Farrea aspondyla Reiswig & Stone 2013, n. sp.

Farrea aspondyla n. sp. (Figs. 5 & 6, Table 3) Synonymy. Farrea kurilensis ssp. nov. Stone et al. , 2011: 16. Material examined. Holotype: USNM# 1196549, ROV ' Jason II' from RV ' Roger Revelle', dive J2099, 31 July 2004, Adak Canyon, 15.9 km SW of Cape Yakak, Adak Island, Al...

Full description

Bibliographic Details
Main Authors: Reiswig, Henry M., Stone, Robert P.
Format: Text
Language:unknown
Published: Zenodo 2013
Subjects:
Online Access:https://dx.doi.org/10.5281/zenodo.5261619
https://zenodo.org/record/5261619
id ftdatacite:10.5281/zenodo.5261619
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
Hexactinellida
Sceptrulophora
Farreidae
Farrea
Farrea aspondyla
spellingShingle Biodiversity
Taxonomy
Animalia
Porifera
Hexactinellida
Sceptrulophora
Farreidae
Farrea
Farrea aspondyla
Reiswig, Henry M.
Stone, Robert P.
Farrea aspondyla Reiswig & Stone 2013, n. sp.
topic_facet Biodiversity
Taxonomy
Animalia
Porifera
Hexactinellida
Sceptrulophora
Farreidae
Farrea
Farrea aspondyla
description Farrea aspondyla n. sp. (Figs. 5 & 6, Table 3) Synonymy. Farrea kurilensis ssp. nov. Stone et al. , 2011: 16. Material examined. Holotype: USNM# 1196549, ROV ' Jason II' from RV ' Roger Revelle', dive J2099, 31 July 2004, Adak Canyon, 15.9 km SW of Cape Yakak, Adak Island, Aleutian Islands, 51º28.091'N, 177º03.055'W, 2105 m, partial, dry & ethanol. Comparative material examined. Farrea kurilensis Okada, 1932, holotype, USNM 22034, USFS ' Albatross', stn 4804, SE of Shimushir Island, Kurile Islands, 24 June 1906, 46º42'N, 151º47'E, 419 m; Farrea beringiana Okada, 1932, holotype, USNM 22037, USFS ' Albatross', stn 4790, Cape Monati, Bering Island, Bering Sea, 14 June 1906, 54º38'45"N, 167º11'45"E, 117 m; Farrea kurilensis , BMNH 1938.07.04.119 (from Zoological Institute of the Academy of Sciences, Leningrad), stn 248, Sea of Okhotsk, other data unavailable. Description. The new species holotype consists of over 100 fragments, the largest being 80 mm long, from a stock of very tightly branching and anastomosing tubes, with internode length less than or about the same as tube diameter, hence appearing nearly lettuce-like, with individual tubular components difficult to distinguish (Figs. 5A, B). Apertures of tube openings on the outer surface are 22±3 (20–28; 6) mm; wall thickness is 2.0±0.4 (1.5–2.5; 10) mm. The color of the preserved fragments is white. Both inner and outer surfaces are smooth, without channelization (Fig. 5B). The skeletal framework is a typical farreoid dictyonal type easily seen by naked eye (Fig. 5C), with smooth beams (Figs. 5D, E). Dictyonalia are mainly restricted to a single layer but a second layer may occasionally be added on the dermal side. Meshes are mostly rectangular, approximately square, so longitudinal and transverse beam lengths do not differ. Spurs are rough, tapered to a fine point, and usually gently curved downstream (to exhalant flow; Figs. 5E, F), but in many areas they project directly perpendicular to the plane of the framework without curvature. Framework measurements are given at the top of Table 3. Megascleres are pentactins, regular hexactins, anchorate clavules and uncinates (dimensions given in Table 3). The pentactins (Fig. 6A) of dermal and atrial surfaces are regularly cruciate and indistinguishable; all rays are straight, slightly tapered, finely rough (moderately dense microspines), and end in abruptly pointed tips. A short rudiment represents an undeveloped sixth (distal) ray; its length is generally less than twice its width and the spicules are here considered to be pentactins. Regular hexactins (Fig. 6B) occur as parenchymal spicules with rays similar to those of the surface pentactins; they are too rare to provide data for Table 3 but the one figured has rays 227 µm long by 11.2 µm thick. Anchorate clavules (Figs. 6C–F) occur on both surfaces; their caps have a small central prominence, raised to varying degrees and often with a few coarse spines; the 3–10, 23–93 µm long marginal spines projecting backwards are rarely straight and more commonly flared outwards or s-shaped. Outer surfaces are mostly smooth, but spines occur across the cap and on the distal spines of some clavules. Darkened surfaces on outer and inner surfaces of some caps (Figs. 6E–F) appear due to incomplete silicification where the nanospherular silica is seen at higher magnification. The shafts are straight, robust and smooth, ending in blunt parabolic tips without inflation; large shaft spines are absent. Uncinates are of moderate size but thin (Fig. 6G); barbs and brackets are well developed in the middle and barbs are moderately inclined from the spicule surface. Microscleres consist of only stellate discohexasters of two distinct size and form classes (dimensions given in Table 3). Both are entirely rough and bear terminal discs with 4–7 marginal teeth. The smaller, more abundant discohexasters (Fig. 6I) generally have long primary rays bearing 3–7 shorter secondary rays, usually bundled very tightly together, but many are slightly flared at the tips and some flare outwards directly from their insertion on the primary ray. The larger discohexasters (Fig. 6H) have relatively shorter primary rays that bear 6–8 long straight secondary rays. The bases of the secondary rays are fused for a short distance forming a calyx-like base. Most of the discohexasters are easily assigned to these two classes, but a few intermediates occur as verified by a plot of spicule diameter vs 1º ray length/2º ray length (not shown). Etymology. The species name, aspondyla , reflects the absence of spines on the clavule shafts. Remarks: The new Aleutian Islands specimen is clearly closely related to F. kurilensis Okada, 1932 based on the shared characteristic shape of its anchorate clavules as well as the form of its dermal and atrial pentactins. It differs from F. k. forma kurilensis Okada, 1932, as modified by Koltun (1967), in the larger caliber of its tubular body components (22 vs. 10 mm diameter in the latter), lack of pileate clavules, complete absence of shaft spines on its anchorate clavules, absence of oxyhexaster microscleres (the dominant microsclere of the latter), and presence of a large class of discohexasters (absent in the latter). It differs from F. k. forma beringiana , Okada, 1932, as modified by Koltun (1967), in absence of pileate clavules (although these were absent in Okada's original Bering Sea specimen), absence of shaft spines on the anchorate clavules, and presence of a much larger class of discohexasters (91–293 vs. 80–150 µm diameter in the latter) with calyx-like fusion of the secondary ray bases. Koltun (1967) noted, after examination of seven previously unreported specimens, that F. kurilensis is a polymorphous species but he still maintained distinction between the two forms, now considered subspecies (Reiswig 2002). Other species of Farrea with only anchorate clavules include F. aculeata Schulze, 1899, from Oregon and F. campossinus Lopes et al., 2011 from Brazil; both differ from Farrea aspondyla n. sp. in having their main microsclere as oxyhexasters. The special characters of the new Aleutian Islands form, absence of pileate clavules, absence of shaft spines on anchorate clavules, and presence of a very large class of stellate discohexasters with calyx-like secondary ray bases, are here considered sufficient evidence for genetic isolation and its recognition as a new species, Farrea aspondyla . Review of all video footage collected with the ROV 'Jason II' indicates that this is a common species, locally abundant in some areas and occurring on bedrock, mudstone, boulders, cobbles, and other hexactinellid skeletons at depths between 1887 and 2249 m (likely much shallower but difficult to determine due to presence of conspecifics from which it cannot always be distinguished in situ ). When encountered in situ , the majid crab Chionoecetes angulatus was using the sponge as cover; other associated fauna include juvenile crabs ( Paralomis and Lithodes spp.). The skeleton of this and other Farrea spp. provide important substrate for gorgonian corals (Primnoidae and Acanthogorgia sp.). : Published as part of Reiswig, Henry M. & Stone, Robert P., 2013, New glass sponges (Porifera: Hexactinellida) from deep waters of the central Aleutian Islands, Alaska , pp. 1-64 in Zootaxa 3628 (1) on pages 11-15, DOI: 10.11646/zootaxa.3628.1.1, http://zenodo.org/record/5261270 : {"references": ["Stone, R. P., Lehnert, H. & Reiswig, H. M. (2011) A guide to the deep-water sponges of the Aleutian Island Archipelago. NOAA Professional Paper NMFS, 12, 1 - 187.", "Okada, Y. (1932) Report on the hexactinellid sponges collected by the United States Fisheries steamer ' Albatross' in the northwestern Pacific during the summer of 1906. Proceedings of the United States National Museum, 81 (2935), 1 - 118, pls 1 - 6. http: // dx. doi. org / 10.5479 / si. 00963801.81 - 2935.1", "Koltun, V. M. (1967) Glass, or hexactinellid sponges of the northern and far-eastern seas of the USSR (Class Hyalospongiae). [In Russian]. Opredeliteli po faune SSR, izdavaemye Zoologicheskim muzeem Akademii nauk, 94, 1 - 124.", "Reiswig, H. M. (2002) Farreidae Gray, 1872. In: Hooper, J. N. A. & van Soest, R. W. M. (Eds.), Systema Porifera: A Guide to the Classification of Sponges. Plenum, New York, pp. 1332 - 1340.", "Schulze, F. E. (1899) Amerikanische Hexactinelliden, nach dem Materiale der Albatross-Expedition. Fischer, Jena. 126 pp, 19 pls.", "Lopes, D. A., Hajdu, E. & Reiswig, H. M. (2011) Taxonomy of Farrea (Porifera, Hexactinellida, Hexactinosida) from the southwestern Atlantic, with description of a new species and a discussion on the recognition of subspecies in Porifera. Canadian Journal of Zoology, 89, 169 - 189. http: // dx. doi. org / 10.1139 / Z 10 - 105"]}
format Text
author Reiswig, Henry M.
Stone, Robert P.
author_facet Reiswig, Henry M.
Stone, Robert P.
author_sort Reiswig, Henry M.
title Farrea aspondyla Reiswig & Stone 2013, n. sp.
title_short Farrea aspondyla Reiswig & Stone 2013, n. sp.
title_full Farrea aspondyla Reiswig & Stone 2013, n. sp.
title_fullStr Farrea aspondyla Reiswig & Stone 2013, n. sp.
title_full_unstemmed Farrea aspondyla Reiswig & Stone 2013, n. sp.
title_sort farrea aspondyla reiswig & stone 2013, n. sp.
publisher Zenodo
publishDate 2013
url https://dx.doi.org/10.5281/zenodo.5261619
https://zenodo.org/record/5261619
long_lat ENVELOPE(59.561,59.561,66.502,66.502)
ENVELOPE(-177.083,-177.083,51.417,51.417)
geographic Bering Sea
Okhotsk
Pacific
Adak
Adak Canyon
geographic_facet Bering Sea
Okhotsk
Pacific
Adak
Adak Canyon
genre Aleutian Island
Archipelago
Bering Island
Bering Sea
Alaska
Aleutian Islands
Glass sponges
genre_facet Aleutian Island
Archipelago
Bering Island
Bering Sea
Alaska
Aleutian Islands
Glass sponges
op_relation http://zenodo.org/record/5261270
http://publication.plazi.org/id/FFEBFFCAFFB836299A40FF842E67FFFC
http://zoobank.org/37D2D7F2-FA0C-40E9-B6D0-9C74EBB6C7F0
https://zenodo.org/communities/biosyslit
https://dx.doi.org/10.11646/zootaxa.3628.1.1
http://zenodo.org/record/5261270
http://publication.plazi.org/id/FFEBFFCAFFB836299A40FF842E67FFFC
https://dx.doi.org/10.5281/zenodo.5261280
https://dx.doi.org/10.5281/zenodo.5261282
http://zoobank.org/37D2D7F2-FA0C-40E9-B6D0-9C74EBB6C7F0
https://dx.doi.org/10.5281/zenodo.5261620
https://zenodo.org/communities/biosyslit
op_rights Open Access
info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.5281/zenodo.5261619
https://doi.org/10.11646/zootaxa.3628.1.1
https://doi.org/10.5281/zenodo.5261280
https://doi.org/10.5281/zenodo.5261282
https://doi.org/10.5281/zenodo.5261620
_version_ 1766265605346820096
spelling ftdatacite:10.5281/zenodo.5261619 2023-05-15T13:14:49+02:00 Farrea aspondyla Reiswig & Stone 2013, n. sp. Reiswig, Henry M. Stone, Robert P. 2013 https://dx.doi.org/10.5281/zenodo.5261619 https://zenodo.org/record/5261619 unknown Zenodo http://zenodo.org/record/5261270 http://publication.plazi.org/id/FFEBFFCAFFB836299A40FF842E67FFFC http://zoobank.org/37D2D7F2-FA0C-40E9-B6D0-9C74EBB6C7F0 https://zenodo.org/communities/biosyslit https://dx.doi.org/10.11646/zootaxa.3628.1.1 http://zenodo.org/record/5261270 http://publication.plazi.org/id/FFEBFFCAFFB836299A40FF842E67FFFC https://dx.doi.org/10.5281/zenodo.5261280 https://dx.doi.org/10.5281/zenodo.5261282 http://zoobank.org/37D2D7F2-FA0C-40E9-B6D0-9C74EBB6C7F0 https://dx.doi.org/10.5281/zenodo.5261620 https://zenodo.org/communities/biosyslit Open Access info:eu-repo/semantics/openAccess Biodiversity Taxonomy Animalia Porifera Hexactinellida Sceptrulophora Farreidae Farrea Farrea aspondyla Text Taxonomic treatment article-journal ScholarlyArticle 2013 ftdatacite https://doi.org/10.5281/zenodo.5261619 https://doi.org/10.11646/zootaxa.3628.1.1 https://doi.org/10.5281/zenodo.5261280 https://doi.org/10.5281/zenodo.5261282 https://doi.org/10.5281/zenodo.5261620 2021-11-05T12:55:41Z Farrea aspondyla n. sp. (Figs. 5 & 6, Table 3) Synonymy. Farrea kurilensis ssp. nov. Stone et al. , 2011: 16. Material examined. Holotype: USNM# 1196549, ROV ' Jason II' from RV ' Roger Revelle', dive J2099, 31 July 2004, Adak Canyon, 15.9 km SW of Cape Yakak, Adak Island, Aleutian Islands, 51º28.091'N, 177º03.055'W, 2105 m, partial, dry & ethanol. Comparative material examined. Farrea kurilensis Okada, 1932, holotype, USNM 22034, USFS ' Albatross', stn 4804, SE of Shimushir Island, Kurile Islands, 24 June 1906, 46º42'N, 151º47'E, 419 m; Farrea beringiana Okada, 1932, holotype, USNM 22037, USFS ' Albatross', stn 4790, Cape Monati, Bering Island, Bering Sea, 14 June 1906, 54º38'45"N, 167º11'45"E, 117 m; Farrea kurilensis , BMNH 1938.07.04.119 (from Zoological Institute of the Academy of Sciences, Leningrad), stn 248, Sea of Okhotsk, other data unavailable. Description. The new species holotype consists of over 100 fragments, the largest being 80 mm long, from a stock of very tightly branching and anastomosing tubes, with internode length less than or about the same as tube diameter, hence appearing nearly lettuce-like, with individual tubular components difficult to distinguish (Figs. 5A, B). Apertures of tube openings on the outer surface are 22±3 (20–28; 6) mm; wall thickness is 2.0±0.4 (1.5–2.5; 10) mm. The color of the preserved fragments is white. Both inner and outer surfaces are smooth, without channelization (Fig. 5B). The skeletal framework is a typical farreoid dictyonal type easily seen by naked eye (Fig. 5C), with smooth beams (Figs. 5D, E). Dictyonalia are mainly restricted to a single layer but a second layer may occasionally be added on the dermal side. Meshes are mostly rectangular, approximately square, so longitudinal and transverse beam lengths do not differ. Spurs are rough, tapered to a fine point, and usually gently curved downstream (to exhalant flow; Figs. 5E, F), but in many areas they project directly perpendicular to the plane of the framework without curvature. Framework measurements are given at the top of Table 3. Megascleres are pentactins, regular hexactins, anchorate clavules and uncinates (dimensions given in Table 3). The pentactins (Fig. 6A) of dermal and atrial surfaces are regularly cruciate and indistinguishable; all rays are straight, slightly tapered, finely rough (moderately dense microspines), and end in abruptly pointed tips. A short rudiment represents an undeveloped sixth (distal) ray; its length is generally less than twice its width and the spicules are here considered to be pentactins. Regular hexactins (Fig. 6B) occur as parenchymal spicules with rays similar to those of the surface pentactins; they are too rare to provide data for Table 3 but the one figured has rays 227 µm long by 11.2 µm thick. Anchorate clavules (Figs. 6C–F) occur on both surfaces; their caps have a small central prominence, raised to varying degrees and often with a few coarse spines; the 3–10, 23–93 µm long marginal spines projecting backwards are rarely straight and more commonly flared outwards or s-shaped. Outer surfaces are mostly smooth, but spines occur across the cap and on the distal spines of some clavules. Darkened surfaces on outer and inner surfaces of some caps (Figs. 6E–F) appear due to incomplete silicification where the nanospherular silica is seen at higher magnification. The shafts are straight, robust and smooth, ending in blunt parabolic tips without inflation; large shaft spines are absent. Uncinates are of moderate size but thin (Fig. 6G); barbs and brackets are well developed in the middle and barbs are moderately inclined from the spicule surface. Microscleres consist of only stellate discohexasters of two distinct size and form classes (dimensions given in Table 3). Both are entirely rough and bear terminal discs with 4–7 marginal teeth. The smaller, more abundant discohexasters (Fig. 6I) generally have long primary rays bearing 3–7 shorter secondary rays, usually bundled very tightly together, but many are slightly flared at the tips and some flare outwards directly from their insertion on the primary ray. The larger discohexasters (Fig. 6H) have relatively shorter primary rays that bear 6–8 long straight secondary rays. The bases of the secondary rays are fused for a short distance forming a calyx-like base. Most of the discohexasters are easily assigned to these two classes, but a few intermediates occur as verified by a plot of spicule diameter vs 1º ray length/2º ray length (not shown). Etymology. The species name, aspondyla , reflects the absence of spines on the clavule shafts. Remarks: The new Aleutian Islands specimen is clearly closely related to F. kurilensis Okada, 1932 based on the shared characteristic shape of its anchorate clavules as well as the form of its dermal and atrial pentactins. It differs from F. k. forma kurilensis Okada, 1932, as modified by Koltun (1967), in the larger caliber of its tubular body components (22 vs. 10 mm diameter in the latter), lack of pileate clavules, complete absence of shaft spines on its anchorate clavules, absence of oxyhexaster microscleres (the dominant microsclere of the latter), and presence of a large class of discohexasters (absent in the latter). It differs from F. k. forma beringiana , Okada, 1932, as modified by Koltun (1967), in absence of pileate clavules (although these were absent in Okada's original Bering Sea specimen), absence of shaft spines on the anchorate clavules, and presence of a much larger class of discohexasters (91–293 vs. 80–150 µm diameter in the latter) with calyx-like fusion of the secondary ray bases. Koltun (1967) noted, after examination of seven previously unreported specimens, that F. kurilensis is a polymorphous species but he still maintained distinction between the two forms, now considered subspecies (Reiswig 2002). Other species of Farrea with only anchorate clavules include F. aculeata Schulze, 1899, from Oregon and F. campossinus Lopes et al., 2011 from Brazil; both differ from Farrea aspondyla n. sp. in having their main microsclere as oxyhexasters. The special characters of the new Aleutian Islands form, absence of pileate clavules, absence of shaft spines on anchorate clavules, and presence of a very large class of stellate discohexasters with calyx-like secondary ray bases, are here considered sufficient evidence for genetic isolation and its recognition as a new species, Farrea aspondyla . Review of all video footage collected with the ROV 'Jason II' indicates that this is a common species, locally abundant in some areas and occurring on bedrock, mudstone, boulders, cobbles, and other hexactinellid skeletons at depths between 1887 and 2249 m (likely much shallower but difficult to determine due to presence of conspecifics from which it cannot always be distinguished in situ ). When encountered in situ , the majid crab Chionoecetes angulatus was using the sponge as cover; other associated fauna include juvenile crabs ( Paralomis and Lithodes spp.). The skeleton of this and other Farrea spp. provide important substrate for gorgonian corals (Primnoidae and Acanthogorgia sp.). : Published as part of Reiswig, Henry M. & Stone, Robert P., 2013, New glass sponges (Porifera: Hexactinellida) from deep waters of the central Aleutian Islands, Alaska , pp. 1-64 in Zootaxa 3628 (1) on pages 11-15, DOI: 10.11646/zootaxa.3628.1.1, http://zenodo.org/record/5261270 : {"references": ["Stone, R. P., Lehnert, H. & Reiswig, H. M. (2011) A guide to the deep-water sponges of the Aleutian Island Archipelago. NOAA Professional Paper NMFS, 12, 1 - 187.", "Okada, Y. (1932) Report on the hexactinellid sponges collected by the United States Fisheries steamer ' Albatross' in the northwestern Pacific during the summer of 1906. Proceedings of the United States National Museum, 81 (2935), 1 - 118, pls 1 - 6. http: // dx. doi. org / 10.5479 / si. 00963801.81 - 2935.1", "Koltun, V. M. (1967) Glass, or hexactinellid sponges of the northern and far-eastern seas of the USSR (Class Hyalospongiae). [In Russian]. Opredeliteli po faune SSR, izdavaemye Zoologicheskim muzeem Akademii nauk, 94, 1 - 124.", "Reiswig, H. M. (2002) Farreidae Gray, 1872. In: Hooper, J. N. A. & van Soest, R. W. M. (Eds.), Systema Porifera: A Guide to the Classification of Sponges. Plenum, New York, pp. 1332 - 1340.", "Schulze, F. E. (1899) Amerikanische Hexactinelliden, nach dem Materiale der Albatross-Expedition. Fischer, Jena. 126 pp, 19 pls.", "Lopes, D. A., Hajdu, E. & Reiswig, H. M. (2011) Taxonomy of Farrea (Porifera, Hexactinellida, Hexactinosida) from the southwestern Atlantic, with description of a new species and a discussion on the recognition of subspecies in Porifera. Canadian Journal of Zoology, 89, 169 - 189. http: // dx. doi. org / 10.1139 / Z 10 - 105"]} Text Aleutian Island Archipelago Bering Island Bering Sea Alaska Aleutian Islands Glass sponges DataCite Metadata Store (German National Library of Science and Technology) Bering Sea Okhotsk Pacific Adak ENVELOPE(59.561,59.561,66.502,66.502) Adak Canyon ENVELOPE(-177.083,-177.083,51.417,51.417)