing the need for clarification of these phylogenetic relationships.