Crateromorpha (Neopsacas) variata Tabachnick, 2002
publication ID |
https://doi.org/ 10.5281/zenodo.176494 |
DOI |
https://doi.org/10.5281/zenodo.5626074 |
persistent identifier |
https://treatment.plazi.org/id/03978792-FFE1-A35E-0FD7-F8FDFB4DFC94 |
treatment provided by |
Plazi |
scientific name |
Crateromorpha (Neopsacas) variata Tabachnick, 2002 |
status |
|
Crateromorpha (Neopsacas) variata Tabachnick, 2002 View in CoL ( Fig. 1 View FIGURE 1 , 2 View FIGURE 2 ; Tab. 1 View TABLE 1 )
Synonymy
Crateromorpha (Neopsacas) variata Tabachnick, 2002: 1481 View in CoL .
Material examined
Holotype: IORAS 5/2/404, R.V. ‘Academic Kurchatov’, 6 voyage, sta. 444, 5.10.1969, 40° 35.3’–36.2’ N, 29° 29.5’–29.4’ W (Mid-Atlantic Ridge), depth 2780- 2500 m.
Paratypes: IORAS 5/2/403, ibid.; IORAS 5/2/479 – R.V. ‘Academic Kurchatov’, 6 voyage, sta. 432, 40° 28.8’–28.5’ N, 29° 33.0’–32.5’ W, depth 2780–2900 m.
Additional studied material: IORAS 5/2/3119, R.V. ‘Academic Mstislav Keldysh’, 43 voyage, sta. 3988, submersible ‘Mir’, 44° 57.40’ N, 28° 0.90’ W, depth 2800 m. IORAS 5/2/3114, ibid. (Mid-Atlantic Ridge).
C. variata C. variata C. variata C. variata C. variata (Holotype, (Paratype, (Paratype, (Non type, (Non type, IORAS 5/2/404) IORAS 5/2/403) IORAS 5/2/479) IORAS 5/2/3114) IORAS 5/2/3119) Description
Body: Types have previously been described by Tabachnick (2002). The newly found specimen (5/2/ 3119) has the shape of a champagne-glass, lower part of the tubular peduncle broken. The body is 80 mm long, 80 mm in diameter with large atrial cavity, 60 mm deep, 60 mm in diameter in the upper part of the body. Walls are about 10 mm in thickness with many deep subdermal cavities 0.5–6 mm in diameter and canals beginning from the atrial surface. The dermal openings are covered by dermal layer made of regularly orientated dermal pentactins with square meshes between their tangential rays; atrial openings seems not to be covered by an atrial lattice. The peduncle is broken, its remnant is tubular, 50 mm long, 4 mm in diameter. The 5/ 2/3114 specimen is a small fragment 3–4 mm in thickness, it is likely a fragment from the margin of specimen 5/2/3119.
Spicules: Choanosomal spicules and the spicules of the peduncle are diactins, the latter are fused by numerous synapticula while other forms: triactins, paratetractins and pentactins could be rarely found anong the former. Investigations of new specimens (5/2/3119; 5/2/3114) allow us to revise the previous interpretation by Tabachnick (2002) of the construction of dermal/atrial skeleton. Dermalia and atrialia consist of similar spicules with similar spicule size. Dermalia and atrialia are spicules with rough rays and rounded outer ends. They are pentactins and derivatives with reduced rays, and commonly have a short proximal (or distal) ray; diactins are common, and rare hexactins may be also found. The pentactins form a layer over the subdermal cavities, but the dermal and atrial spicules do not seem to construct a continuous net, they do not overlap by their tangential rays. Hypodermal or hypoatrial pentactins are more or less regularly situated. The tangential rays of hypodermal pentactins are 0.038–0.448 mm long, the proximal ray is 0.053–0.304 mm long, their diameter is 0.01–0.05 mm. The ray of dermal diactin is 0.046–0.091/ 0.002–0.005 mm, usually these spicules have four rudimental tubercles in the middle. Atrial spicules are very similar to dermal ones. The atrial pentactins have tangential rays 0.068–0.388 mm long, distal ray 0.053–0.152 mm long, diameter is 0.008–0.03 mm. Atrial diactins have rays 0.018–0.167/ 0.004–0.006 mm. Hypodermal and hypoatrial pentactins have spines near the spicule centre. Tangential rays of dermal pentactins are 0.175–0.456 mm long, proximal ray is 0.091–1.041 mm long, diameter is 0.020–0.040 mm. Hypoatrial pentactins have tangential rays 0.076–0.646 mm long, distal ray is 0.038–1.011 mm long. Large numbers of hexactins similar to hypodermal/hypoatrial spicules were found as oscularia marginalia, which can be attributed to atrial surface rather than to dermal one in two of the newly found specimens (5/2/3119; 5/2/3114). The ray directed outside the body of these hexactins is 0.061–0.494 mm long, tangential rays are 0.099–0.243 mm long, the ray directed inside the body is 0.395–1.406 mm long, their diameters are about 0.015 mm.
The microscleres were described quite correctly before ( Tabachnick, 2002) but new findings allow addition the previous data. The large discohexactins and their derivatives have rays 0.058–0.115/ 0.004–0.007 mm. The small discohexactins and their derivatives have rays measuring 0.025–0.090/ 0.002–0.004 mm. The most common hemioxyhexasters, oxyhexactins, hemionychohexasters and onychohexactins are 0.036–0.133 mm in diameter. The regular oxyhexasters with numerous secondary rays are 0.036–0.101 mm in diameter with primary rosette 0.011–0.061 mm in diameter. The regular onychohexasters/discohexasters with numerous secondary rays are 0.054–0.101 mm in diameter with primary rosette 0.011–0.025 mm in diameter.
n | avg | min | max | std | n | avg | min | max | std | n | avg | min max std | n | avg | min | max | std | n | avg | min | max std | |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
L derm. pent. tang. ray | 6 | .258 | .167 | .312 | .0 62 | 7 | .293 | .0 38 | .448 | .129 | 25 | .332 | .251 | .395 | .0 33 | |||||||
L derm.pent. prox. ray | 1 | .122 | .122 | .122 | 25 | .101 | .0 53 | .304 | .0 56 | |||||||||||||
L derm. hex., para- tetrac., stauractin ray | 6 | .105 | .0 53 | .190 | .0 46 | 12 | .0 77 | .0 38 | .137 | .0 24 | ||||||||||||
L derm. diactin ray | 6 | .0 71 | .0 46 | .0 91 | .0 16 | |||||||||||||||||
L atrial pent. tang. ray | 19 | .174 | .0 68 | .319 | .0 71 | 14 | .268 | .182 | .388 | .0 64 | ||||||||||||
L atrial pent. dist. ray | 3 | .0 94 | .0 53 | .152 | .0 52 | |||||||||||||||||
L.atrial hex., para- tetrac., stauract. ray | 8 | .0 77 | .0 41 | .176 | .0 42 | 18 | .0 79 | .0 45 | .207 | .0 35 | 1 | .0 85 | .0 85.0 85 | 3 | .0 22 | .0 14 | .0 29 | .0 0 7 | 25 | .155 | .0 76 | .327.0 63 |
L atrial diactin ray | 8 | .103 | .0 76 | .167 | .0 28 | 17 | .0 81 | .0 61 | .167 | .0 24 | 7 | .0 24 | .0 18 | .0 34 | .0 0 6 | 25 | .0 75 | .0 41 | .107.0 21 | |||
L hypoderm. pentac. tang. ray | 25 | .325 | .213 | .441 | .0 55 | 20 | .357 | .228 | .456 | .0 71 | 12 | .220 | .380.0 57 | 25 | .255 | .175 | .357 | .0 48 | 25 | .327 | .190 | .441.0 50 |
L hypoderm. pentac. prox. ray | 25 | .695 | .152 | .897 | .164 | 17 | .675 | .380 | .836 | .130 | 13 | .755 | .494.973.126 | 10 | .433 | .319 | .532 | .0 74 | 25 | .714 | .0 91 | 1.04.212 1 |
L hypoatr. pent. tang. ray | 20 | .213 | .114 | .365 | .0 68 | 11 | .348 | .182 | .646 | .117 | 24 | .273 | .205 | .365 | .0 39 | 25 | .248 | .0 76 | .380 0.63 | |||
L hypoatr. pent. dist. ray | 20 | .472 | .137 | .851 | .191 | 11 | .621 | .365 | .836 | .167 | 25 | .639 | .266 | 1.01 | .180 | 25 | .407 | .0 38 | .631.106 | |||
L hypoatr. hex. ray directed outside body | 25 | .222 | .0 61.494.144 | 11 | .149 | .0 61 | .334 | .116 | ||||||||||||||
L hypoatr. hexa. tang. ray | 25 | .181 | .0 99.220.0 29 | 10 | .201 | .152 | .243 | .0 32 | ||||||||||||||
L hypoatr. hexa. ray directed inside body | 24 | .705 | .395 1.40.281 6 | 12 | .688 | .403 | 1.36 8 | .256 | ||||||||||||||
L large discohexactins & derivatives ray | 20 | .0 94 | .0 77 | .115 | .0 0 9 | 20 | .0 75 | .0 58 | .0 94 | .0 11 | 20 | .0 95 | .0 85.108.0 0 7 | |||||||||
L small discohexactins & derivatives ray | 20 | .0 33 | .0 25 | .0 38 | .0 0 3 | 20 | .0 43 | .0 31 | .0 58 | .0 0 8 | 20 | .0 47 | .0 34.0 68.0 0 8 | 4 | .0 36 | .0 32 | .0 41 | .0 0 4 | 25 | .0 71 | .0 58 | .0 90.0 0 8 |
D hemidiscohexaster | 20 | .0 66 | .0 54 | .0 94 | .0 10 | 20 | .0 89 | .0 61 | .133 | .0 18 | 20 | .0 80 | .0 58.108.0 12 | 13 | .0 71 | .0 65 | .0 86 | .0 0 7 | 25 | .0 68 | .0 58 | .0 83.0 0 6 |
d hemidiscohexaster | 20 | .0 15 | .0 11 | .0 22 | .0 0 4 | 20 | .0 17 | .0 11 | .0 22 | .0 0 2 | 13 | .0 18 | .0 11.0 29.0 0 4 | 25 | 0.15 | 0.07 | .0 32 | .0 0 5 | ||||
D oxyhexac., onycho- hexac. & derivatives | 20 | .0 90 | .0 65 | .108 | .0 12 | 20 | .0 99 | .0 76 | .130 | .0 13 | 20 | .0 96 | .0 79.115.0 10 | 25 | .0 88 | .0 65 | .104 | .0 0 8 | 25 | .0 83 | .0 50 | .108.0 11 |
D oxyhemihexaster & onychaster | 20 | .0 89 | .0 65 | .108 | .0 0 9 | 20 | .0 90 | .0 72 | .130 | .0 14 | 20 | .0 87 | .0 65.108.0 10 | 25 | .0 88 | .0 65 | .112 | .0 0 9 | 25 | .0 85 | .0 65 | .0 97.0 10 |
d oxyhemihexaster & onychaster | 20 | .0 16 | .0 11 | .0 18 | .0 0 2 | 20 | .0 15 | .0 11 | .0 18 | .0 0 2 | 20 | .0 15 | .0 11.0 18.0 0 2 | 25 | .0 16 | .0 11 | .0 22 | .0 0 3 | 25 | .0 16 | .0 11 | .0 20.0 0 2 |
D regular oxyhexaster | 4 | .0 52 | .0 43 | .0 61 | .0 0 9 | 20 | .0 53 | .0 40 | .101 | .0 13 | 2 | .0 58 | .0 47.0 68.0 15 | 25 | .0 60 | .0 47 | .0 90 | .0 10 | 25 | .0 54 | .0 36 | .0 72.0 0 7 |
d regular oxyhexaster | 4 | .0 16 | .0 11 | .0 22 | .0 0 5 | 20 | .0 18 | .0 11 | .0 61 | .0 10 | 5 | .0 17 | .0 14.0 22.0 0 3 | 25 | .0 18 | .0 13 | .0 29 | .0 0 4 | 25 | .0 16 | .0 0 9 | .0 22.0 0 2 |
D regular onychohex./ discohex. | 25 | .0 79 | .0 54 | .101 | .0 12 | 3 | .0 97 | .0 90.101.0 0 6 | 25 | .0 77 | .0 65 | .0 90 | .0 0 7 | 25 | .0 76 | .0 61 | .0 90.0 0 6 | |||||
d regular onychohex./ discohex. | 25 | .0 18 | .0 11 | .0 25 | .0 0 4 | 3 | .0 18 | .0 18.0 18.0 0 0 | 25 | .0 19 | .0 11 | .0 25 | .0 0 4 | 25 | .0 18 | .0 11 | .0 22.0 0 3 |
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.
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
|
Genus |
Crateromorpha (Neopsacas) variata Tabachnick, 2002
Menshenina, Larisa L., Tabachnick, Konstantin R. & Janussen, Dorte 2007 |
Crateromorpha (Neopsacas) variata
Tabachnick 2002: 1481 |