Tethya leysae Heim & Nickel, 2010, sp. nov.

Tethya leysae sp. nov. Holotype: NHM 2009.5. 1.1, Leg. Sally P. Leys, 25.06. 2003. Paratype: PMJ Porif 287, Leg. Sally P. Leys, 27.09. 2006 Type locality: Rocky hard bottom substrate in the shallow Infralittoral (10 - 25 m depth) near Ohiat Islet, Northeast Pacific, Barkley Sound, Bamfield, Vancouve...

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Main Authors: Heim, Isabel, Nickel, Michael
Format: Text
Language:unknown
Published: Zenodo 2010
Subjects:
Online Access:https://dx.doi.org/10.5281/zenodo.5696287
https://zenodo.org/record/5696287
id ftdatacite:10.5281/zenodo.5696287
record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic Biodiversity
Taxonomy
Animalia
Porifera
Demospongiae
Hadromerida
Tethyidae
Tethya
Tethya leysae
spellingShingle Biodiversity
Taxonomy
Animalia
Porifera
Demospongiae
Hadromerida
Tethyidae
Tethya
Tethya leysae
Heim, Isabel
Nickel, Michael
Tethya leysae Heim & Nickel, 2010, sp. nov.
topic_facet Biodiversity
Taxonomy
Animalia
Porifera
Demospongiae
Hadromerida
Tethyidae
Tethya
Tethya leysae
description Tethya leysae sp. nov. Holotype: NHM 2009.5. 1.1, Leg. Sally P. Leys, 25.06. 2003. Paratype: PMJ Porif 287, Leg. Sally P. Leys, 27.09. 2006 Type locality: Rocky hard bottom substrate in the shallow Infralittoral (10 - 25 m depth) near Ohiat Islet, Northeast Pacific, Barkley Sound, Bamfield, Vancouver Island, British Columbia, Canada (Fig. 1), coordinates 48 ° 51 ’3.00’’ N, 51 ’ 3 ’’ 125 ° 11 ’60.00’’ W. Diagnosis. Tethya leysae sp. nov. is the only Tethya species in the NE Pacifc possessing a massive uniform cortex with few lacunae and densely packed megasters (oxyspherasters 41-115 µm; R/C 0.41), which are larger and display shorter rays compared to T. californiana . It also lacks the alveolar exocortex and the bilayered megastrer distribution typical for T. californiana Two categories of oxeas/strongyloxeas, both slightly larger/thicker than in T. californiana : main (1580-2540 µm x 18-53 µm) and auxiliary (490-1490 µm x 7–30), lacking tylostrongyles. Etymology. We have chosen the name in honor of Prof. Dr. Sally P. Leys, Edmonton, BC, Canada, who collected and kindly provided the type specimens and is an inspiring colleague and friend. Description. General body morphology. The body is spherical, with a diameter of 5 x 4 cm (holotype; Fig 2 A). Sections show an unambiguous division into a cortex region and a choanosomal core (Fig. 3 A). The colour in life is orange-yellow to light red (Fig. 2 C). The colour in alcohol is white, with a greyish core (Fig. 2 A). In living specimens, the body is slightly contractile. However, the overal body consistency is incompressible. The verrucose surface is frequently loaded lightly with sediment. The surface lacks tubercles, filaments and stalked buds (at least they have not been found in the examined material). The cortex is dense and compact, with 3-6 mm in thickness. It lacks lacunae, but is packed with megasters (Figs. 3 and 4). Skeletal morphology. The dense radiate bundles of main megascleres (oxeas and strongyloxeas) display diameters between 400–600 µm (see sections, Fig. 3 C, F; and microtomographic reconstructions, Fig. 4 A, B). The bundles terminate in compact cortical fans which are formed by the main and auxiliary megascleres and make up broad cortical tubercles (Figs. 3 B) which contribute to the external verrucose appearance. Groups of auxiliary megascleres are also present interstitially in the choanosome between the main bundles (Fig. 3 C). The megasters (spherasters/oxyspherasters) are evenly and densely scattered throughout the whole cortex (Figs. 3 B, 3 F, 4), but almost lacking in the peripheral 200–500 µm of the cortex (Fig. 3 D) and in some basal parts of the cortex near the cortical-choanosomal boundary (Fig. 3 E). Micrasters form a discrete layer allocated in the exopinacoderm surface (Fig. 3 D) and are most dense in the peripheral cortex. In addition, micrasters are evenly but sparsely distributed throughout the cortex and the choanosome. Spicules. The main megascleres are constituted by oxeas, anisostrongyles and strongyloxeas (Fig. 5), 1580–2540 µm (2049 ± 259 µm; n= 40) in length, 18–53 µm (34 ± 7 µm; n= 40) in diameter. Auxiliary megascleres are constituted by oxeas, anisostrongyles and strongyloxeas, 490–1490 µm (1055 ± 215 µm; n= 128) in length, 7–30 µm (19 ± 5 µm; n= 128) in diameter. Main and auxiliary megascleres form two significantly different length categories (independent t-test, p<0.001; Fig. 6 B), both of normal distribution (Kolmogorov-Smirnov test). The megasters are represented by spherasters to oxyspherasters of varying size and morphology, as evidenced by SEM and microtomography reconstructions (Figs. 5 B, C, 6 A and 7 C, Tab. 1). Cortical megasters (Fig. 5 B) display 8–20 rays and are 41–115 µm (84 ± 12 µm; n= 40) in diameter with R/Cs of 0.34– 0.69 (0.46 ± 0.07; n= 227). Choanosomal megasters (Fig. 5 C) display 12–18 rays and are 24–81 µm in diameter, with R/Cs of 0.25–0.81 (0.41 ± 0.1; n= 85). The form of the rays varies in both regions from slender to stout (Fig. 5 B, C). A Kolmogorov-Smirnov test (independent t-test, p<0.001) suggests that choanosomal oxyspherasters size is significantly smaller than in cortical megasters. Micrasters (Fig. 5 D) fall into four categories: acanthoxyspherasters (Fig 5 D, top left), 10–19 µm in diameter with 10–12 rays (the main category); acanthostrongylasters (Fig. 5 D, top middle) 8–18 µm in diameter, with 8–12 rays; a few acanthotylasters with only slight terminal knobs (Fig. 5 D, top right), 6–8 µm in diameter, with 10–14 slightly spinulated rays; and small oxyspherasters (Fig. 5 D, bottom), 4–10 µm in diameter, with 10–15 slender rays. Molecular characters. The nucleotide sequences of the cytochrome oxidase subunit I (Folmer fragment) are accessible in Genbank (holotype: GQ 292532; paratype: GQ 292533) and at www.spongebarcoding.org (record no. 222). The base pair exchanges in the COI fragment and the deduced amino acid sequences (Tab. 2) clearly distinguish T. leysae sp. nov. from T. californiana (4 nt/ 2 aa), T. minuta Sarà, Sarà, Nickel & Brümmer, 2001 (22 nt/ 3 aa) and T. actinia (18 nt/ 3 aa). Reproduction. Asexual reproduction by bud formation near the sponge surface is indicated (Fig. 2 C; asterisks). No data exist to date on the sexual reproduction of T. leysae sp. nov. Ecology. The type habitat at Barkley Sound is infralittoral hard bottom influenced by strong tidal changes such as regular periods of strong currents. Usually, T. leysae is found in aggregates of several specimens (presumably due to asexual reproduction by budding). Larger specimens of up to 8 cm diameter sometimes cluster in sheltered small canyons of wave exposed areas. Tethya leysae sp. nov. is most abundant in depths between 15–20 m with moderate water flow but no direct wave exposure or current. It usually lives in lighted conditions and on shaded rocks, but avoids dark habitats. Specimens of T. leysae sp. nov. are frequently found to be covered by debris which might be particulate organic matter, but also algae and other small epibionts like foraminifers. In some areas of Barkley Sound, it is the most obvious subtidal sponge. Other common sponges are Neopetrosia vanilla (de Laubenfels, 1930) and Cliona sp. (for a species list compare Austin et al. 1999 –2007). Distribution. At present, T. leysae sp. nov. has only been reported for its type locality Barkley Sound, near Bamfield, British Columbia, Canada. It is likely to occur more widely along the North American Pacific coast but its biogeographical limits are presently not known. Related species. Comparative morphology (general anatomy, skeleton structure, megasclere and microsclere sizes, forms and distribution) suggests that T. leysae sp. nov. might be closely related to T. aurantium , T. robusta (Bowerbank, 1873) and T. californiana . At present, T. californiana seems to be the only species which eventually occurs sympatrically. However, T. leysae sp. nov. can be clearly distinguished from T. californiana by the lack of an alveolar cortex and the extremely high density of megasters in the cortex. Another striking difference is the megaster morphology. Their R/C values differ significantly between T. californiana and T. leysae sp. nov. (Tab. 1) and the oxyspherasters of the latter rarely display bent rays. In addition, spherules have not been found among the micrasters of T. leysae sp. nov. However, this character can only be accessed by extensive and very careful study of spicule preparations. In addition to the morphological differences between T. californiana and T. leysae sp. nov. , extensive nucleotide (4 nt) and amino acid (2 aa) exchanges are present within the molecular marker COI (Tab. 2). Tethya leysae sp. nov. also differs from T. aurantium in respect to cortex architecture, which is more massive and much more densely packed with megasters in the new species. In comparison to T. aurantium , the variance in relative ray length of the megasters is higher: while T. aurantium displays spherasters, T. leysae sp. nov. displays a range from spherasters to oxysherasters (compare data in Sarà & Melone 1965; Sarà et al. 1992). In addition to the morphological differences between T. aurantium and T. leysae sp. nov. , extensive nucleotide (52 nt) and amino acid (4 aa) exchanges are present within the molecular marker COI (Tab. 2). Tethya robusta seems to be the species with the most similar cortical architecture (Bowerbank 1873; Sarà & Sarà 2004), since in both species, megasters are so closely packed “that the rays of each pass between those of the adjoining ones, and the whole become, as it were, cemented into a solid mass” (Bowerbank 1873). However, the megasters in T. robusta display a much higher number of rays (24–32) than those of T. leysae sp. nov. Both species also differ in micraster types: T. leysae sp. nov. lacks the fine rayed oxyasters of T. robusta which in turn lacks the stout acanthoxyspherasters of T. leysae sp. nov. : Published as part of Heim, Isabel & Nickel, Michael, 2010, Description and molecular phylogeny of Tethya leysae sp. nov. (Porifera, Demospongiae, Hadromerida) from the Canadian Northeast Pacific with remarks on the use of microtomography in sponge taxonomy, pp. 1-21 in Zootaxa 2422 on pages 5-9, DOI: 10.5281/zenodo.194503 : {"references": ["Austin, B., Ott, B., McDaniel, N. & Romagosa, P. (1999 - 2007) An annotated checklist of marine invertebrates in the cold temperate northeast Pacific, Khoyatan Marine Laboratory. Available from: http: // www. mareco. org / KML / Projects / NEsponges. asp (12.6.2009).", "Bowerbank, J. S. (1873) Contributions to a General History of the Spongiadae. Part IV. Proceedings of the Zoological Society of London, 1873, 3 - 25, pls. I - IV.", "Sara, M. & Melone, N. (1965) Una nuova specie del genere Tethya, T. citrina sp. n. dal Mediterraneo (Porifera, Demospongiae). Atti della Societa Peloritana di Scienze fisiche matematiche e naturali, 11, 123 - 138.", "Sara, M., Bavestrello, G. & Mensi, P. (1992) Redescription of Tethya norvegica Bowerbank (Porifera, Demospongiae), with remarks on the genus Tethya in the North East Atlantic. Zoologica Scripta, 21, 211 - 216.", "Sara, M. & Sara, A. (2004) A revision of Australian and New Zealand Tethya (Porifera: Demospongiae) with a preliminary analysis of species grouping. Invertebrate Systematics, 18, 117 - 156."]}
format Text
author Heim, Isabel
Nickel, Michael
author_facet Heim, Isabel
Nickel, Michael
author_sort Heim, Isabel
title Tethya leysae Heim & Nickel, 2010, sp. nov.
title_short Tethya leysae Heim & Nickel, 2010, sp. nov.
title_full Tethya leysae Heim & Nickel, 2010, sp. nov.
title_fullStr Tethya leysae Heim & Nickel, 2010, sp. nov.
title_full_unstemmed Tethya leysae Heim & Nickel, 2010, sp. nov.
title_sort tethya leysae heim & nickel, 2010, sp. nov.
publisher Zenodo
publishDate 2010
url https://dx.doi.org/10.5281/zenodo.5696287
https://zenodo.org/record/5696287
long_lat ENVELOPE(-125.003,-125.003,54.000,54.000)
ENVELOPE(12.601,12.601,64.648,64.648)
geographic Austin
Canada
Pacific
New Zealand
British Columbia
Folmer
geographic_facet Austin
Canada
Pacific
New Zealand
British Columbia
Folmer
genre North East Atlantic
genre_facet North East Atlantic
op_relation http://publication.plazi.org/id/FFF02272FFCEFFEBFFC1AA0AFFDCFF98
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info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.5281/zenodo.5696287
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spelling ftdatacite:10.5281/zenodo.5696287 2023-05-15T17:39:04+02:00 Tethya leysae Heim & Nickel, 2010, sp. nov. Heim, Isabel Nickel, Michael 2010 https://dx.doi.org/10.5281/zenodo.5696287 https://zenodo.org/record/5696287 unknown Zenodo http://publication.plazi.org/id/FFF02272FFCEFFEBFFC1AA0AFFDCFF98 https://zenodo.org/communities/biosyslit https://dx.doi.org/10.5281/zenodo.194503 http://publication.plazi.org/id/FFF02272FFCEFFEBFFC1AA0AFFDCFF98 https://dx.doi.org/10.5281/zenodo.194504 https://dx.doi.org/10.5281/zenodo.194505 https://dx.doi.org/10.5281/zenodo.194506 https://dx.doi.org/10.5281/zenodo.194507 https://dx.doi.org/10.5281/zenodo.194508 https://dx.doi.org/10.5281/zenodo.194509 https://dx.doi.org/10.5281/zenodo.5696288 https://zenodo.org/communities/biosyslit Open Access info:eu-repo/semantics/openAccess Biodiversity Taxonomy Animalia Porifera Demospongiae Hadromerida Tethyidae Tethya Tethya leysae Taxonomic treatment article-journal Text ScholarlyArticle 2010 ftdatacite https://doi.org/10.5281/zenodo.5696287 https://doi.org/10.5281/zenodo.194503 https://doi.org/10.5281/zenodo.194504 https://doi.org/10.5281/zenodo.194505 https://doi.org/10.5281/zenodo.194506 https://doi.org/10.5281/zenodo.194507 https://doi.or 2022-02-08T13:42:09Z Tethya leysae sp. nov. Holotype: NHM 2009.5. 1.1, Leg. Sally P. Leys, 25.06. 2003. Paratype: PMJ Porif 287, Leg. Sally P. Leys, 27.09. 2006 Type locality: Rocky hard bottom substrate in the shallow Infralittoral (10 - 25 m depth) near Ohiat Islet, Northeast Pacific, Barkley Sound, Bamfield, Vancouver Island, British Columbia, Canada (Fig. 1), coordinates 48 ° 51 ’3.00’’ N, 51 ’ 3 ’’ 125 ° 11 ’60.00’’ W. Diagnosis. Tethya leysae sp. nov. is the only Tethya species in the NE Pacifc possessing a massive uniform cortex with few lacunae and densely packed megasters (oxyspherasters 41-115 µm; R/C 0.41), which are larger and display shorter rays compared to T. californiana . It also lacks the alveolar exocortex and the bilayered megastrer distribution typical for T. californiana Two categories of oxeas/strongyloxeas, both slightly larger/thicker than in T. californiana : main (1580-2540 µm x 18-53 µm) and auxiliary (490-1490 µm x 7–30), lacking tylostrongyles. Etymology. We have chosen the name in honor of Prof. Dr. Sally P. Leys, Edmonton, BC, Canada, who collected and kindly provided the type specimens and is an inspiring colleague and friend. Description. General body morphology. The body is spherical, with a diameter of 5 x 4 cm (holotype; Fig 2 A). Sections show an unambiguous division into a cortex region and a choanosomal core (Fig. 3 A). The colour in life is orange-yellow to light red (Fig. 2 C). The colour in alcohol is white, with a greyish core (Fig. 2 A). In living specimens, the body is slightly contractile. However, the overal body consistency is incompressible. The verrucose surface is frequently loaded lightly with sediment. The surface lacks tubercles, filaments and stalked buds (at least they have not been found in the examined material). The cortex is dense and compact, with 3-6 mm in thickness. It lacks lacunae, but is packed with megasters (Figs. 3 and 4). Skeletal morphology. The dense radiate bundles of main megascleres (oxeas and strongyloxeas) display diameters between 400–600 µm (see sections, Fig. 3 C, F; and microtomographic reconstructions, Fig. 4 A, B). The bundles terminate in compact cortical fans which are formed by the main and auxiliary megascleres and make up broad cortical tubercles (Figs. 3 B) which contribute to the external verrucose appearance. Groups of auxiliary megascleres are also present interstitially in the choanosome between the main bundles (Fig. 3 C). The megasters (spherasters/oxyspherasters) are evenly and densely scattered throughout the whole cortex (Figs. 3 B, 3 F, 4), but almost lacking in the peripheral 200–500 µm of the cortex (Fig. 3 D) and in some basal parts of the cortex near the cortical-choanosomal boundary (Fig. 3 E). Micrasters form a discrete layer allocated in the exopinacoderm surface (Fig. 3 D) and are most dense in the peripheral cortex. In addition, micrasters are evenly but sparsely distributed throughout the cortex and the choanosome. Spicules. The main megascleres are constituted by oxeas, anisostrongyles and strongyloxeas (Fig. 5), 1580–2540 µm (2049 ± 259 µm; n= 40) in length, 18–53 µm (34 ± 7 µm; n= 40) in diameter. Auxiliary megascleres are constituted by oxeas, anisostrongyles and strongyloxeas, 490–1490 µm (1055 ± 215 µm; n= 128) in length, 7–30 µm (19 ± 5 µm; n= 128) in diameter. Main and auxiliary megascleres form two significantly different length categories (independent t-test, p<0.001; Fig. 6 B), both of normal distribution (Kolmogorov-Smirnov test). The megasters are represented by spherasters to oxyspherasters of varying size and morphology, as evidenced by SEM and microtomography reconstructions (Figs. 5 B, C, 6 A and 7 C, Tab. 1). Cortical megasters (Fig. 5 B) display 8–20 rays and are 41–115 µm (84 ± 12 µm; n= 40) in diameter with R/Cs of 0.34– 0.69 (0.46 ± 0.07; n= 227). Choanosomal megasters (Fig. 5 C) display 12–18 rays and are 24–81 µm in diameter, with R/Cs of 0.25–0.81 (0.41 ± 0.1; n= 85). The form of the rays varies in both regions from slender to stout (Fig. 5 B, C). A Kolmogorov-Smirnov test (independent t-test, p<0.001) suggests that choanosomal oxyspherasters size is significantly smaller than in cortical megasters. Micrasters (Fig. 5 D) fall into four categories: acanthoxyspherasters (Fig 5 D, top left), 10–19 µm in diameter with 10–12 rays (the main category); acanthostrongylasters (Fig. 5 D, top middle) 8–18 µm in diameter, with 8–12 rays; a few acanthotylasters with only slight terminal knobs (Fig. 5 D, top right), 6–8 µm in diameter, with 10–14 slightly spinulated rays; and small oxyspherasters (Fig. 5 D, bottom), 4–10 µm in diameter, with 10–15 slender rays. Molecular characters. The nucleotide sequences of the cytochrome oxidase subunit I (Folmer fragment) are accessible in Genbank (holotype: GQ 292532; paratype: GQ 292533) and at www.spongebarcoding.org (record no. 222). The base pair exchanges in the COI fragment and the deduced amino acid sequences (Tab. 2) clearly distinguish T. leysae sp. nov. from T. californiana (4 nt/ 2 aa), T. minuta Sarà, Sarà, Nickel & Brümmer, 2001 (22 nt/ 3 aa) and T. actinia (18 nt/ 3 aa). Reproduction. Asexual reproduction by bud formation near the sponge surface is indicated (Fig. 2 C; asterisks). No data exist to date on the sexual reproduction of T. leysae sp. nov. Ecology. The type habitat at Barkley Sound is infralittoral hard bottom influenced by strong tidal changes such as regular periods of strong currents. Usually, T. leysae is found in aggregates of several specimens (presumably due to asexual reproduction by budding). Larger specimens of up to 8 cm diameter sometimes cluster in sheltered small canyons of wave exposed areas. Tethya leysae sp. nov. is most abundant in depths between 15–20 m with moderate water flow but no direct wave exposure or current. It usually lives in lighted conditions and on shaded rocks, but avoids dark habitats. Specimens of T. leysae sp. nov. are frequently found to be covered by debris which might be particulate organic matter, but also algae and other small epibionts like foraminifers. In some areas of Barkley Sound, it is the most obvious subtidal sponge. Other common sponges are Neopetrosia vanilla (de Laubenfels, 1930) and Cliona sp. (for a species list compare Austin et al. 1999 –2007). Distribution. At present, T. leysae sp. nov. has only been reported for its type locality Barkley Sound, near Bamfield, British Columbia, Canada. It is likely to occur more widely along the North American Pacific coast but its biogeographical limits are presently not known. Related species. Comparative morphology (general anatomy, skeleton structure, megasclere and microsclere sizes, forms and distribution) suggests that T. leysae sp. nov. might be closely related to T. aurantium , T. robusta (Bowerbank, 1873) and T. californiana . At present, T. californiana seems to be the only species which eventually occurs sympatrically. However, T. leysae sp. nov. can be clearly distinguished from T. californiana by the lack of an alveolar cortex and the extremely high density of megasters in the cortex. Another striking difference is the megaster morphology. Their R/C values differ significantly between T. californiana and T. leysae sp. nov. (Tab. 1) and the oxyspherasters of the latter rarely display bent rays. In addition, spherules have not been found among the micrasters of T. leysae sp. nov. However, this character can only be accessed by extensive and very careful study of spicule preparations. In addition to the morphological differences between T. californiana and T. leysae sp. nov. , extensive nucleotide (4 nt) and amino acid (2 aa) exchanges are present within the molecular marker COI (Tab. 2). Tethya leysae sp. nov. also differs from T. aurantium in respect to cortex architecture, which is more massive and much more densely packed with megasters in the new species. In comparison to T. aurantium , the variance in relative ray length of the megasters is higher: while T. aurantium displays spherasters, T. leysae sp. nov. displays a range from spherasters to oxysherasters (compare data in Sarà & Melone 1965; Sarà et al. 1992). In addition to the morphological differences between T. aurantium and T. leysae sp. nov. , extensive nucleotide (52 nt) and amino acid (4 aa) exchanges are present within the molecular marker COI (Tab. 2). Tethya robusta seems to be the species with the most similar cortical architecture (Bowerbank 1873; Sarà & Sarà 2004), since in both species, megasters are so closely packed “that the rays of each pass between those of the adjoining ones, and the whole become, as it were, cemented into a solid mass” (Bowerbank 1873). However, the megasters in T. robusta display a much higher number of rays (24–32) than those of T. leysae sp. nov. Both species also differ in micraster types: T. leysae sp. nov. lacks the fine rayed oxyasters of T. robusta which in turn lacks the stout acanthoxyspherasters of T. leysae sp. nov. : Published as part of Heim, Isabel & Nickel, Michael, 2010, Description and molecular phylogeny of Tethya leysae sp. nov. (Porifera, Demospongiae, Hadromerida) from the Canadian Northeast Pacific with remarks on the use of microtomography in sponge taxonomy, pp. 1-21 in Zootaxa 2422 on pages 5-9, DOI: 10.5281/zenodo.194503 : {"references": ["Austin, B., Ott, B., McDaniel, N. & Romagosa, P. (1999 - 2007) An annotated checklist of marine invertebrates in the cold temperate northeast Pacific, Khoyatan Marine Laboratory. Available from: http: // www. mareco. org / KML / Projects / NEsponges. asp (12.6.2009).", "Bowerbank, J. S. (1873) Contributions to a General History of the Spongiadae. Part IV. Proceedings of the Zoological Society of London, 1873, 3 - 25, pls. I - IV.", "Sara, M. & Melone, N. (1965) Una nuova specie del genere Tethya, T. citrina sp. n. dal Mediterraneo (Porifera, Demospongiae). Atti della Societa Peloritana di Scienze fisiche matematiche e naturali, 11, 123 - 138.", "Sara, M., Bavestrello, G. & Mensi, P. (1992) Redescription of Tethya norvegica Bowerbank (Porifera, Demospongiae), with remarks on the genus Tethya in the North East Atlantic. Zoologica Scripta, 21, 211 - 216.", "Sara, M. & Sara, A. (2004) A revision of Australian and New Zealand Tethya (Porifera: Demospongiae) with a preliminary analysis of species grouping. Invertebrate Systematics, 18, 117 - 156."]} Text North East Atlantic DataCite Metadata Store (German National Library of Science and Technology) Austin Canada Pacific New Zealand British Columbia ENVELOPE(-125.003,-125.003,54.000,54.000) Folmer ENVELOPE(12.601,12.601,64.648,64.648)