New genus and species of lithistid demosponges from submarine caves in Nuku Hiva (Marquesas Islands) and Tahiti Iti (Society Islands), French Polynesia

Lithistid demosponges are well known from limestone caves of karstic origin in the Mediterranean Sea. However, they have never been reported from submarine caves of volcanic origin in the South Pacific. Here, we describe and provide DNA barcodes for four new lithistid demosponges including one new genus. All species grew on basaltic rocks inside lava tubes on Nuku Hiva Island (Marquesas Islands) and Tahiti Iti peninsula on Tahiti Island (Society Islands) in French Polynesia. Three of the species have rhizoclone desmas as choanosomal skeletons and belong to the family Scleritodermidae ( Microscleroderma miritatarata sp. nov. and Microscleroderma lava sp. nov.) and Siphonidiidae ( Gastrophanella basaltica sp. nov.). The new genus Levispongia gen. nov. belongs to the family Corallistidae. The new species Levispongia meyeri gen. nov. sp. nov. has dicranoclone desmas, complex dichotrianes with strongly spinose upper surfaces of the cladome and microstyles as the only microscleres. Phylogenetic relationships of these new species are discussed and compared with other material from the Caribbean and Central to the West Pacific Ocean.


Introduction
Submarine caves share several ecological features which often resemble that of deep-sea habitats including darkness, hydrodynamic, geochemical and faunal compositions (Harmelin & Vacelet 1997). Although differences in pressure, temperature and habitat sizes exist (Moldovan et al. 2019), these submarine caves are often colonized by deep-sea invertebrates like gastropods, annelids, crustaceans and sponges (Bussotti et al. 2006;Gerovasileiou et al. 2015;Culver & Pipan 2019). In particular, the abundance of demosponges represents an important element of submarine cave communities (Bibiloni et al. 1989;Gerovasileiou & Voultsiadou 2012). Since most of these caves are accessible by SCUBA diving, they provide a unique opportunity to study various aspects of deep-sea sponge biology and systematics (Vacelet 1996). However, we still know little about the diversity and connectivity of sponges from different cave systems around the world, especially how many of these species are cryptic or relict, present as a living fossil. Sponge cave biodiversity has been well studied in the Mediterranean Sea (e.g. Gerovasileiou et al. 2016). The Mediterranean submarine caves are all of karstic origin (limestones) and are a large biodiversity reservoir of sponge species that are otherwise only recorded from the deep-sea (Gerovasileiou & Voultsiadou 2012). In particular, the occurrence of a polyphyletic group of demosponges historically called lithistids (Pisera & Lévi 2002a;Schuster et al. 2015) seems to be highly abundant and thrive in these cave systems (Pérez et al. 2004;Manconi et al. 2006;Manconi & Serusi 2008;Pisera & Vacelet 2011;Pisera & Gerovasileiou 2018). Lithistids are characterized by an articulated choanosomal skeleton composed of siliceous desmas. Molecular systematics placed the majority of these desma-bearing sponges into the order Tetractinellida Marshall 1876 (Schuster et al. 2015). In oceans today, lithistids are normally found in deep-waters of the tropics (Carvalho et al. 2015;Schuster et al. 2021), however, some species are also found in shallow waters (Pomponi et al. 2001). It is postulated that the majority of these sponges were originally shallow water sponges that moved into deeper waters as silica concentrations decreased in shallow water (Pisera 2004). Few records exist of lithistid cave fauna occurring outside the Mediterranean Sea (Gerovasileiou et al. 2016;Gómez et al. 2021). Some lithistids were described from shallow crevices in coral reefs of Madagascar (Vacelet & Vasseur 1965), from the central western Atlantic in Belize and Fernando de Noronha (Muricy & Minervino 2000), and a few more were observed in a large submarine cave on Palawan in the Philippines, which represents the only known record of cave lithistids so far in the Pacific Ocean (Pisera & Vacelet 2006). In all investigated caves, the dominant lithistid species seem to belong to rhizomorine families like Scleritodermidae Sollas, 1888, Azorizidae Sollas, 1888Siphonidiidae Von Lendenfeld, 1903 and dicranoclone family Corallistidae Sollas, 1888. All of which are usually recorded from deep-waters. The observed morphological features from all these various cave lithistids show high affinities to those of the Mesozoic of Europe (Łukowiak et al. 2014;Frisone et al. 2016;Świerczewska-Gładysz 2016), which would suggest that most of these species represent a relict fauna with probable Tethys origin as already predicted for other non-cave lithistids (Reid 1967;Manconi 2011) and recently tested with molecular clocks for the lithistid genus Vetulina (Sphaerocladina Schrammen 1924 (Schuster et al. 2018).
In this integrative taxonomy study, we describe for the first time four new lithistid demosponges and one new genus from two shallow submarine caves in French Polynesia: Ekamako Cave at the southern coast of Nuku Hiva (Marquesas Islands) and Te Pari Cave on Tahiti Iti peninsula (Tahiti island, Windward Islands, Society Islands) (Figure 1). In contrast to the above-mentioned limestone caves, the Polynesian cave systems are formed by large lava flows and are of volcanic origin. This is an important finding not only because they grow on these basaltic volcanic rocks inside lava tubes, but also due to the fact that the new genus and species described herein represent the first records of lithistids from this extreme isolated archipelago in French Polynesia. Thus, our results will be of profound interest for further biogeographical and systematic studies on this evolutionary important demosponge group.
The sponges from Tahiti Iti peninsula were also collected by SCUBA diving from a lava tube inside the Te Pari Cave (Tahiti Island, Windward Islands, Society Islands) (Figure 1 D,E). For more details on the cruise see Debitus (2013). The entrance of this cave is about 10 m wide and its sandy bottom lies at 12 m depth. It forms a right angle 25 m after the cave mouth and is another 180 m long (measured with a hand depth sounder). It is a regular 6-8 m wide cylinder, that narrows and rises towards the end. The sides and bottom (after the turn) are formed of irregular basaltic rocks. The cave ends in a narrow, rocky, chaotic pipe, inaccessible for divers. The roof at the end of the cave is characterized by an air pocket as it is above sea level. The presence of a few dead leaves indicated freshwater inflows, probably during heavy rains. The top water column temperature in the cave was around 26°C, while the lower bottom was warmer around 28°C, and the open sea temperature was 30°C. This cooler top water temperature would confirm the inflow of freshwater, thus keeping the upper layer of the cave water cooler. Further indication for freshwater inflow is given by the observation of some cave 750 A. Schuster et al. openings that are close to trails where locals observed salty water coming out during rough seas and killing the surrounding plants, however, no light could be observed inside the cave. Moreover, the water at the surface in the back (end) of the cave tasted less saline than throughout the rest of the cave, which again indicates the inflow of freshwater from the surrounding environments. This cave represents a hot spot of diversity of sponges in Tahiti and concentrates almost half of the total observed species in our surveys (26 species including lithistids, most of them new to science) (personal observation by the author C. Debitus). Worth mentioning is that the first 25 m into the cave (before the turn) concentrate most of the nonlithistid sponge species of which some are already described and published such as the calcareous Leucetta chagosensis Dendy, 1913 and Ascandra cf. crewsi (Klautau et al. 2020) and many more demosponge species that await formal descriptions (Chondrosia corticata, Psammocinia sp., Suberea ianthelliformis, Spirastrella sp., Chondrosia sp., Tedania sp., Hyatella sp., Dysidea sp., Psammoclema sp., Haliclona spp., Halichondria sp., Chondrilla sp., Cinachyrella sp., Luffariella sp., Rhabdastrella sp.). The lithistids were found further inside the cave on the walls and roof of the cave, with Microscleroderma lava sp. nov. first, after which Gastrophanella basaltica sp. nov. and Levispongia meyeri gen. nov. sp. nov. followed further inside the cave with a few other demosponges on the rocky blocks on the cave floor (Suberea sp., Halichondria sp., Dysidea sp., Haliclona sp., Tedania sp., Plakinastrella sp.).
All lithistid specimens were preserved in 70-80% ethanol and are deposited within the "Zoothèque" of the Natural History Museum in Paris (MNHN). SEM stubs and small pieces of the holotypes and paratypes are stored at the Polish Academy of Sciences, Institute of Paleobiology in Warsaw, Poland (ZPAL). In addition, DNA samples are available at the Bavarian State Collection for Palaeontology and Geology (BSPG) in Munich, Germany. DNA barcodes are registered at the Sponge Barcoding Database (SBD) https://www.spon gebarcoding.org/ and new sequences (28S, C1-D2 region) from this study are deposited at the National Center for Biotechnology Information (NCBI). New species are registered in ZooBank (http://zoobank. org/urn:lsid:zoobank.org:pub:844E385C-9A92-4F1B-B85C-9C1E319CD13F.) Morphological features of the specimens were analyzed through Scanning Electron Microscopy (SEM). In detail, pieces of the ectosome and choanosome of the sponges were cut and either directly mounted on stubs or digested in nitric acid (HNO 3 ) first, in order to remove any organic material, followed by several washing steps with distilled water and twice 70-80% ethanol before a final fixation in 99% ethanol (Pisera & Pomponi 2015). Dried spicules, zygosed skeletons and chemically untreated surfaces were mounted on stubs using Carbon-Leit -C (PLANO, Germany) and covered with platinum for examination on a Philips L-20 SEM at the Institute of Paleobiology in Warsaw, Poland.

Molecular Systematics
For the assessment of the molecular relationships of the new species and the new genus Levispongia gen. nov. among other lithistids, we performed two separate phylogenetic analyses. One for the family Corallistidae where the new genus belongs to, and another for the suborder Spirophorina Bergquist & Hogg, 1969 that includes all new rhizomorine species from this study. In detail, we used the C1-D2 region of the 28S rDNA gene (~800 bp) that has been shown in previous studies to resolve relationships on species level (see Schuster et al. 2015Schuster et al. , 2018. For Microscleroderma lava sp. nov. (LR656090) and the two Microscleroderma miritatarata sp. nov. (LR656088, LR656089) 28S sequences already exist and were extracted from Schuster et al. (2021). For Gastrophanella basaltica sp. nov. and Levispongia meyeri gen. nov. sp. nov., new sequences of the same gene were obtained following the molecular barcoding protocol in Schuster et al. (2015Schuster et al. ( , 2021. For a better overview, we reduced the sequence alignment of Schuster et al. (2021) to the family Corallistidae which includes representative species from all six valid genera (Awhiowhio Kelly, 2007, Corallistes Schmidt, 1870, Herengeria Lévi & Lévi, 1988, Isabella Schlacher-Hoenlinger, Pisera & Hooper, 2005, Neophrissospongia Pisera & Lévi, 2002band Neoschrammeniella Pisera & Lévi, 2002b and aligned to this the new sequence Levispongia meyeri gen. nov. sp. nov. using AliView v.1.26 (Larsson 2014). A reduced alignment from Schuster et al. (2021) including Scleritodermidae, Siphonidiidae and Azoricidae was used to calculate the phylogenetic tree. Since in this study the new Microscleroderma species were already included, only Gastrophanella basaltica sp. nov. was added using the same program as above.
Bayesian inference (BI) of phylogenies was executed separately for each dataset using the MrBayes 3.2.2 plugin on the CIPRES Science gateway (Miller et al. 2010). The best fit evolutionary model (GTR +G + I) was selected according to the results of JModelTest2 (Darriba et al. 2012) plugin using the CIPRES Science Gateway v.3.3 (Miller et al. 2010). Two concurrent runs of four Metropolis-coupled Markov-chains Monte Carlo (MCMC) for 100,000,000 generations were run and stopped when the average standard deviation of split frequencies reached below 0.01. The first 25% of the sampled trees were discarded as burn-in for further analyses. FigTree v1.4.2 (Rambau 2009) and Inkscape 1.0 was used to visualize the trees.
Unfortunately, we could not sequence the independent mitochondrial barcoding marker COI for Gastrophanella basaltica sp. nov. and Microscleroderma miritatarata sp. nov., most likely because of the presence of intronic regions within COI. These intronic regions seem to be widespread among rhizomorine taxa (see Schuster et al. 2017) and it was detected in the new species Microscleroderma lava sp. nov. (COI = LT628364, synonym Microscleroderma sp.3, in Schuster et al. 2017). In fact, this species harbors two intron insertions (ORF 723 and ORF 870) within its most conserved COI barcoding region. Therefore, we suspect that also Microscleroderma miritatarata sp. nov., contain such an intron, which awaits to be sequenced in a follow-up study. Etymology. This genus name is given to honor Prof. Claude Lévi for his achievements in sponge science.
Diagnosis. Massive to fan-shaped corallistid with complex dichotrianes that show a strongly spinose upper surface of their cladome and microscleres that are microstyles and microrhabds; no streptaster of any kind.

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Remarks.
The new genus is close to Neophrissospongia as it shares very similar desmas with a central core, complex dichotriaenes with spinose or tuberculated upper surface of the cladome and microstyles among microscleres. However, it lacks any kind of streptasters, but instead has two types of spinose microrhabds. Also, the habitus of this new species is different from most, but not all Neophrissospongia species, which are vase or foliose in shape. Such differences usually are treated to characterize different genera (see for example Racodiscula; Zittel, 1878 and Theonella; Gray, 1868; (Pisera & Lévi 2002c)). The only other close corallistid species, attributed earlier to Neophrissospongia, is N. microstylifera Lévi & Lévi, 1983 from New Caledonia, as a result we propose to transfer this species from the genus to the new genus Levispongia gen. nov.

Levispongia meyeri sp. nov. (Figures 2-4)
Diagnosis. Massive to fan-shaped sponge composed of cylindrical units that are more or less fused; dichotriaenes are complex and have strongly spinose upper surface of cladome; desmas are dicranoclones with central core and are strongly tuberculated; larger tubercules are ornated by small tubercules; microscleres as spinose microstyles and two types of spinose microrhabds; one is thin, long and curved, the second is short, massive and often irregular. Type locality. Tahiti Iti peninsula, Tahiti Island, Society Islands, French Polynesia (Figure 1(a,d,e)).
Distribution. Only known from type locality.
Habitat. Lava tube cave, attached to basaltic rocks.
Description. Morphology, the examined sponges have the shape of cylindrical almost erected subunits that are fused and evenly anastomosing along most of their length, each with its own osculum ( Figure 2). The body plus side growths of the largest sponge (holotype, MNHN-IP-2019-2) is 13 cm wide x 10 cm high and about 2 cm thick, Figure 2(c-e)). The individual cylinders are up to 10 cm long and about 0.5-1 cm in diameter. The top of cylinders is rounded with a small 1-3 mm centrally located osculum. There are about seven of such cylindrical subunits present in the holotype (Figure 2(c-e)) with numerous outgrowths on sides at the base. At the base of the fan, those cylindrical subunits have an irregular orientation, are shorter and only partly fused (Figure 2(d,e)). The two smaller paratypes (Figure 2(a,b)) are of the same growth form but smaller in size (6 cm wide x 3.5 cm height and are 1-1.5 cm thick, and 7 × 5 cm and 1 cm thick). The smallest specimen is just 2 × 1.5 in size and formed by the partial fusion of only three cylinders. Texture, stony and hard. Surface, even, but not entirely smooth due to the rugged surface of the choanosomal skeleton protruding in many places from below the ectosome.  (Figure 4(n-r)). Choanosomal skeleton composed of zygosed dicranoclone desmas ( Figure 3) and microstyles. Megascleres, desmas that are massive arched shaped with a central core from which several arms (four to six) branch from the underside of the arch and both the core and the arms are strongly covered with irregular tubercles (Figure 3). Young dicranoclone desmas are less tuberculated than mature ones (Figure 3(f)). Microscleres, in the holotype are spined microstyles that occur in the choanosome and that are 77.6-93.6 μm long and 3.09-4.56 μm in diameter at the top (Figure 4(k-m)); short and thick microrhabds that are concentrated in the ectosome and that are 24.4-32.7 μm long and 11.3-17.3 μm in diameter (Figure 4(a-c); (h-j)), as well as longer slightly curved rhabds that are 47.1-53.6 μm long and 6.73-9.83 μm in diameter (Figure 4(d-g)).
Etymology. Named after Jean-Yves Meyer, research delegate of French Polynesia and an active conservation biologist in French Polynesia who helped in various logistical and administrative ways during our sampling field trips.  Figure 14) that has a similar set of microsclere characters (pers. observation A. Pisera) and is molecularly sister (3 bp difference) to the new Levispongia gen. nov. species (Figure 14). We therefore suggest to synonymize the species WAM Z35946 (LR656117) with the new genus Levispongia gen. nov. sp. (Figure 14). Due to major differences in the composition of microscleres and the species specific habitus, we assign the new described species L. meyery sp. nov. and L. gen. nov. sp. (WAM Z35946) together with N. microstylifera to the new genus Levispongia that is sister to the genus Neophrissospongia ( Figure 14). The species N. microstylifera (0CDN7083-J, LR656096) will be N. cf. microstylifera until further investigations and comparison.    Distribution. Only known from type locality Tahiti Iti Island.
Habitat. On basaltic rocks in lava tube caves.
Description. Morphology of the holotype (specimen MNHN-IP-2019-7) is an irregular mass of cylindrical subunits (or fan-like with additional lateral tubes). Each tube is fused at the base or along most of its length and has an apical osculum of 1 to 3 mm in diameter ( Figure 5(g,h)). The sponge is 6 cm wide and 4.5 cm high and has about 20 tubes ranging from 3 mm to 10 mm in diameter ( Figure 5(g,h)). Texture, stony and hard. Color in life is cream white and beige

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A. Schuster et al. to light brownish in ethanol. Surface, mostly inhalant; these areas are separated by narrow, slightly elevated flat ridges that are smooth. Short sinuous subdermal canals are visible on the surface that run from the top of tubes downward. Inhalant areas are rough on the surface of the narrow, short skeletal ridges that run in all directions; between them are sparsely distributed depressions with ostia. This entire surface is hispid as it is covered with very short protruding microsclere spicules. One of the paratype specimens (MNHN-IP -2019-9, Figure 5(d-f)) differs considerably in morphology by being a curved shallow earshaped fan with two clearly different surfaces, one is concave, has a lot of irregularities and is rough with subdermal short skeletal ridges visible on the surface (the same as inhalant areas in the holotype MNHN-IP-2019-7) between each ridge membranes ostias are visible that measure about 0.05-0.1 m in diameter. This concave side has exotylostyles that are densely distributed and oriented perpendicularly to the surface. The other side that is convex bears numerous (about 30) raised oscula that are 1-2 mm in diameter. The oscula are located on low (up to 5 mm high) conical outgrowths. Oscula approaches the upper margin of the sponge from the convex side. The oscula membrane is armed with tangentially embedded exotylostyles. Ectosomal skeleton, with exotylostyles that are densely distributed and oriented perpendicularly to the surface (Figure 6(a)). On the concave side, the margin bears numerous sinuous subdermal furrows that are visible  the exotylostyles are 10.9-14.2 μm long and 12.3-14.3 μm in diameter, whilst the rhabd is 9.41-11.1 μm in diameter at the top (Figure 7(e,f)).
Etymology. named after the basaltic rocks on which it grows inside lava tube cave.
Remarks. Gross morphology of the sponge resembles that of Levispongia meyeri gen. nov. sp. nov., for which it could be mistaken for in the field, however, it has different spicules: rhizoclones instead of dicranoclones, and microscleres as spiny exotylostyles. To date, three Gastrophanella species are known from the Atlantic namely G. implexa Schmidt, 1879, G. cavernicola Muricy &Minervino, 2000 andG. stylifera;Mothes & Silva, 1999, however, the latter one might be likely a junior synonym of G. implexa (see Pisera & Lévi 2002d). One species is known from a cave in the Mediterranean Sea G. phoeniciensis Perez, Vacelet, Bitar & Zibrowius, 2004 and another one G. mammilliformis Burton, 1929 was recorded from South African waters, with no precise location given (Burton 1929). Until now, the only known Gastrophanella from the central Eastern Pacific coast of Mexico was G. primore Gómez, 1998. Our new species Gastrophanella basaltica sp. nov. will add the second species of this genus in the Pacific. Its habitus is similar to G. cavernicola from Fernando de Noronha, Brazil because both species form a mass of cylindrical tubes, but G. cavernicola is rather massive while our species is rather fan shaped. Another similar species from the Atlantic (Brazil) is G. stylifera Mothes and Silva, 1999 which is tube shaped thus also similar. Molecularly (28S C1-D2, Figure 15) G. basaltica sp. nov. is closely related (2 bp difference) to species from Honduras and Curacao ( Figure 15) that were first considered to belong to the genus Siphonidium in Schuster et al. (2021). Based on our current morphological and molecular barcodes of the G. basaltica sp. nov. in this study we propose the reallocation of all species (LR656148, LR656147, LR656145, LR656146, LR656150) to the genus Gastrophanella ( Figure 15).
Diagnosis. Microscleroderma with laminar folded slightly compressed growth morphology. Surface covered with long hair-like oxeas; microscleres as thick spinose sigmaspires. Type locality. Tahiti-Iti peninsula, Tahiti Island

Distribution. French Polynesia
Habitat. On basaltic rock in lava tube cave Te Pari Description. Morphology, three larger and three very small fragments of the same laminar sponge were examined. The larger fragments show several folds that are slightly compressed (Figure 4(a,b)). The size of the largest fragment is about 4 cm long, 2.5 cm in wide and 3 cm high. The thickness of the folds is 3 to 5 mm. Ectosomal surface is even and strongly hispid on both sides; there are evenly and densely occurring depressions with ostia openings that are about 0.4-0.5 mm in diameter. Choanosomal skeleton, is evenly and densely covered by canal openings that are 200-300 μm in diameter and contains rhizoclone desmas. Megascleres are dense heavily spined rhizoclones (Figure 8(c,f)), where the spines are divided many times. On the surface, long hair-like oxeas are visible (Figure 8  (a,b)). Microscleres as relatively thick spinose sigmaspires that are 13.0-16.0 μm long and 2.02-2.76 μm in diameter (Figure 9(a-h)).

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Etymology. Named after its occurrence in caves formed by lava flows. Remarks. This species is most similar to Microscleroderma lamina Perez, Vacelet, Bitar & Zibrowius, 2004 from the submarine cave in Lebanon (Eastern Mediterranean Sea), however, its desmas are rather tuberculated than spinose, sig-

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A. Schuster et al. maspires are more S-shaped and spiral, as well as much smaller and less thick than in M. lava sp. nov. In habitus M. lava sp. nov. resembles also M. novaezelandiae Kelly, 2007 from New Zealand, but its outer wall is considerably thicker and rhizoclone desmas are different. The sizes of the sigmaspires are similar, albeit being slightly smaller and less thick (stout). The differences mentioned here between our Tahiti material and the one from New Zealand, as well as their geographical distance between them, support the morphological difference that they are different species. Notable that features of M. novaezelandiae are not well illustrated in detail, making any closer comparison difficult. Molecularly these two species differ by 28 bp difference in the 28S C1-D2 region (Figure 15).

Microscleroderma miritatarata sp. nov.
( Figures 5(a-c), 10-13) Description. Morphology, the holotype (MNHN-IP -2019-11) is a complex mass of folded laminae that is 7.5 cm large and about 4 cm wide and 3 cm high. The laminae are 5-6 mm wide and have rounded margins (Figure 3(a-c)). Surfaces, both inner and outer surface are strongly hispid, especially in protected areas in the folds. Colour, in situ is light yellowish beige and beige with light brownish spots in ethanol. Megascleres, in the exposed areas (i.e. ectosomal outer part of the sponges) the protruding oxeas are either absent or very sparsely distributed ( Figure 10). All thin, long hair-like oxeas observed in our preparations were broken and thus not measured. Microscleres are spinose sigmaspires that are 11.6-12.6 long and 1.64-2.12 um thick (Figure 13(a-e)). Morphology of the paratype (MNHN-IP-2019-12) represents an ear shaped fragment, probably from a larger folded massive specimen (Figure 3(a,b)) that is 4 cm high and 3.5 cm wide with walls about 8 mm thick and rounded margins. Both surfaces are even and covered with small depressions that are densely and evenly distributed over the entire surface. On the outer site of the sponge these depressions are up to 0.4 mm in diameter and separated by a very narrow skeletal band; on the inner side of the sponge body they are also 0. 4 mm in diameter, but slightly less depressed; this inner side has a hispid surface due to the numerous very long (mm scale) oxeas  Remarks. This species is most similar to the new species Microscleroderma lava sp. nov. from Tahiti Iti, however, it differs in having longer, thinner and more spined sigmaspires. It also differs in the gross morphology. Another morphologically close species is M. lamina from the Lebanon coast of the Mediterranean Sea (Pérez et al. 2004), but their geographic distance makes their con-specificity very unlikely. Molecularly our new species M. miritatarata sp. nov. is sister to Microscleroderma sp. 1 (LR656087) from Martinique ( Figure 15).

Discussion and summary
In this study, we report for the first time the occurrence of lithistids in French Polynesia and subsequently increase the current knowledge on Pacific lithistids. Three new species of rhizomorines were described i.e. Microscleroderma lava sp. nov., Microscleroderma miritatarata sp. nov. and Gastrophanella basaltica sp. nov. One new corallistid species Levispongia meyeri gen. nov. sp. nov., which is also a new genus based on the morphological and the phylogenetic species concept, was also described.
Microscleroderma miritatarata sp. nov. was found in the cave Ekamako on Nuku Hiva Island (Marquesas Islands) (Figure 1), characterized by its rhizoclones desmas and sigmaspire microscleres. The three other lithistid species were found in a longer submarine cave at Te Pari on Tahiti Iti peninsula (Tahiti Island, Windward Islands, Society Islands) ( Figure 1). Microscleroderma lava sp. nov. is very similar to M. miritatarata sp. nov. from Nuku Hiva, but differs morphologically and molecularly (33 bp difference). Organic extracts of M. miritatarata sp. nov. displayed antifungal properties related to the presence of microsclerodermins, as described in other species from the Western Pacific deep waters and from a shallow water species from Mauritius, Microscleroderma herdmani, Dendy, 1905;(Bewley et al. 1994;Qureshi et al. 2000). Previous to this study, only three species of Microscleroderma were described from the Indo-Pacific namely M. hirsutum, M. herdmani and M. stonae Lévi & Lévi, 1983, however, none of these species were recorded in caves. So far, the only cave species (Microscleroderma lamina Pérez, Vacelet, Bitar & Zibrowius) was found in the Eastern Mediterranean Sea (Pérez et al. 2004). The new Microscleroderma species from Marquesas and Tahiti are most similar in morphology and spiculation to the Mediterranean

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