identifier	taxonID	type	CVterm	format	language	title	description	additionalInformationURL	UsageTerms	rights	Owner	contributor	creator	bibliographicCitation
50ABE2C90B9C59B789E7DB39ABF4C497.text	50ABE2C90B9C59B789E7DB39ABF4C497.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Bathydorus poculum Reiswig, Dohrmann & Kelly 2021	<div><p>Bathydorus poculum Reiswig, Dohrmann &amp; Kelly sp. nov.</p><p>Figs 2, 3</p><p>Material examined.</p><p>Holotype NIWA 126338, RV Sonne Stn SO 254/85ROV19_BIOBOX17, <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=178.852&amp;materialsCitation.latitude=-35.612" title="Search Plazi for locations around (long 178.852/lat -35.612)">Southern Kermadec Ridge</a>, 35.612°S, 178.852°E, 1150 m, 24 Feb 2017.</p><p>Distribution.</p><p>Known only from the type locality, the Southern Kermadec Ridge, north of New Zealand (Fig. 2A).</p><p>Habitat.</p><p>Attached to hard substratum at 1149 m (Fig. 2B).</p><p>Description.</p><p>Morphology of the holotype is a thick-walled funnel attached to rock substratum by a wide basal disc (Fig. 2B). Both dermal and atrial surfaces have a very dense, bushy, cover of prostal diactins (Fig. 2C, E, F). The single terminal osculum is the widest body part and the margin is abruptly sharpened; it has no marginalia (Fig. 2D). Dimensions of the holotype are ~ 17.2 cm high and 12.8 cm wide; the measurements are only approximate as only one of the two laser points could be certainly found on the in-situ images. Wall thickness is 10.7 cm, excluding the 1-2.5 cm thick prostal cover layers on each side. Texture is soft, compressible, and resilient, neither hard nor fragile. Surfaces of both the inner and outer walls are hairy to the naked eye, and when inspected at low magnification of a dissecting microscope, both are covered with a bushy layer of prostal diactins. Colour in life is pale beige, and pale brown when preserved in ethanol.</p><p>Skeleton. Choanosomal skeleton consists of a loose network of thin choanosomal diactins amongst the thicker proximal ends of prostal diactins, and proximal rays of hypodermal pentactins. No choanosomal hexactins are present. There is no evidence of fusion between any spicules. Microscleres are scattered evenly throughout the choanosome. Ectosomal skeleton of the dermal side consists of abundant prostal diactins passing through the distal tangential parts of hypodermal pentactins and dermalia, which are mostly stauractins (62% of 126 assessed), pentactins (29%) and hexactins (10%). The atrial ectosome lacks hypoatrial pentactins but has atrialia in the form of hexactins (89% of 126 assessed), pentactins (8%), stauractins, and triactins (1.5% each). Microscleres are present as in the choanosome.</p><p>Spicules. Megascleres (Fig. 3; Table 1) are prostal diactins, hypodermal pentactins, choanosomal diactins, dermalia mostly as stauractins, and atrialia mostly as hexactins. Prostal diactins (Fig. 3A) are long bow-shaped spicules, smooth except for patches of subterminal spines; the smooth tips are rounded or parabolic; the spicule centre is not swollen. Hypodermal pentactins (Fig. 3B) are regular and crucial in form with very long proximal rays, averaging 3.4  × tangential ray length, and fine spines evenly scattered over the entire surface. All five rays have subterminal patches of larger spines and smooth round tips. Choanosomal diactins (Fig. 3C) are straight, bent or more commonly sinuous in shape. Most are broken so few intact spicules are measurable for length. They are smooth except for subterminal inflated rough patches; the tip is smooth and abruptly tapered to a point. The spicule centre is moderately swollen. Dermalia (Fig. 3D) are mainly crucial stauractins completely covered with short, rounded knobs or spines; rays are tapered to a round tip. Atrialia (Fig. 3E) are mostly hexactins ca. half of which are pinular with one ray longer than the others. Like dermalia, these are entirely covered with short, rounded knobs or spines but longer than those of the dermalia; ray tips are rounded.</p><p>Microscleres (Fig. 3; Table 1) are all oxyhexasters and their variants with hemioxyhexasters being the most common. Oxyhexasters (Fig. 3F, G) have short smooth primary rays and long straight secondary rays; the secondary rays are entirely ornamented with reclined spines that increase in size from the ray tip to its proximal end. Secondary rays on each primary ray vary from 2-5. Hemioxyhexasters (Fig. 3H) are similar to oxyhexasters but at least one of the six primary rays bear only a single secondary ray. Other rare variants include oxyhexactins, oxypentasters, and oxystaurasters (Fig. 3I).</p><p>Etymology.</p><p>Named for the beaker-shaped morphology of this species ( Bathydorus poculum, beaker; Latin).</p><p>Remarks.</p><p>This New Zealand specimen, NIWA 126338, is entirely consistent with the diagnosis of  Bathydorus and is assigned there. Each of the known species of the genus differ from this specimen in the following characters:  Bathydorus echinus Koltun, 1967 has prostal pentactins in addition to diactins, and dermalia as mainly pentactins;  B. fimbriatus Schulze, 1886 has prostalia including pentactins as marginalia only, and no pinular atrialia;  B. laevis laevis Schulze, 1886 has no prostalia lateralia and no pinular atrialia;  B. laevis pseudospinosus Tabachnick &amp; Menshenina, 2013 has some large choanosomal or prostal hexactins and smaller oxyhexasters to only 100  µm diameter;  B. laninger Kahn, Geller, Reiswig &amp; Smith Jr., 2013 has a flat body form and no prostalia on the atrial (upper) surface;  B. servatus Topsent, 1927 has no prostal diactins, and dermalia as stauractins and diactins;  B. spinosissimus Lendenfeld, 1915 has choanosomal hexactins, and oxyhexasters with longer primary rays (4-12  µm); in the original description of  B. spinosus Schulze, 1886, there is no mention of hypodermal pentactins; although Tabachnick and Menshenina (2013) include these, they fail to certify that they are present in the holotype; this species also has wavy secondary rays on the oxyhexasters;  B. uncifer Schulze, 1899 has smooth dermal and atrial surfaces, and dermalia as mainly pentactins and stauractins. These differences are sufficient to conclude that the new form is a new species, here designated as  Bathydorus poculum sp. nov.</p></div>	https://treatment.plazi.org/id/50ABE2C90B9C59B789E7DB39ABF4C497	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
BD2A510BB9AE571B90D9D09ED0009107.text	BD2A510BB9AE571B90D9D09ED0009107.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Bathydorus Schulze 1886	<div><p>Bathydorus Schulze, 1886</p><p>Bathydorus poculum Reiswig, Dohrmann &amp; Kelly, sp. nov.</p></div>	https://treatment.plazi.org/id/BD2A510BB9AE571B90D9D09ED0009107	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
E5F13B62E7BB5693AF4695A9C64109DE.text	E5F13B62E7BB5693AF4695A9C64109DE.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Bathydorus Schulze 1886	<div><p>Bathydorus Schulze, 1886</p><p>Diagnosis.</p><p>Rossellinae with tubular, saccular, or plate-like gross morphology. Basiphytous or lophophytous, thin-walled. Dermalia are combinations of spicules from hexactins to diactins. Regular pentactins make up a hypodermal layer. Choanosomal skeleton composed of diactins, sometimes with hexactins. Atrialia are hexactins or stauractins. Microscleres are combinations of oxyoidal hexasters, hemihexasters, and hexactins; lacking pappocomes (from Kahn et al. 2013).</p><p>Type species.</p><p>Bathydorus fimbriatus Schulze, 1886</p></div>	https://treatment.plazi.org/id/E5F13B62E7BB5693AF4695A9C64109DE	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
07CBE7530CA4568993E2515A627881FA.text	07CBE7530CA4568993E2515A627881FA.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Caulophacus (Caulophacus) discohexaster Tabachnick & Levi 2004	<div><p>Caulophacus (Caulophacus) discohexaster Tabachnick &amp; 
Levi, 2004</p><p>Figs 12, 13</p><p>Type and locality (not examined).</p><p>Holotype - MNHN HCL519, Norfolk Ridge, HALlPRO 2, Zoneco Stn BT 062, 24.71°S, 168.648°E, 720-1048 m.</p><p>Material examined.</p><p>NIWA 126342, RV Sonne Stn SO 254/85ROV19_BIOBOX6, <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=178.854&amp;materialsCitation.latitude=-35.609" title="Search Plazi for locations around (long 178.854/lat -35.609)">Southern Kermadec Ridge</a>, 35.609°S, 178.854°E, 1163.6 m, 24 Feb 2016 ;   NIWA 126343, RV Sonne Stn SO 254/85ROV19_BIOBOX17, <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=178.852&amp;materialsCitation.latitude=-35.612" title="Search Plazi for locations around (long 178.852/lat -35.612)">Southern Kermadec Ridge</a>, 35.612°S, 178.852°E, 1149.8 m, 24 Feb 2017  .</p><p>Distribution.</p><p>Known from the type locality, Norfolk Ridge near New Caledonia, and southern Kermadec Ridge, ~ 223 km N of East Cape, North Island, New Zealand.</p><p>Habitat.</p><p>Attached to hard substratum; depth 720 to 1348 m (New Zealand locations, Fig. 12A).</p><p>Description.</p><p>This description refers to New Zealand specimens only. Body forms a solitary mushroom cap-shaped upper body on a long, kinked, somewhat crooked, flattened, hollow stalk (Fig. 12B, E). Surfaces of the upper body are smooth (Fig. 12C, D) with a slight blunt eminence on the outer atrial face opposite the stalk insertion, but there is no indication of an osculum. The upper dermal surface lacks any visual indication of a lattice. The lower dermal surface of the specimen is divided by ridges into six depressions not seen in the smaller specimen. The stalks of both are flattened and that of the smaller bears a cylindrical central canal (Fig. 12F). SEM views of the dried surfaces show pores in the dermal body surface membrane (Fig. 12G), apparently contracted pores in the atrial body surface involving the atrial pinules (Fig. 12H), and no indication of pores on the dermal stalk surface (Fig. 12I). Dimensions of the smaller specimen upper body is ~ 12.5  × 10.6 cm in diameter; stalk is 15.9  × 9.0 mm in diameter and stalk canal is 4.1  × 3.3 mm in diameter. Length of the stalk could not be approximated. The larger specimen upper body is 25.0  × 15.9 cm in diameter while the flattened stalk is 5.9 cm wide. Measurable ostia of the smaller specimen (Fig. 12G) are 70 and 99  µm in diameter. Texture of the body is firm but compressible; the stalk is hard. Surface of all parts are smooth, consisting of tight palisades of pinular rays of dermalia and atralia supported on hypodermal and hypoatrial pentactins. There are no projecting prostalia. Colour in life is pale pinkish brown as are the specimens preserved in ethanol.</p><p>Skeleton. Choanosomal skeleton of the body consists of a tight network of choanosomal hexactins and diactins. There is no evidence of fusion between any spicules within the body. Microscleres are scattered evenly throughout the choanosome. The stalk internal skeleton is composed of large diactins oriented longitudinally and fused by synapticula. Ectosomal skeleton of the dermal and atrial sides consists of tightly packed pinular hexactins and very few pinular pentactins (1.6% of 623 assessed). These are supported on, respectively, hypodermal and hypoatrial pentactins which are never raised above the surfaces. Microscleres are present as in the choanosome.</p><p>Spicules. Megascleres (Fig. 13; Table 6) are hypodermal pentactins, choanosomal hexactins and diactins, and pinular hexactins and a few pentactins. Hypodermal pentactins of the body (Fig. 13A) are regular and usually smooth except for spined ray ends; 8% have indistinct spines on the proximal part of the proximal ray. The proximal rays are longer, averaging 1.24  × the length of tangential rays. Hypoatrial pentactins of the body (Fig. 13B) are regular and spined on both ray-ends and 61% of them on the proximal part of the proximal rays. The proximal ray is longer, averaging 1.62  × the length of tangential rays. Hypodermal pentactins of the stalk (Fig. 13C) are regular in shape but significantly smaller than those of the body; they are spined only on ray ends. Tangential and proximal rays are approximately equal in length. Choanosomal hexactins (Fig. 13D) are restricted to the body; rays are smooth, and spines are restricted to the ray ends except where the ray is exceptionally short. These hexactins occur in two forms, one with a short spiny ray (upper figure) and the other with all rays approximately equal in length (lower figure). Choanosomal diactins (Fig. 13E) are straight or slightly curved and are smooth except for ends on which they have small but detectable central swellings. Dermal pinular hexactins of the body (Fig. 13F) have bushy, nearly cylindrical pinular rays with a short, thick, rounded apical tip. Tangential and proximal rays are entirely spined and approximately similar in size and shape. Very rarely, these and pinules of other body surfaces are pentactine with only a round nub in place of the proximal ray. Atrial pinular hexactins of the body (Fig. 13G) have pinular rays that taper in length of scales at both ray ends, resulting in fusiform shape. The pinular ray has a thick and rounded tip. Tangential and proximal rays are entirely spined and similar in size and shape. Stalk pinular hexactins (Fig. 12H) have a pinular ray that is squat and slightly wider than those of the body spicules. Scale lengths taper basally and apically and again the apex of the pinule is a blunt, thick cap. Tangential and proximal rays are entirely spined and similar in size and shape.</p><p>Microscleres (Fig. 13; Table 6) are discohexactins (43% of 221 assessed), hemidiscohexactins (54.7%), and discohexasters (2.3%); all are thick-rayed forms. Discohexactins (Fig. 13I) have rays ornamented with large, reclined spines and a terminal disc with 5 (4-7) marginal teeth. Hemidiscohexasters (Fig. 13J) are similar with at least one ray being branched and at least one ray being unbranched; the total number of rays is 9.4 (7-13). Terminal discs are similar to discohexactins. Discohexasters (Fig. 13K) have all primary rays branched varying from 2-6 terminal rays on each primary ray. Terminal discs have 3-8 marginal teeth.</p><p>Remarks.</p><p>The morphological characters of the two New Zealand specimens place them clearly in subgenus  Caulophacus (Caulophacus), of which there are 22 recognised species. Table 7 compares the key morphological characters that differentiate them from each other and from the New Zealand specimens, NIWA 126342 and NIWA 126343. We admit that some of these differences are subjective and the list is not exhaustive. Table 7 shows only a single species,  C. (C.) discohexaster, that has a single morphological difference from the specimens described here, i.e., the visual impression of the dermal pinule (Tabachnick and  Lévi 2004: 51, fig. 24A). Measurement of the dermal pinule in that figure shows that the figured pinular ray is too wide (84  µm) to fit within the data given for the pinular ray of the dermal hexactin given there (106-220  µm /30-46  µm). Removing this illustration error from the list results in no differences between the New Zealand specimens and the type material described by Tabachnick and  Lévi (2004) from New Caledonia; therefore, we assign the specimens to that species.</p><p>*Taxonomic authorities have been excluded from this column but are available from van Soest et al. (2021)</p></div>	https://treatment.plazi.org/id/07CBE7530CA4568993E2515A627881FA	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
CAA72752CEEB5252962661AFC687BFC1.text	CAA72752CEEB5252962661AFC687BFC1.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Caulophacus (Caulophacus) ramosus Reiswig, Dohrmann & Kelly 2021	<div><p>Caulophacus (Caulophacus) ramosus Reiswig, Dohrmann &amp; Kelly sp. nov.</p><p>Figs 16, 17</p><p>Material examined.</p><p>Holotype NIWA 126085, RV Sonne Stn SO254/22ROV06_BIOBOX4, Kermadec Trench slope, 29.266°S, 176.702°W, 4819 m, 04 Feb 2017.</p><p>Distribution.</p><p>Known only from the type locality, the Kermadec Trench slope, north of New Zealand (Fig. 16A).</p><p>Habitat.</p><p>Attached to hard substratum; depth 4819 m.</p><p>Description.</p><p>Morphology of the holotype is a compound mass of a thin, convoluted stalk-part, with at least one small mushroom-shaped body branching from it (Fig. 16D, E), and a longer, thicker, upright stalk-part bearing a larger terminal mushroom-shaped body (Fig. 16B, C). The larger upright stalk has six lateral knobs just below the larger body on its stalk (Fig. 16C) whose nature and function are unknown, possibly sites for attachment to a hard substratum, or are new buds. The lower convoluted stalk part branches into many attachment points, at least eight within a 27 mm length (Fig. 16D). The smaller of the two bodies attached to this stalk system has a felt-like cover of long pinular pentactins on the outer surface (Fig. 16E); we have had no opportunity to examine the larger body. The stalk in all parts is hollow (Fig. 16F). Overall dimension of the larger body in the in-situ image is 45.5 mm in diameter with the stalk having a diameter of 5.9 mm at a point 5 mm below the attachment. The smaller specimen is 5.3 mm in diameter and 3.6 mm in height. Stalk diameter varies from 1.0 mm at the short branch joining the small specimen to the convoluted stalk which is mostly ca 1.8 mm thick. The connection of the convoluted part of the stalk to the thicker upright stalk part was not available for assessment. Surfaces of the small body are covered by a villous plush of long pinular pentactins, but there are no special prostalia present. The lower convoluted stalk surfaces appear devoid of any visible surface spicules, but spicule preparations of this apparently  “barren” stalk still show that typical stalk spicules are present. Thus, spicules obtained from stalks may derive from other locations on the specimen and should be considered as possibly from other original sources. Surfaces of the upper straight stalk and the terminal larger body are known only from fresh seawater-wet lab photos; they are covered by a thick spiny layer of brown tissue (Fig. 16C). Colour of the body in life is translucent white; when preserved in ethanol it is pale brown.</p><p>Skeleton. Choanosomal skeleton of the body is a network of diactins and hexactins. There is no evidence of fusion between any spicules within the body. Spicule fusion is restricted to the choanosomal diactins of the hollow stalks where the diactins are joined by fusion at spot contacts and by relatively long synapticula forming ladders. Microscleres are scattered evenly throughout the choanosome. Ectosomal skeleton of the dermal and atrial sides of the body consists of tightly packed pinular pentactins; no pinular hexactins are present. These are supported on, respectively, hypodermal and hypoatrial pentactins, which are never raised above the surfaces. Microscleres are present as in the choanosome.</p><p>Spicules. Megascleres (Fig. 17; Table 9) are hypodermal and hypoatrial pentactins, choanosomal hexactins and diactins, and pinular pentactins. Hypodermal pentactins of the body (Fig. 17A) are regular and smooth except for spined ray ends. The proximal rays are longer, averaging 1.26  × the length of tangential rays. Hypoatrial pentactins of the body (Fig. 17B) are also regular and smooth except for spined areas on both tangential and proximal ray ends. The proximal ray is longer, averaging 1.41  × the length of tangential rays. Hypodermal pentactins of the stalk (not figured) are regular in shape but significantly smaller than those of the body. Choanosomal hexactins (Fig. 17C) are restricted to the body; rays are smooth and spines are present only on ray ends. Macrospines are never found in the central part of these spicules. Choanosomal diactins (Fig. 17D) are straight or slightly curved and are smooth except for the ends; they have small but detectable central swellings. Dermal pinular pentactins of the body (Fig. 17E) have narrow pinular rays topped with a short, blunt apical spine. Their basal rays are entirely spined and end in abruptly rounded tips. Atrial pinular pentactins of the body (Fig. 17F) have narrow pinular rays like the dermal pinules, but with a longer pinular ray (on average 1.25  ×); however, presence of an apical spine was not determined since all of these examined in SEM had broken tips. Basal rays are like those of the dermal pinules. Stalk pinular pentactins (not figured) are morphologically similar to the dermal body pentactins.</p><p>Microscleres (Fig. 17; Table 9) are thick-rayed discohexactins and rare hemidiscohexasters and thin-rayed stellate discohexasters. Discohexactins (Fig. 17G) are the most abundant microscleres; they have rays ornamented with large, reclined spines and a terminal disc with 5-8 marginal teeth. Rare hemidiscohexasters (Fig. 17H) are similar to the discohexactins. Thin-rayed stellate discohexasters (Fig. 17I) have long, smooth primary rays supporting a narrow shorter brush of 3-9 straight, rough, terminal rays ending in small discs.</p><p>Etymology.</p><p>Named for the lower, convoluted stalk part, which branches into many attachment points ( Caulophacus ramosus, branching; Latin).</p><p>Remarks.</p><p>The morphological character of all microscleres being discoid, places this species in the subgenus  Caulophacus (Caulophacus) . In comparing it to the 22 recognised species of this subgenus (Table 7), it is apparent that there are no forms known with all pinules, both dermal and atrial, as exclusively pentactins. It is very like the previous described new species,  C. (Caulophacus) serpens sp. nov. in its mainly, but not exclusively, pinular pentactins, and in the body form with a significant portion of the stalk convoluted, attached by many attachment sites and compound bearing several bodies. The two differ, however, in pinule morphology and types of microscleres. Also, molecular data (MD, unpubl. results) suggest a closer relationship of this specimen to  C. (Caulophacus) arcticus,  C. (Caulodiscus) valdiviae, and  C. (Oxydiscus) weddelli than to  C. (C.) serpens sp. nov. Since it cannot be assigned to any of the former species on the basis of morphology, it is thus clear that the form described here represents the holotype of a new species named  Caulophacus (Caulophacus) ramosus sp. nov.</p></div>	https://treatment.plazi.org/id/CAA72752CEEB5252962661AFC687BFC1	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
AAE5741018595553BD91FCC23ABA0404.text	AAE5741018595553BD91FCC23ABA0404.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Caulophacus (Caulophacus) (Caulophacus) Schulze 1886	<div><p>Caulophacus (Caulophacus) Schulze, 1886</p><p>Caulophacus (Caulophacus) discohexaster Tabachnick &amp;  Lévi, 2004</p><p>Caulophacus (Caulophacus) serpens Reiswig, Dohrmann &amp; Kelly, sp. nov.</p><p>Caulophacus (Caulophacus) ramosus Reiswig, Dohrmann &amp; Kelly, sp. nov.</p></div>	https://treatment.plazi.org/id/AAE5741018595553BD91FCC23ABA0404	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
0506246A03995101BC4FA401B11BFCE9.text	0506246A03995101BC4FA401B11BFCE9.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Caulophacus (Caulophacus) (Caulophacus) Schulze 1886	<div><p>Caulophacus (Caulophacus) Schulze, 1886</p><p>Diagnosis.</p><p>Body is mushroom-shaped or cup-like, basiphytous with long stalk. Choanosomal spicules are diactins and hexactins. Dermalia and atrialia are pinular hexactins and/or pinular pentactins. Hypodermalia and hypoatrialia are pentactins. Microscleres are represented chiefly by spicules with discoidal terminations. They usually can be divided into two categories. The first are spicules with thick rays covered with dense spines: usually discohexactins but also discohexasters, hemidiscohexasters, and rarely discasters. The second are discohexasters with thin, smooth, or rough secondary rays usually in the form of lophodiscohexasters but sometimes calycocomes and spherical discohexasters are present among them (emended from Tabachnick 2002).</p><p>Remarks.</p><p>The subgenus  Caulophacus Caulophacus is likely paraphyletic (Dohrmann 2019; MD, unpubl. results) and retained here for historical reasons only. Diagnoses of genus  Caulophacus and subgenus  Caulophacus Caulophacus are emended to include the new species  Caulophacus (Caulophacus) serpens sp. nov. (described below) with mostly pinular pentactins as both dermalia and atrialia.</p><p>Type species.</p><p>Caulophacus (Caulophacus) elegans Schulze, 1886.</p></div>	https://treatment.plazi.org/id/0506246A03995101BC4FA401B11BFCE9	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
F8338B31A2F8591C87DAA811AB9862BB.text	F8338B31A2F8591C87DAA811AB9862BB.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Caulophacus (Caulophacus) serpens Reiswig, Dohrmann & Kelly 2021	<div><p>Caulophacus (Caulophacus) serpens Reiswig, Dohrmann &amp; Kelly sp. nov.</p><p>Figs 14, 15</p><p>Material examined.</p><p>Holotype NIWA 126084, RV Sonne Stn SO254/22ROV06_BIOBOX6, Kermadec Trench slope, 29.266°S, 176.702°W, 4816 m, 04 Feb 2017.</p><p>Distribution.</p><p>Known only from the type locality, the Kermadec Trench slope, north of New Zealand (Fig. 14A).</p><p>Habitat.</p><p>Attached to large pieces of rubble lying on a sediment plain at 4816 m.</p><p>Description.</p><p>Morphology of the holotype a rhizome-like, hard, hollow, thin stem that creeps across the sediment seabed, attaching to rubble here and there, in places forming a tangled mass, from which arises the main mushroom-shaped body on a zigzag stem (Fig. 14B, C), and two tiny, mushroom-shaped bodies (Fig. 14D). Overall dimension of the holotype, spreading across the seabed, is 64 cm. Dimension of the larger body (Fig. 14B) is 22.2 mm in diameter and 11.2 mm in height; its associated stalk is 3.6 (2-6-4.3) (n = 12) mm in diameter. The associated stalk measures 3.3 (2.7-4.0) (n = 29) mm in diameter, the length, measured in conformation from the body to the stalk tangle, is 167 mm. The smaller bodies (Fig. 14D) are 7.2  × 5.4 and 5.2  × 4.3 mm in diameter and height, respectively; the stalk of the larger one is 1.1 (1.0-1.3) (n = 12) mm in diameter. The piece of thick stalk received from NIWA is 72 mm long and 3.0 (2.8-3.3) (n = 12) mm in diameter, approximately the same gauge as the convoluted stalk shown in the in situ and deck images. Surfaces of the body are a bit lumpy and fuzzy (Fig. 14D); that of the thin attached stalks is also fuzzy. There are no projecting prostal spicules. Colour of the body in life is white, and the stem pale brown; when preserved in ethanol it is very pale brown, almost white.</p><p>Skeleton. Choanosomal skeleton of the body is a network of diactins and hexactins. There is no evidence of fusion between any spicules within the body. Spicule fusion is restricted to the choanosomal diactins of the hollow stalks where the diactins are joined by synapticula and points of spot contacts between spicules. Microscleres are scattered evenly throughout the choanosome. Ectosomal skeleton of the dermal and atrial sides of the body and living stalks consists of tightly packed pinular pentactins and very few pinular hexactins (1.3% of 374 assessed). These are supported on, respectively, hypodermal and hypoatrial pentactins which are never raised above the surfaces. Microscleres are present as in the choanosome.</p><p>Spicules. Megascleres (Fig. 15; Table 8) are hypodermal and hypoatrial pentactins, choanosomal hexactins and diactins, and pinular pentactins and a few pinular hexactins. Hypodermal pentactins of the body (Fig. 15A) are regular and usually smooth except for spined ray ends; 31% have macrospines on the central part of the proximal ray. The proximal rays are longer, averaging 1.21  × the length of tangential rays. Hypoatrial pentactins of the body (Fig. 15B) are regular and spined on both tangential and proximal ray ends; macrospines are present on the central part of most (60%) proximal rays but all tangential rays lack macrospines. The proximal ray is longer, on average 1.86  × the length of tangential rays. Hypodermal pentactins of the stalk (Fig. 15C) are regular in shape but significantly smaller than those of the body; they are spined on ray ends but macrospines are uncommon (12%) on the central part of only the proximal rays. Proximal rays are generally longer, on average 1.49  × tangential ray length. Choanosomal hexactins (Fig. 15D) are restricted to the body; rays are smooth, and spines are restricted to the ray ends. Macrospines are never found in the central part of these spicules. Choanosomal diactins (Fig. 15E) are straight or slightly curved and are smooth except for ends; they have small but detectable central swellings. Dermal pinular pentactins of the body (Fig. 15F) have narrow pinular rays topped with a short, sharp apical spine. Their basal rays are entirely spined and end in abruptly pointed tips. Approximately 10% of the dermal pinules are hexactine forms. Atrial pinular pentactins of the body (Fig. 15G) have narrow pinular rays like the dermal pinules but with a longer pinular ray (on average 2.1  ×) and longer apical spine; basal rays are like those of the dermal pinules. Stalk pinular hexactins (Fig. 15H) have a pinular ray that is narrow in its basal half but curves to one side and swells in width apically, assuming an overt club-shape. It has no atrial spine since the apex is enfolded by the apical scales. Basal rays are like those of the dermal and atrial pinules.</p><p>Microscleres (Fig. 15; Table 8) are discohexactins, thick-ray discohexasters and thin-ray discohexasters. Discohexactins (Fig. 15I) are the most abundant microscleres; they have rays ornamented with large, reclined spines and a terminal disc with 5-8 marginal teeth. Thick-ray discohexasters (Fig. 15J) are the least abundant microsclere; they are spherical, have 6-9 thorned terminal rays on each smooth primary ray, and terminal discs have 4-8 marginal teeth. Thin-ray discohexasters (Fig. 15J, K) are among the most numerous microscleres, but comparing their abundance with discohexactins is not possible since detection of the two spicule types requires different microscope arrangements. They are semi-stellate with each smooth primary ray supporting 16 (8-28) (n = 16) thorned terminal rays ending in discs with 3-7 marginal teeth.</p><p>Etymology.</p><p>Named for the rhizome-like stem that may form tangled, convoluted stems from which the main bodies arise, the whole creeping along the substrate ( Caulophacus serpens, creeping; Latin).</p><p>Remarks.</p><p>The morphological character of all microscleres being discoid, places this species in the subgenus  Caulophacus (Caulophacus) . In comparing them to the 22 recognised species of this subgenus (Table 7), it is apparent that there are no forms known with both dermal and atrial spicules as mainly pinular pentactins. It is thus clear that the form described here is the holotype of a new species named  Caulophacus (Caulophacus) serpens sp. nov.</p></div>	https://treatment.plazi.org/id/F8338B31A2F8591C87DAA811AB9862BB	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
2804D83296EF5122B2E31DAB054E9B70.text	2804D83296EF5122B2E31DAB054E9B70.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Rossellidae Schulze 1886	<div><p>Rossellidae Schulze, 1885</p><p>Diagnosis.</p><p>The body is usually cup-like basiphytose or lophophytose; in the pedunculate forms the body can be mushroom-like.  Prostalia lateralia, when present, are formed with diactins or outwardly protruding hypodermal pentactins; prostalia basalia, when present, are outwardly protruding hypodermal pentactins which are usually specialised (anchorate). Choanosomal skeleton consists of diactins, sometimes together with less frequent hexactins. Hypodermal pentactins often present, usually they protrude from the dermal surface serving as prostalia. Hypoatrial pentactins are rarely found or absent in some taxa. Dermalia are combinations of various spicules usually pentactins; stauractins and diactins, rarely hexactins. Atrialia are usually hexactins but other holactinoidal spicules can be also found there. Microscleres are various: holactinoidal, asterous and asters; they usually have discoidal or oxyoidal terminations but sometimes floricoidal, onychoidal, or sigmoidal ones (after Tabachnick 2002).</p></div>	https://treatment.plazi.org/id/2804D83296EF5122B2E31DAB054E9B70	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
E56C0B5C344657F2A58D6ECCD0A015F4.text	E56C0B5C344657F2A58D6ECCD0A015F4.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Caulophacus Schulze 1886	<div><p>Caulophacus Schulze, 1886</p><p>Diagnosis.</p><p>Body is fungus-like or cup-like, basiphytose with long stalk. Choanosomal spicules are diactins and hexactins. Dermalia are pinular hexactins and/or pentactins. Atrialia are pinular hexactins and/or pentactins. Hypodermalia and hypoatrialia are pentactins. Microscleres are spicules of hexactinous or hexasterous forms with discoidal, onychoidal, and oxyoidal termination (emended from Janussen et al. 2004).</p><p>Type species.</p><p>Caulophacus (Caulophacus) elegans Schulze, 1886.</p></div>	https://treatment.plazi.org/id/E56C0B5C344657F2A58D6ECCD0A015F4	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
BD8B043A48B9551BAEB1EEE18E9F7785.text	BD8B043A48B9551BAEB1EEE18E9F7785.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Nubes poculiformis Reiswig, Dohrmann & Kelly 2021	<div><p>Nubes poculiformis Reiswig, Dohrmann &amp; Kelly sp. nov.</p><p>Figs 6, 7</p><p>Material examined.</p><p>Holotype NIWA 126016, RV Sonne Stn SO 254/08ROV02_BIOBOX10, Seamount No. 114 in International Waters to the east of <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=175.197&amp;materialsCitation.latitude=-31.301" title="Search Plazi for locations around (long 175.197/lat -31.301)">Three Kings Ridge</a> and Norfolk Island, 31.301°S, 175.197°E, 1285 m, 31 Jan 2017.</p><p>Distribution.</p><p>Known only from the type locality, Seamount No. 114, in International Waters to the east of Three Kings Ridge and Norfolk Island (Fig. 6A).</p><p>Habitat.</p><p>Attached to hard substratum; depth 1285 m (Fig. 6B).</p><p>Description.</p><p>Morphology of the holotype body is a thick-walled tubular sponge, attached to hard substratum, by a moderately long, narrow stalk (Fig. 6B, C). A moderately sized, round osculum is terminal and opens into a deep atrial cavity. The margin is blunt, bordered by a band of diactine marginalia (Fig. 6D, F). The dermal surface has a dense covering of raised, prostal, hypodermal pentactins (Fig. 6D, E), projecting up to 7 mm from the surface proper. Some of the deck images indicate long diactins projecting sparsely, up to 14 mm, from the dermal surface, but these may be foreign in origin; we have not found such large diactins in the material available for examination. Dimensions of the holotype are ~ 6 cm in total length, including the stalk of 1.8 cm length (Fig. 6G), and 3.5 cm in width; the maximum body wall thickness is 13.9 mm. The osculum is 12.3 by 16.9 mm diameter in situ. Texture is soft, compressible, and resilient, neither hard nor fragile. Surface of the dermal side below the layer of projecting hypodermal pentactins is supported by an intact tight lattice of dermalia (Fig. 6H). The atrial surface (Fig. 6I), in contrast, is torn apart by removal from supporting fluids and the atrial lattice remains only as dismembered patches attached to underlying diactins. Colour in life is pale brown as is the specimen preserved in ethanol.</p><p>Skeleton. Choanosomal skeleton consists of a loose, vacuolar network of thin choanosomal diactins, large choanosomal hexactins and the thicker proximal rays of the hypodermal pentactins. There is no evidence of fusion between any spicules. Microscleres are scattered evenly throughout the choanosome. Ectosomal skeleton of the dermal side consists of abundant prostal pentactins providing good support for the sturdy lattice of stauractine (60.0% of 315 assessed), pentactine (38.4%), and rare hexactine (1.64%) dermalia. The atrial ectosome lacks hypoatrial pentactins but has bands of diactins that provide poor support for the atrial lattice of mainly hexactins (86.4% of 118 assessed), pentactins (7.5%), and stauractins (5.1%). Microscleres are present as in the choanosome.</p><p>Spicules. Megascleres (Fig. 7; Table 3) are prostal hypodermal pentactins, marginal diactins, choanosomal diactins of the body, choanosomal diactins of the stalk, dermalia and atrialia. Prostal hypodermal pentactins (Fig. 7A) are large, raised orthotropal forms with long straight tangential rays. Tangential rays are ca. one half the length of the longer straight proximal rays. The spicules are smooth except for the rough sharp or round tips. Marginalia (Fig. 7B) are long, slightly curved diactins; no intact tips were found in SEM surveys but an exhaustive survey with LM indicates tips taper to nearly invisible thinness and are quite distinct from the thick roughened tips of choanosomal diactins. Choanosomal diactins (Fig. 7C) are straight or slightly curved with undetectable central swellings; they are smooth except for the rough, slightly inflated tips. Stalk diactins (Fig. 7D) are longer and thicker than the choanosomal diactins, but otherwise similar. Dermalia (Fig. 7E) are mainly entirely rough stauractins and pentactins with rounded ray tips. Atrialia (Fig. 7F) are entirely rough hexactins with equal length rays and more acute ray tips.</p><p>Microscleres (Fig. 7; Table 3) are oxyhexasters, hemioxyhexasters, and anisodiscohexasters. Oxyhexasters (Fig. 7G) and hemioxyhexasters have very short, sparsely spined or smooth, thick primary rays, ending in swollen hemispheres; 1-7, usually 3-4, rough, straight, terminal rays tapering to pointed tips emanate from the margins and occasionally from the centre of the hemisphere. Short to very short spur-like terminal rays are common. Anisodiscohexasters (Fig. 7H) have smooth primary rays ending in ovoid strobila. Each strobilum supports ca. 20-30 rough, curved terminal rays that end in discs with 4-7 marginal discs. The tuft of terminal rays from each primary ray varies in length of rays, and with ray length the diameter of terminal discs, in a pattern that is not yet clear, but the whole spicule resembles a radially symmetrical starburst.</p><p>Etymology.</p><p>Named for the goblet shape of the sponge ( Nubes poculiformis, goblet-shaped; Latin).</p><p>Remarks.</p><p>This species differs from  Nubes tubulata sp. nov. in having a short stalk and orthotropal hypodermal pentactins, but is otherwise similar enough to include it in the genus  Nubes as its second species,  Nubes poculiformis sp. nov.</p></div>	https://treatment.plazi.org/id/BD8B043A48B9551BAEB1EEE18E9F7785	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
840700424F8955DF9D7CA2A896F7A417.text	840700424F8955DF9D7CA2A896F7A417.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Nubes Reiswig, Dohrmann & Kelly 2021	<div><p>Nubes Reiswig, Dohrmann &amp; Kelly gen. nov.</p><p>Diagnosis.</p><p>Rossellinae with basiphytous, saccular, thick-walled body, unstalked or with a short stalk. Hypodermalia are large, raised, paratropal or orthotropal pentactins with strongly curved or straight tangential rays, smooth except for rough tips, forming a cloud or veil around the thick-walled body. Prostal diactins are marginalia only. Choanosomal spicules are diactins and sometimes large hexactins with curved rays, smooth except for rough tips. Dermalia are mainly stauractins and pentactins. Atrialia are mainly hexactins and sometimes pentactins. Microscleres are oxyhexasters, hemioxyhexasters, and anisodiscohexasters.</p><p>Etymology.</p><p>Named for the cloud of large hypodermal pentactins that veils the body of these sponges (nubes, cloud; Latin).</p><p>Type species.</p><p>Nubes tubulata sp. nov.</p><p>Remarks.</p><p>This new genus diagnosis differs from those of most other anisodiscohexaster-bearing genera or subgenera in the following ways: from  Anoxycalyx Kirkpatrick, 1907 in not having anchorate hypodermalia, and having pleural hypodermalia raised, having marginalia; in not including pappocomes and discohexasters other than anisodiscohexasters (strobiloidal discohexasters) as microscleres. It differs from that of  Crateromorpha (Crateromorpha) Gray in Carter, 1872 in body form, having marginal diactins, and having main atrialia as hexactins. It differs from that of  Rossella Carter, 1872 in having most atrialia as hexactins instead of stauractins, and no calycocomes. However, it does not differ from the present diagnosis of  Vazella Gray, 1870 (Tabachnick 2002) in any way, but below we offer a modified diagnosis of that genus to separate the two groups.</p></div>	https://treatment.plazi.org/id/840700424F8955DF9D7CA2A896F7A417	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
6FC6D34E962A5A07B310E30EF356C4B2.text	6FC6D34E962A5A07B310E30EF356C4B2.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Nubes Reiswig, Dohrmann & Kelly 2021	<div><p>Nubes Reiswig, Dohrmann &amp; Kelly gen. nov.</p><p>Nubes tubulata Reiswig, Dohrmann &amp; Kelly, sp. nov.</p><p>Nubes poculiformis Reiswig, Dohrmann &amp; Kelly, sp. nov.</p></div>	https://treatment.plazi.org/id/6FC6D34E962A5A07B310E30EF356C4B2	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
D0CFA768826F5F16B8404AB1356975B9.text	D0CFA768826F5F16B8404AB1356975B9.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Nubes tubulata Reiswig, Dohrmann & Kelly 2021	<div><p>Nubes tubulata Reiswig, Dohrmann &amp; Kelly sp. nov.</p><p>Figs 4, 5</p><p>Material examined.</p><p>Holotype NIWA 126159, RV Sonne Stn SO 254/36ROV10_BIOBOX7, Seamount No. 986, off <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=178.214&amp;materialsCitation.latitude=-39.99" title="Search Plazi for locations around (long 178.214/lat -39.99)">Hawkes Bay</a> shelf, 39.990°S, 178.214°E, 782.8 m, 09 Feb 2017  .   Paratype NIWA 126160, RV Sonne Stn SO 254/36ROV10_BIOBOX10, Seamount No. 986, off <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=178.214&amp;materialsCitation.latitude=-39.989" title="Search Plazi for locations around (long 178.214/lat -39.989)">Hawkes Bay</a> shelf, 39.989°S, 178.214°E, 767 m, 09 Feb 2017  .</p><p>Distribution.</p><p>Known only from the type locality, Seamount 986 off Hawkes Bay shelf, east of North Island, New Zealand (Fig. 4A).</p><p>Habitat.</p><p>Attached to hard substratum; depth 767-783 m (Fig. 4B).</p><p>Description.</p><p>Morphology of the holotype and paratype a thick-walled, tubular sponge, attached to hard substratum by a narrow base (Fig. 4B). A round osculum of moderate size is terminal and opens into a deep atrial cavity. The margin is sharp and there are indications of sparse diactin marginalia in deck images, but we have been unable to verify them in the material at hand. The dermal surface has a dense covering of raised, prostal, hypodermal pentactins (Fig. 4C, D, I) projecting up to 1 cm from the surface proper. There is indication in some of the deck images of long diactins projecting sparsely up to 6 cm from the dermal surface, especially basally, but these may be choanosomal diactins pulled out during collection; we have not found such large diactins in the material we had for examination. Dimensions of the holotype are ~ 13.3 cm high, 7.0 cm wide, and 10.8 (9.2-13.3) (n = 9) mm in body wall thickness; the osculum is 2.2 cm in diameter in situ. The paratype is 19.5 cm high, 13.4 cm wide, and body wall is 7.4 (5.5-9.3) (n = 11) mm in thickness. The osculum is 4.2 cm in diameter in situ. Texture is soft, compressible, and resilient, neither hard nor fragile. Surface of the dermal side is covered by a thick layer of projecting hypodermal pentactins (Fig. 4E). The dermal lattice is torn apart, and dermalia reside in preserved specimens as attached flakes on the hypodermalia (Fig. 4G). The atrial layer retains the atrial lattice covering smaller apertures (Fig. 4F, H); no large megascleres project into the atrium. Colour in life is transparent white, preserved in ethanol is medium brown (Fig. 4C).</p><p>Skeleton. Choanosomal skeleton consists of a loose, vacuolar network of thin choanosomal diactins, large choanosomal hexactins, and the thicker proximal rays of the hypodermal pentactins. There is no evidence of fusion between any spicules. Microscleres are scattered evenly throughout the choanosome. Ectosomal skeleton of the dermal side consists of abundant prostal pentactins supporting a delicate lattice of hexactine, pentactine, and stauractine dermalia. The atrial ectosome lacks hypoatrial pentactins but has bands of diactins that support the atrial lattice of hexactins, providing greater support than available to the dermal lattice. Microscleres are present as in the choanosome.</p><p>Spicules. Megascleres (Fig. 5; Table 2) are prostal hypodermal pentactins, choanosomal diactins, choanosomal hexactins, dermalia, and atrialia. Prostal hypodermal pentactins (Fig. 5A) are mostly large, raised paratropal forms (90% of 68 scored) with long, very curved tangential rays, but some regular, crucial forms occur (10%) in smaller forms especially near the margin. Tangential rays are 1.7  × the shorter, straighter proximal rays. The spicules are smooth except for the rough sharp tips. Choanosomal diactins (Fig. 5B) are straight or strongly curved, usually with undetectable central swellings; they are smooth except for the rough, slightly inflated tips. Choanosomal hexactins (Fig. 5C) are large forms with strongly curved or nearly straight, nearly equal length rays, which are otherwise similar to those of the hypodermalia. Dermalia (Fig. 5D) are entirely spined and consist of stauractins (31% of 387 scored) and similar forms with reduced fifth ray (subpentactins) or both fifth and sixth rays in one axis (subhexactins) (64%) with a few (1-2%) as tauactins, diactins and paratetractins. It was not possible to differentiate the subpentactins and subhexactins either wet in dishes or mounted spicule microscope slides. Tips are either rounded or more often sharp. Atrialia (Fig. 5E) are entirely spined and mostly subhexactins (71% of 125 scored) with one ray reduced or hexactins (26%) with all rays of nearly equal length; a few (1-2%) are stauractins and tauactins. Ray tips are sharp-pointed.</p><p>Microscleres (Fig. 5; Table 2) are oxyhexasters and their variants, with hemioxyhexasters being the most common, and anisodiscohexasters. Oxyhexasters and hemioxyhexasters (Fig. 5F, G) have very short smooth primary rays and long straight secondary rays entirely ornamented with small, reclined spines. Secondary rays on each primary ray vary from 1-4. Anisodiscohexasters (Fig. 5H) are spherical with stellate discs with 4-6 marginal claws on the ends of terminal rays. Primary rays are smooth and end in strobiloid discs with a short central projecting knob. Each primary strobilum supports 30-40 terminal rays with undulating, probably helically coiled, finely rough shafts of unequal lengths. Terminal discs vary in diameter with shaft length, the longer shafts carrying the larger discs, e.g., a series 1.7, 2.5, 3.1, 3.4, 3.6, 5.4, 6.9  µm diameter for shafts 15.0, 20.5, 23.5, 27.3, 32.0. 33.4, 37.1  µm in length. These spicules look very different in LM (lower image) and SEM (upper image) due to collapse of the rays during drying for SEM and support of them by balsam in LM.</p><p>Etymology.</p><p>Named for the tubular morphology of the sponge ( Nubes tubulata, tubular; Latin).</p><p>Remarks.</p><p>The characters of these two New Zealand specimens are inconsistent with the present diagnoses of all  Rossellinae genera except  Vitrollula Ijima, 1898. They differ, however, from those of  V. fertilis Ijima, 1898, the only species in the genus, in characters not used as diagnostic. These are that  V. fertilis has a smooth surface without raised hypodermalia, but the two new specimens have a bristly surface with raised hypodermalia, and that the discohexasters of  V. fertilis are isodiscohexasters while those of the new species are anisodiscohexasters. In view of these differences, we opt not to include the new species in  Vitrollula nor to change the diagnosis of that genus at this time. We choose to erect a new genus in  Rossellinae with characters of this and the following second species described below, and designate this species as  Nubes tubulata gen. nov., sp. nov.</p></div>	https://treatment.plazi.org/id/D0CFA768826F5F16B8404AB1356975B9	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
38826F237EEE54DFBD5D86AE99F25A88.text	38826F237EEE54DFBD5D86AE99F25A88.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Rossellinae Bolivar 1906	<div><p>Rossellinae Schulze, 1885</p><p>Diagnosis.</p><p>As for family.</p><p>Remarks.</p><p>This subfamily is clearly not monophyletic (Dohrmann et al. 2017) and retained here for historical reasons only.</p></div>	https://treatment.plazi.org/id/38826F237EEE54DFBD5D86AE99F25A88	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
44B4A7D7A3735F1C8A3E1ABDD7800305.text	44B4A7D7A3735F1C8A3E1ABDD7800305.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Scyphidium australiense Tabachnick, Janussen & Menschenina 2008	<div><p>Scyphidium australiense Tabachnick, Janussen &amp; Menschenina, 2008</p><p>Figs 8, 9</p><p>Note.</p><p>From the ending of its name,  Scyphidium is a neuter noun, and thus  S. australiensis (as originally named by Tabachnick et al. 2008) should be  S. australiense . This is borne out by the names of conspecifics that are also adjectives (e.g.,  S. chilense,  S. septentrionale,  S. tuberculatum) (J. Rosser, pers. comm.). We hereby make that change and use the corrected name throughout this work.</p><p>Type and locality (not examined).</p><p>Holotype - NIWA 155561, RV Sonne Stn SO17/80 (NZOI Stn Z3951B), Chatham Rise, 43.553°S, 179.457°E, 409 m, 10 Apr 1981 [Originally cited in Tabachnick et al. (2008) as WAM (p14), RV Soela Stn SO 17-80, 43°33.10'-33.05'S, 179°27.25'-27.08'E, depth unknown].</p><p>Material examined.</p><p>NIWA 126237, RV Sonne, Stn SO254/77ROV14_BIOBOX02, Pegasus Canyon slope, off Christchurch shelf, 43.2927361°S, 173.6066742°E, 853 m, 20 Feb 2017.</p><p>Distribution.</p><p>Chatham Rise and Pegasus Canyon slope, off Christchurch shelf Christchurch shelf, New Zealand (Fig. 8A).</p><p>Habitat.</p><p>Attached to hard substratum; depth 409-853 m.</p><p>Description.</p><p>Body form is a heavy-looking, thick-walled, club-shaped, pendant sponge with a narrow basal attachment, widening gradually to a hemispherical rounded terminal end (Fig. 8B, C) where a large osculum is centrally located. The osculum opens into a deep atrial cavity (Fig. 8D). The margin is sharp-edged with indication of sparse marginalia that do not differ from prostal diactins of the lower body. The external surface of the upper body is fairly smooth, without prostalia, but the lower half is conspicuously conulose with long prostal diactins projecting in small groups from conules (Fig. 8E). We did not have access to the basal attachment so we cannot comment on the basidictyonalia. Dimensions of the specimen are 27.6 cm in height, 11.7 cm in maximum width, 5.7-10.9 cm in diameters of the osculum, 10.0 mm in maximum wall thickness, 8.3 mm in length of projecting part of prostal diactins. Texture is firm but compressible and resilient, neither soft nor fragile. Surface of the dermal side is covered by an intact lattice of dermalia (Fig. 8G) consisting mostly of pentactins (98% of 302 assayed), and a few stauractins and diactins (1% each). The upper body surface is fairly smooth, but the lower body is covered with conspicuous conules up to 3.2 mm high, from which prostal diactins project in small groups of one to four. One large pentactin was found but it was broken and assumed to be foreign. The atrial surface is covered by a felt-like layer of disarranged atrialia (Fig. 8H) composed of hexactins (57% of 168 assayed), pentactins (20%), paratetractins (8%), diactins (6%), stauractins (5%), and triactins (3%). Colour in life is very pale brown, preserved in ethanol is medium brown.</p><p>Skeleton. Choanosomal skeleton consists of a tight series of macroscopic partitions of inhalant and exhalant channels running perpendicular to the body surfaces (Fig. 8F). They consist of networks of choanosomal diactins and microscleres and in the lower body the proximal ends of the prostal diactins. A few small patches of fused choanosomal diactins occur but these are too rare to provide significant support to the body. Ectosomal skeleton of the dermal side consists of the robust lattice of pentactine dermalia and in the lower body the projecting prostal diactins. The atrial ectosomal skeleton consists of the felt-like lattice of atrialia and the supporting layer of hypoatrial diactins.</p><p>Spicules. Megascleres (Fig. 9; Table 4) are prostal diactins, choanosomal diactins, dermalia, and atrialia. Prostal diactins (Fig. 9A) are large, curved, and smooth spicules with rounded proximal tips either smooth or bearing very low suggestions of obsolete spines. They have neither an axial cross nor central swellings. Distal tips are invariably broken off. Choanosomal diactins (Fig. 9B) come in three distinct forms. The larger ones over 2 mm long are straight or slightly curved or sinuous and are smooth except for the patches of spines at the rounded or abruptly pointed tips. Those between 1 and 2 mm long have sharp tips and longer spines on the tip patches. The shortest, less than 1 mm long, are entirely spined with sharp tips and often with a central tyle or four knobs. Dermalia (Fig. 9C) are thick stubby pentactins, entirely profusely spined without a knob of a sixth ray. Atralia (Fig. 9D) are highly diverse; the most common hexactins have thinner and less densely spined rays than the dermalia. Pentactin atrialia are very similar to the dermal pentactins but have a knob in place of the sixth ray. Paratropal atrialia have rays similar to the hexactine atrialia. Spheres (Fig. 9E) are common and here considered megascleres.</p><p>Microscleres (Fig. 9; Table 4) are two types of discohexasters and one type of oxyhexaster and its variants, rare hemioxyhexasters and oxyhexactins. Discohexasters 1 (Fig. 9F) are spherical with very short smooth primary rays, each supporting 3.5 (2-5) thick secondary rays ornamented with reclined spines. Terminal discs invariably have six stout marginal teeth. Discohexasters 2 (Fig. 9G) are smaller spherical forms with each smooth primary ray supporting 6.3 (5-8) thinner terminal rays; the terminal discs also invariably have 6 marginal teeth. Oxyhexasters (Fig. 9H) are stout spherical forms with each short smooth primary ray supporting 3.2 (3-5) fully developed secondary rays ornamented with dense reclined spines and ending in sharp tips. Each oxyhexaster also has 2-12 poorly developed secondary rays only a few micrometres in length. Only one hemioxyhexaster and three oxyhexactins, all of a similar size and ray characters as the oxyhexaster, were discovered in microsclere surveys.</p><p>Remarks.</p><p>The characters of this new specimen agree with those in the original description of  S. australiense by Tabachnick et al. (2008) except for the absence of prostal diactins and sphere megascleres in the latter, and absence of the rare discohexactins in the former. Absence of prostal diactins in the holotype is likely attributable to it being a distal fragment where we also found no prostalia in the new specimen. Spheres appear to be spicules of erratic occurrence in hexactinellids and are unlikely to be of phylogenetic significance. Absence of discohexactins in the new specimen is not considered an important difference. Sizes and shapes of the common microscleres are similar enough in both specimens to conclude that they are from specimens of the same species. It is somewhat surprising that the authors of this species assigned it to the genus  Scyphidium without altering the generic diagnosis to encompass it; we have done so here.</p><p>Prior to the discovery of a second specimen of  S. australiense here, there was considerable doubt as to the true type locality of the holotype described by Tabachnick et al. (2008). This work focused on hexactinellid sponges "sampled mainly off the Australian West Coast", and the holotype was named "after the type locality of this species", i.e., Australia. However, the latitude and longitude for RV Soela Stn SO 17-80 (43°33.10'-33.05'S, 179°27.25'-27.08'E) placed the type locality as on the north central Chatham Rise on the east coast of New Zealand. The Western Australian Museum (WAM) has confirmed that the RV Soela carried out fieldwork off western and northern Australia, and that the material covered in Tabachnick et al. (2008) was sent to the MNHN to be worked on taxonomically. Unfortunately, WAM has no details for "RV Soela Stn SO 17-80" (Jane Fromont, Western Australian Museum, pers. comm.), but interestingly, the specimen reported here, NIWA 126237, is also from Chatham Rise (Pegasus Canyon Slope, off Christchurch Shelf), intensifying the mystery surrounding the type locality of this species. Investigation of pre-2004 electronic records at NIC revealed that the specimen listed from station "RV Soela Stn SO 17-80", given in Tabachnick et al. (2008), was more likely to have been collected on the RV Sonne Cruise SO-17 on the Chatham Rise phosphorite deposits east of New Zealand (Von Rad 1984), because the NZOI Stn Z3951B from that cruise, a large grab with  Porifera listed in the Remarks column, has identical coordinates and similar station numbers. We are still unsure as to how the specimen reached  Tabachnick’s attention at the MNHN, and indeed, the whereabouts of the holotype, but we know that errors were made in translation of the station data from the specimen labels to this publication, and it is possible that the authors assumed that the RV Sonne representation of "Stn SO17/80" was just another RV Soela Stn, represented as SO 17-80 in the publication. The MNHN was temporarily closed for most of 2020 and the early months of 2021 due to measures of the French government to prevent the spread of COVID-19 (novel coronavirus disease), so the repatriation of this specimen was not able to be completed at time of publication.</p></div>	https://treatment.plazi.org/id/44B4A7D7A3735F1C8A3E1ABDD7800305	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
32450BE3C84B577F87E3509BD36F73C9.text	32450BE3C84B577F87E3509BD36F73C9.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Lanuginellinae Schulze 1900	<div><p>Lanuginellinae Gray, 1872</p><p>Diagnosis.</p><p>Basiphytous, rarely lophophytous, often pedunculate,  Rossellidae; dermalia hexactins, pentactins, stauractins, or diactins supported by large hypodermal pentactins; choanosomal spicules diactins, often supplemented by significant amount of hexactins; atrialia pentactins or hexactins often supported by large hypoatrial pentactins; dermal and atrial hexactins and pentactins frequently pinular; prostalia, if present, pentactins or diactins; microscleres include strobiloplumicomes, which may be absent in some species, oxy-, onycho-, or disco-tipped forms (hexasters, hemihexasters, hexactins); microdiscohexasters absent (after Dohrmann et al. 2017).</p></div>	https://treatment.plazi.org/id/32450BE3C84B577F87E3509BD36F73C9	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
47AD038379F75B26B545236AD6F2F5D1.text	47AD038379F75B26B545236AD6F2F5D1.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Scyphidium Schulze 1900	<div><p>Scyphidium Schulze, 1900</p><p>Diagnosis.</p><p>Body is saccular, basiphytous, sometimes rhizophytous. Choanosomal skeleton is composed of diactins. Hypodermal spicules, if present, are pentactins.  Prostalia, if present, are hypodermal pentactins and/or diactins. Dermalia are stauractins and/or pentactins in various combinations. Atrialia are mainly hexactins. Microscleres are discohexasters and oxyhexasters often with hemioxyhexasters and oxyhexactins; with two or three types of discohexasters, none as calycocomes. Among the larger is a spherical form with a restricted number of secondary rays (emended from Tabachnick 2002).</p><p>Remarks.</p><p>The genus diagnosis is emended of necessity, to accept  S. australiense Tabachnick, Janussen &amp; Menschenina, 2008 and  S. variospinosum sp. nov., described below.</p><p>Type species.</p><p>Scyphidium septentrionale Schulze, 1900.</p></div>	https://treatment.plazi.org/id/47AD038379F75B26B545236AD6F2F5D1	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
EB3D7FF2AE47592EA05364008B0FAA8F.text	EB3D7FF2AE47592EA05364008B0FAA8F.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Scyphidium Schulze 1900	<div><p>Scyphidium Schulze, 1900</p><p>Scyphidium australiense Tabachnick, Janussen &amp; Menschenina, 2008</p><p>Scyphidium variospinosum Reiswig, Dohrmann &amp; Kelly, sp. nov.</p></div>	https://treatment.plazi.org/id/EB3D7FF2AE47592EA05364008B0FAA8F	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
0984F0D27E075AFAA164DCFAC8FF3BB2.text	0984F0D27E075AFAA164DCFAC8FF3BB2.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Scyphidium variospinosum Reiswig, Dohrmann & Kelly 2021	<div><p>Scyphidium variospinosum Reiswig, Dohrmann &amp; Kelly sp. nov.</p><p>Figs 10, 11</p><p>Material examined.</p><p>Holotype NIWA 126279, RV Sonne Stn SO254/78ROV15_BIOBOX3-5, Wairarapa Slope, 41.619°S, 175.788°E, 1630.5 m, 21 Feb 2017. Paratype NIWA 126274, RV Sonne Stn SO254/78ROV15_BIOBOX1, Wairarapa Slope, 41.619°S, 175.788°E, 1675.1 m, 21 Feb 2017.</p><p>Distribution.</p><p>Known only from two locations on the Wairarapa Slope, New Zealand (Fig. 10A).</p><p>Habitat.</p><p>Attached to hard substratum; depth 1631-1675 m (Fig. 10B).</p><p>Description.</p><p>Morphology of the holotype and paratype is a thick-walled, club-shaped sponge with a narrow basal attachment, widening gradually to a hemispherical rounded terminal end where a large osculum is centrally located (Fig. 10B-E). The osculum opens into a deep atrial cavity. The margin is sharp-edged with indication of sparse marginalia that do not differ from prostal diactins of the general body wall. The external surface of the entire body is clean and conulose, with prostal diactins and hypodermal pentactins emanating from conules in small groups of 1-10. Dimensions of the holotype and paratype are, respectively, length 16.5 and 15.8 cm, width 9.5 and, excluding the lateral bulge, 9.5 cm, diameter of the osculum 6.4 and 6.6 cm, wall thickness 11.1 and 10.0 mm. Texture is soft, compressible, and resilient, but not fragile. Surface of the dermal side is conulose and bears a layer of prostal diactins projecting 12.5 (6.5-19.3) (n = 9) mm above the dermal surface, intermingled with a veil of prostal, hypodermal, thorned, paratropal pentactins (Fig. 10F, G) projecting 8.6 (7.2-10.0) (n = 9) mm above the surface. On the surface below is a lattice of overlapping dermalia of mostly pentactins (94% and 82% of 160 and 101 assessed) (Fig. 10H). The atrial surface bears a poorly preserved atrial lattice of mostly hexactins (94.7% and 94% of 133 and 131 assessed) (Fig. 10I) forming a cover over the exhalant apertures. Colour in life and preserved is very pale brown.</p><p>Skeleton. Choanosomal skeleton is composed of choanosomal diactins without detectable macroscopic or microscopic organisation. No evidence of spicule fusion was noted in either specimen. Microscleres are scattered throughout the choanosome. Ectosomal skeleton of the dermal side consists of the prostal diactins and projecting veil of thorned pentactins. The dermal surface is covered by a robust lattice of mostly pentactine dermalia. The atrial ectosome consists of the felt-like disorganised lattice of mostly hexactine atrialia and the supporting layer of hypoatrial diactins.</p><p>Spicules. Megascleres (Fig. 11; Table 5) are prostal diactins, prostal hypodermal pentactins, choanosomal diactins, dermalia, and atrialia. Prostal diactins (Fig. 11A) are large, curved, and smooth spicules with rough subterminal patches and round tips. They have neither axial crosses nor central swellings. Prostal hypodermal pentactins (Fig. 11B) are large spicules with proximal rays ~ 1.4 times the length of tangential rays; the tangential rays are mainly paratropal, occasionally orthotropal. Both tangential and proximal rays have smooth rounded tips, but only tangential rays bear large thorns on the middle halves of the rays. Choanosomal diactins (Fig. 11C) occur in two distinct forms. Large ones&gt; 2 mm in length are straight, slightly curved or sinuous, and are smooth except for rough subterminal areas; tips are rounded or abruptly pointed. Small forms &lt;2 mm in length are entirely spined, have sharp tips and often four central knobs or a single tyle. Dermalia (Fig. 11D) are thick stubby pentactins, entirely and profusely spined without a knob of a sixth ray. Atralia (Fig. 11D) are most commonly hexactins, with rays longer, thinner, and less profusely spined than those of dermalia.</p><p>Microscleres (Fig. 11; Table 5) are three types of discohexasters and two types of oxyhexasters and their variants, rare hemioxyhexasters and oxyhexactins. The centrum in all categories tends to be varyingly swollen to the extent that the spicules approach asteroid forms. The oxyhexasters are extremely difficult to separate into types due to presence of intermediates. Discohexasters 1 (Fig. 11F) are semi-stellate with very short smooth primary rays, each supporting 4-8 gently curved secondary rays ornamented with reclined spines; terminal discs invariably have eight stout marginal teeth. Discohexasters 2 (Fig. 11G) are very slightly smaller spherical forms with each smooth primary ray supporting 2-4 straight thick terminal rays ornamented with reclined spines; the terminal discs have 5-9 marginal teeth. Discohexasters 3 (Fig. 11H) are small semi-stellate forms like discohexasters 1, with very short, smooth primary rays, each supporting 7-11 thin, curved, rough secondary rays, each ending in a terminal disc with 4-9 marginal teeth. Oxyhexasters 1, including hemioxyhexasters (Fig. 11H), are stout spherical forms with each short smooth primary ray supporting 1-3 secondary rays ornamented with dense reclined spines and ending in sharp tips. Oxyhexasters 2 (no SEM image available) are forms with very thin secondary rays and often broken; they have diverse characters but are not considered immature forms of oxyhexasters 1. The centres are very small or swollen to globular form and the distal ends of the primary rays are either very thin or globular, each primary end supports two or three thin secondary rays that appear totally smooth. We are not confident in recognising this as a spicule category since the only practical character in defining it is the thinness of the secondary rays and size. Oxyhexactins (no SEM available) are rare: only four have been verified in spicule surveys. They have characteristics of oxyhexasters 1 in the stoutness and ornamentation of their rays.</p><p>Etymology.</p><p>Named for the large, irregularly thorned hypodermal pentactins, that project from the body of this species ( Scyphidium variospinosum, with irregular thorns; Latin).</p><p>Remarks.</p><p>The characters of these new specimens agree with the revised diagnosis of  Scyphidium (see above) but differ from those of all eight recognised species of that genus. None has raised, thorned, hypodermal pentactins as prostalia. Only three species,  S. tuberculatum (Okada, 1932),  S. jamatai Tabachnick, 1991, and  S. australiense Tabachnick, Janussen &amp; Menschenina, 2008 (see above) have dermalia as mostly pentactins and atrialia as mostly hexactins, in agreement with the two new specimens. The sizes of the discohexasters are considerably smaller in all three than those in the new forms described here. On the basis of these and other differences, we are confident that the two new specimens described here represent a new species, here designated as  Scyphidium variospinosum sp. nov.</p></div>	https://treatment.plazi.org/id/0984F0D27E075AFAA164DCFAC8FF3BB2	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
393B206ECD435721A5CFE8111EB41539.text	393B206ECD435721A5CFE8111EB41539.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Vazella Gray 1870	<div><p>Vazella Gray, 1870</p><p>Diagnosis.</p><p>Body is saccular, basiphytous. Choanosomal skeleton is composed of diactins. Hypodermal pentactins are raised, thorned paratropal pentactins.  Prostalia basalia and marginalia are monaxons (diactins). Dermalia are stauractins and pentactins. Atrialia are mainly hexactins. Discoid microscleres are microisodiscohexasters and microanisodiscohexasters; oxyoid microscleres are combinations of hexactins, hexasters, and hemihexasters (modified from Tabachnick 2002).</p><p>Remarks.</p><p>This modified diagnosis allows separation of the present genus,  Nubes gen. nov., from  Vazella on the basis of lack of thorned hypodermalia and presence of discoid microscleres that are not anisodiscohexasters in the former. Furthermore, molecular phylogenetic results do not support a close relationship of the two genera (MD, unpubl. results).</p></div>	https://treatment.plazi.org/id/393B206ECD435721A5CFE8111EB41539	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Reiswig, Henry M.;Dohrmann, Martin;Kelly, Michelle;Mills, Sadie;Schupp, Peter J.;Woerheide, Gert	Reiswig, Henry M., Dohrmann, Martin, Kelly, Michelle, Mills, Sadie, Schupp, Peter J., Woerheide, Gert (2021): Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species. ZooKeys 1060: 33-84, DOI: http://dx.doi.org/10.3897/zookeys.1060.63307, URL: http://dx.doi.org/10.3897/zookeys.1060.63307
