Aulosaccus schulzei Ijima. The 1896

Aulosaccus schulzei Ijima, 1896 (Figs. 14 & 15, Table 7) Synonymy. Aulosaccus schulzei Ijima, 1896: 252; 1898: 51; 1904: 110; Koltun 1967: 68; Tabachnick 2002: 1447; Lee et al. 2007: K257; Stone et al. 2011: 33. Aulosaccus albatrossi Okada, 1932:78; Koltun 1967: 68. Material examined. USNM# 1196...

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Bibliographic Details
Main Authors: Reiswig, Henry M., Stone, Robert P.
Format: Text
Language:unknown
Published: Zenodo 2013
Subjects:
Biodiversity
Taxonomy
Animalia
Porifera
Hexactinellida
Lyssacinosida
Rossellidae
Aulosaccus
Aulosaccus schulzei
Kamchatka Peninsula
Okhotsk
Pacific
Aleutian Island
Archipelago
Kamchatka
okhotsk sea
Alaska
Aleutian Islands
Glass sponges
Online Access:https://dx.doi.org/10.5281/zenodo.5261625
https://zenodo.org/record/5261625
id ftdatacite:10.5281/zenodo.5261625
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
Lyssacinosida
Rossellidae
Aulosaccus
Aulosaccus schulzei
spellingShingle Biodiversity
Taxonomy
Animalia
Porifera
Hexactinellida
Lyssacinosida
Rossellidae
Aulosaccus
Aulosaccus schulzei
Reiswig, Henry M.
Stone, Robert P.
Aulosaccus schulzei Ijima. The 1896
topic_facet Biodiversity
Taxonomy
Animalia
Porifera
Hexactinellida
Lyssacinosida
Rossellidae
Aulosaccus
Aulosaccus schulzei
description Aulosaccus schulzei Ijima, 1896 (Figs. 14 & 15, Table 7) Synonymy. Aulosaccus schulzei Ijima, 1896: 252; 1898: 51; 1904: 110; Koltun 1967: 68; Tabachnick 2002: 1447; Lee et al. 2007: K257; Stone et al. 2011: 33. Aulosaccus albatrossi Okada, 1932:78; Koltun 1967: 68. Material examined. USNM# 1196554, ROV ' Jason II' from RV ' Roger Revelle', dive J2105, 06 August 2004, 4.5 km W of Cape Sajaka, Tanaga Island, Aleutian Islands, Alaska, 51º52.021'N, 178º17.720'W, 1320 m, 1 partial specimen attached to cobble, dry & ethanol. Comparative material examined. A. schulzei holotype, MCZ 10004, Sagami Bay, Japan, prior to 1896, dry. A. albatrossi holotype, USNM 22111, USFS 'Albatross' stn 4797, 20 June 1906, Staritschkof Island off South Kamchatka Peninsula, 52˚37.8'N, 158˚49.8'E, 1248 m, ethanol Description. The collected fragment is the top quarter of a slightly flattened sac, 53 cm long by 25 cm diameter, with large flared oscular margin (Figs. 14A, B); dimensions of the fragment (Fig. 14C) are 135 mm tall, 110 mm wide, and 34 mm in wall thickness in the middle. All surfaces are smooth, without prostalia, veil, or conules. The oscular margin is thin and without marginalia. The dermal surface has visible strands of hypodermal pentactins and diactins, oriented in all directions, forming a subsurface network supporting the dermal spicule lattice and obscuring the apertures of the subdermal inhalant canals (Figs. 14C, D). The dermal lattice (Figs. 14D, E) is a rectangular meshwork with mean side length of 122 µm, composed of about equal numbers of hexactins, pentactins, and stauractins. The atrial surface has openings of exhalant canals generally visible through the less regularly organized atrial lattice (Fig. 14F). Meshes of the atrial lattice, composed mainly of hexactins with a few stauractins and pentactins, are not rectangular and microscleres, not present in the dermal lattice, make up a significant component of this structure. The main supporting skeleton is a network of loose interwoven unfused diactins occurring in bundles or singly and oriented without order. Spicule fusion probably occurs only in the basidictyonal skeleton, not collected. Within the moderately firm surface layers, the main parenchyma is cavernous, resulting in a very soft overall body texture. Color of the fresh specimen was white; when preserved in ethanol or dried it is light brown. Megascleres: (spicule dimensions are given in Table 7). Hypodermal pentactins (Fig. 15A), and a very few triactins and irregular tetractins, are mostly crucial, rarely semi-paratropal, and smooth, with long tapered rays ending in rough sharp tips. Their tangential rays are bundled with thick and thin diactins to form primary support for hexactine dermalia. Dermalia (Fig. 15B) are entirely rough spicules with cylindric rays ending in rounded and sometimes inflated tips; 37% are hexactins, 31% pentactins, and 32% stauractins. Hexactins are distributed mainly over the hypodermal strands, pentactins at edges of strands, and stauractins over the unsupported middle of the larger lattice fields. Atrialia are composed of the same three spicule types (Fig. 15C), but they are larger than dermalia, tend to have elongate proximal rays in pentactins and one axis elongate in hexactins. Parenchymal megascleres are all diactins, including thick principal diactins (Fig. 15D) and thin intermediate and comital diactins (Fig. 15E). Thick principal diactins are slightly curved, generally smooth, with no medial swelling and rough rounded or parabolic tips. Thin diactins are straight to sinuous, generally smooth with a significant medial swelling and rough parabolic tips. Short straight diactins (Fig. 15F) are associated with only the atrial surfaces. µm unless otherwise indicated). Microscleres consist of immense discasters, also known as solasters, hemioxyhexasters, oxyhexactins and variants, and microdiscohexasters. The subdermal solasters (Fig. 15G) are derived discohexasters with centrum expanded to a solid sphere, entirely enclosing the primary rays. Terminal rays emanating directly from the centrum are unequal in length, ornamented with short reclined barbs, and end in marginally toothed discs. Oxy-tipped microscleres (Fig. 15H) are very thin and mainly associated with the atrial skeleton; they include regular oxyhexactins, hemioxyhexasters and an array of forms with reduced ray numbers—2, 3, 4, 5 developed rays—but never complete oxyhexasters. They are all rough, all terminal rays ornamented with reclined spines. Many have sharp bends at the end of the primary rays, with one or two developed rays and a short spur emanating from that point; compact spiral variants are rare. Microdiscohexasters (Fig. 15I) are very rare and associated with both surface skeletons. They have short, thick, smooth primary rays, each of which supports 5–10 spined, irregularly sinuous terminal rays ending in very small discs with recurved marginal teeth. Remarks. This species is widely distributed in the N Pacific, from Sagami Bay, Japan through the Kurile Islands and the Okhotsk Sea (Tabachnick, 2002) and has recently been reported from Central California (Lee et al . 2007). Our discovery of A. schulzei in Alaska is not surprising, but it represents a considerable range extension of ca 2,000 km from its nearest previously reported occurrence in the Okhotsk Sea. The new Aleutian Islands specimen agrees in virtually all details with the holotype specimen from Sagami Bay, Japan. In reviewing other possible assignments of this specimen, we discovered that there are no significant differences between A. albatrossi Okada, 1932 from off S Kamchatka Peninsula, and A. schulzei . In his description of A. albatrossi , Okada described its macrodiscohexasters (not figured) as 250–650 µm in diameter (we found 409–592–788 µm, n = 8, in the holotype), terminal rays as smooth with conically convex discs (we found terminal rays rough with hemispheric discs), and two size classes of microdiscohexasters of 32–40 and 50–56 µm diameters (we found one class, 23–34–42 µm, n = 127). Okada's description of A. albatrossi is, like many of his other descriptions, clearly unreliable and almost all reputed differences between the species evaporate when the holotypes are directly compared. Maximum size of macrodiscohexasters (solasters) is quite variable between specimens of the same species and is not alone considered a sufficient basis for distinguishing between species. We thus propose A. albatrossi Okada to be recognized as a junior synonym of A. schulzei Ijima. The description here of the Aleutian Islands specimen is the first documentation of A. schulzei spicule forms with SEM. Review of all video footage collected with the ROV 'Jason II' indicates that it is a rare species occurring singly on bedrock, boulders, and cobbles at depths between 1270 and 1350 m. Associated fauna include juvenile lithodid crabs ( Paralomis verrilli and Lithodes couesi ), pandalid shrimps, and the large ophiuroid Gorgonocephalus eucnemis . : 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 29-33, DOI: 10.11646/zootaxa.3628.1.1, http://zenodo.org/record/5261270 : {"references": ["Ijima, I. (1896) Notice of new Hexactinellida from Sagami Bay. Zoologischer Anzeiger, 19 (504), 249 - 254.", "Ijima, I. (1898) The genera and species of Rossellidae. Annotationes zoologicae japonenses, 2 (2), 41 - 55.", "Ijima, I. (1904) Studies on the Hexactinellida. Contribution IV. (Rossellidae). Journal of the College of Sciences, Imperial University of Tokyo, 18 (7), 1 - 307, pls I - XXIII.", "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.", "Lee, W. L., Elvin, D. W., & Reiswig, H. M. (2007) The Sponges of California: A Guide and Key to the Marine Sponges of California. Monterey Bay National Marine Sanctuary Foundation, Monterey, California, x + 395 pp.", "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"]}
format Text
author Reiswig, Henry M.
Stone, Robert P.
author_facet Reiswig, Henry M.
Stone, Robert P.
author_sort Reiswig, Henry M.
title Aulosaccus schulzei Ijima. The 1896
title_short Aulosaccus schulzei Ijima. The 1896
title_full Aulosaccus schulzei Ijima. The 1896
title_fullStr Aulosaccus schulzei Ijima. The 1896
title_full_unstemmed Aulosaccus schulzei Ijima. The 1896
title_sort aulosaccus schulzei ijima. the 1896
publisher Zenodo
publishDate 2013
url https://dx.doi.org/10.5281/zenodo.5261625
https://zenodo.org/record/5261625
long_lat ENVELOPE(160.000,160.000,56.000,56.000)
geographic Kamchatka Peninsula
Okhotsk
Pacific
geographic_facet Kamchatka Peninsula
Okhotsk
Pacific
genre Aleutian Island
Archipelago
Kamchatka
Kamchatka Peninsula
okhotsk sea
Alaska
Aleutian Islands
Glass sponges
genre_facet Aleutian Island
Archipelago
Kamchatka
Kamchatka Peninsula
okhotsk sea
Alaska
Aleutian Islands
Glass sponges
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op_doi https://doi.org/10.5281/zenodo.5261625
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spelling ftdatacite:10.5281/zenodo.5261625 2023-05-15T13:14:49+02:00 Aulosaccus schulzei Ijima. The 1896 Reiswig, Henry M. Stone, Robert P. 2013 https://dx.doi.org/10.5281/zenodo.5261625 https://zenodo.org/record/5261625 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.5261298 https://dx.doi.org/10.5281/zenodo.5261300 http://zoobank.org/37D2D7F2-FA0C-40E9-B6D0-9C74EBB6C7F0 https://dx.doi.org/10.5281/zenodo.5261626 https://zenodo.org/communities/biosyslit Open Access info:eu-repo/semantics/openAccess Biodiversity Taxonomy Animalia Porifera Hexactinellida Lyssacinosida Rossellidae Aulosaccus Aulosaccus schulzei Text Taxonomic treatment article-journal ScholarlyArticle 2013 ftdatacite https://doi.org/10.5281/zenodo.5261625 https://doi.org/10.11646/zootaxa.3628.1.1 https://doi.org/10.5281/zenodo.5261298 https://doi.org/10.5281/zenodo.5261300 https://doi.org/10.5281/zenodo.5261626 2021-11-05T12:55:41Z Aulosaccus schulzei Ijima, 1896 (Figs. 14 & 15, Table 7) Synonymy. Aulosaccus schulzei Ijima, 1896: 252; 1898: 51; 1904: 110; Koltun 1967: 68; Tabachnick 2002: 1447; Lee et al. 2007: K257; Stone et al. 2011: 33. Aulosaccus albatrossi Okada, 1932:78; Koltun 1967: 68. Material examined. USNM# 1196554, ROV ' Jason II' from RV ' Roger Revelle', dive J2105, 06 August 2004, 4.5 km W of Cape Sajaka, Tanaga Island, Aleutian Islands, Alaska, 51º52.021'N, 178º17.720'W, 1320 m, 1 partial specimen attached to cobble, dry & ethanol. Comparative material examined. A. schulzei holotype, MCZ 10004, Sagami Bay, Japan, prior to 1896, dry. A. albatrossi holotype, USNM 22111, USFS 'Albatross' stn 4797, 20 June 1906, Staritschkof Island off South Kamchatka Peninsula, 52˚37.8'N, 158˚49.8'E, 1248 m, ethanol Description. The collected fragment is the top quarter of a slightly flattened sac, 53 cm long by 25 cm diameter, with large flared oscular margin (Figs. 14A, B); dimensions of the fragment (Fig. 14C) are 135 mm tall, 110 mm wide, and 34 mm in wall thickness in the middle. All surfaces are smooth, without prostalia, veil, or conules. The oscular margin is thin and without marginalia. The dermal surface has visible strands of hypodermal pentactins and diactins, oriented in all directions, forming a subsurface network supporting the dermal spicule lattice and obscuring the apertures of the subdermal inhalant canals (Figs. 14C, D). The dermal lattice (Figs. 14D, E) is a rectangular meshwork with mean side length of 122 µm, composed of about equal numbers of hexactins, pentactins, and stauractins. The atrial surface has openings of exhalant canals generally visible through the less regularly organized atrial lattice (Fig. 14F). Meshes of the atrial lattice, composed mainly of hexactins with a few stauractins and pentactins, are not rectangular and microscleres, not present in the dermal lattice, make up a significant component of this structure. The main supporting skeleton is a network of loose interwoven unfused diactins occurring in bundles or singly and oriented without order. Spicule fusion probably occurs only in the basidictyonal skeleton, not collected. Within the moderately firm surface layers, the main parenchyma is cavernous, resulting in a very soft overall body texture. Color of the fresh specimen was white; when preserved in ethanol or dried it is light brown. Megascleres: (spicule dimensions are given in Table 7). Hypodermal pentactins (Fig. 15A), and a very few triactins and irregular tetractins, are mostly crucial, rarely semi-paratropal, and smooth, with long tapered rays ending in rough sharp tips. Their tangential rays are bundled with thick and thin diactins to form primary support for hexactine dermalia. Dermalia (Fig. 15B) are entirely rough spicules with cylindric rays ending in rounded and sometimes inflated tips; 37% are hexactins, 31% pentactins, and 32% stauractins. Hexactins are distributed mainly over the hypodermal strands, pentactins at edges of strands, and stauractins over the unsupported middle of the larger lattice fields. Atrialia are composed of the same three spicule types (Fig. 15C), but they are larger than dermalia, tend to have elongate proximal rays in pentactins and one axis elongate in hexactins. Parenchymal megascleres are all diactins, including thick principal diactins (Fig. 15D) and thin intermediate and comital diactins (Fig. 15E). Thick principal diactins are slightly curved, generally smooth, with no medial swelling and rough rounded or parabolic tips. Thin diactins are straight to sinuous, generally smooth with a significant medial swelling and rough parabolic tips. Short straight diactins (Fig. 15F) are associated with only the atrial surfaces. µm unless otherwise indicated). Microscleres consist of immense discasters, also known as solasters, hemioxyhexasters, oxyhexactins and variants, and microdiscohexasters. The subdermal solasters (Fig. 15G) are derived discohexasters with centrum expanded to a solid sphere, entirely enclosing the primary rays. Terminal rays emanating directly from the centrum are unequal in length, ornamented with short reclined barbs, and end in marginally toothed discs. Oxy-tipped microscleres (Fig. 15H) are very thin and mainly associated with the atrial skeleton; they include regular oxyhexactins, hemioxyhexasters and an array of forms with reduced ray numbers—2, 3, 4, 5 developed rays—but never complete oxyhexasters. They are all rough, all terminal rays ornamented with reclined spines. Many have sharp bends at the end of the primary rays, with one or two developed rays and a short spur emanating from that point; compact spiral variants are rare. Microdiscohexasters (Fig. 15I) are very rare and associated with both surface skeletons. They have short, thick, smooth primary rays, each of which supports 5–10 spined, irregularly sinuous terminal rays ending in very small discs with recurved marginal teeth. Remarks. This species is widely distributed in the N Pacific, from Sagami Bay, Japan through the Kurile Islands and the Okhotsk Sea (Tabachnick, 2002) and has recently been reported from Central California (Lee et al . 2007). Our discovery of A. schulzei in Alaska is not surprising, but it represents a considerable range extension of ca 2,000 km from its nearest previously reported occurrence in the Okhotsk Sea. The new Aleutian Islands specimen agrees in virtually all details with the holotype specimen from Sagami Bay, Japan. In reviewing other possible assignments of this specimen, we discovered that there are no significant differences between A. albatrossi Okada, 1932 from off S Kamchatka Peninsula, and A. schulzei . In his description of A. albatrossi , Okada described its macrodiscohexasters (not figured) as 250–650 µm in diameter (we found 409–592–788 µm, n = 8, in the holotype), terminal rays as smooth with conically convex discs (we found terminal rays rough with hemispheric discs), and two size classes of microdiscohexasters of 32–40 and 50–56 µm diameters (we found one class, 23–34–42 µm, n = 127). Okada's description of A. albatrossi is, like many of his other descriptions, clearly unreliable and almost all reputed differences between the species evaporate when the holotypes are directly compared. Maximum size of macrodiscohexasters (solasters) is quite variable between specimens of the same species and is not alone considered a sufficient basis for distinguishing between species. We thus propose A. albatrossi Okada to be recognized as a junior synonym of A. schulzei Ijima. The description here of the Aleutian Islands specimen is the first documentation of A. schulzei spicule forms with SEM. Review of all video footage collected with the ROV 'Jason II' indicates that it is a rare species occurring singly on bedrock, boulders, and cobbles at depths between 1270 and 1350 m. Associated fauna include juvenile lithodid crabs ( Paralomis verrilli and Lithodes couesi ), pandalid shrimps, and the large ophiuroid Gorgonocephalus eucnemis . : 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 29-33, DOI: 10.11646/zootaxa.3628.1.1, http://zenodo.org/record/5261270 : {"references": ["Ijima, I. (1896) Notice of new Hexactinellida from Sagami Bay. Zoologischer Anzeiger, 19 (504), 249 - 254.", "Ijima, I. (1898) The genera and species of Rossellidae. Annotationes zoologicae japonenses, 2 (2), 41 - 55.", "Ijima, I. (1904) Studies on the Hexactinellida. Contribution IV. (Rossellidae). Journal of the College of Sciences, Imperial University of Tokyo, 18 (7), 1 - 307, pls I - XXIII.", "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.", "Lee, W. L., Elvin, D. W., & Reiswig, H. M. (2007) The Sponges of California: A Guide and Key to the Marine Sponges of California. Monterey Bay National Marine Sanctuary Foundation, Monterey, California, x + 395 pp.", "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"]} Text Aleutian Island Archipelago Kamchatka Kamchatka Peninsula okhotsk sea Alaska Aleutian Islands Glass sponges DataCite Metadata Store (German National Library of Science and Technology) Kamchatka Peninsula ENVELOPE(160.000,160.000,56.000,56.000) Okhotsk Pacific

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