Hymedesmia (Hymedesmia) noramaloneae Goodwin & Berman & Hendry 2019, sp. nov.

Hymedesmia ( Hymedesmia ) noramaloneae sp. nov. (Figure 9, Table 6) lsid:zoobank.org:act: D3D74DBA-258E-4FAB-8E5F-343DD3FB562B Type material. Holotype: BELUM. Mc 2015.701 Vieugue Island (65°38.758’S, 65° 12.540’W), depth 10–22 m; collected by C. Goodwin and E. Priestley, 23/02/2015. Paratype: BELUM....

Full description

Bibliographic Details
Main Authors: Goodwin, Claire E., Berman, Jade, Hendry, Katharine R.
Format: Text
Language:unknown
Published: Zenodo 2019
Subjects:
Biodiversity
Taxonomy
Animalia
Porifera
Demospongiae
Poecilosclerida
Hymedesmiidae
Hymedesmia
Hymedesmia noramaloneae
Antarctic
Antarctic Peninsula
Kerguelen
Charcot
South Georgia Island
Malone
Priestley
Goodwin
Grotto
Booth Island
Grotto Island
Port Charcot
Antarc*
Antarctica
Antarctique*
Online Access:https://dx.doi.org/10.5281/zenodo.5584974
https://zenodo.org/record/5584974
Description
Summary:Hymedesmia ( Hymedesmia ) noramaloneae sp. nov. (Figure 9, Table 6) lsid:zoobank.org:act: D3D74DBA-258E-4FAB-8E5F-343DD3FB562B Type material. Holotype: BELUM. Mc 2015.701 Vieugue Island (65°38.758’S, 65° 12.540’W), depth 10–22 m; collected by C. Goodwin and E. Priestley, 23/02/2015. Paratype: BELUM.Mc2015.722and BELUM. Mc 2015.726 Port Charcot, Booth Island (65°03.853’S, 64° 01.868’W), depth 6–16 m; collected by C. Goodwin and E. Priestley, 23/02/2015. Other specimens: BELUM. Mc 2015.601 Grotto Island, Verdansky Base (Site 1) (65°14.615’S, 64° 15.019’W), depth 14–24 m. BELUM. Mc 2015.734 Port Charcot, Booth Island (65°03.853’S, 64° 01.868’W), depth 6–16 m. Diagnosis. Hymedesmia ( Hymedesmia ) with tornote ectosomal spicules (245–358 µm long) and two categories of acanthostyles (267–633 and 137–208 µm long), the larger of which are only spined for their basal third. Etymology. Named after Nora Malone, daughter of Jade Berman, who was born a few months after the expedition. External morphology. In situ appearance (Figure 9A): Very thin pale yellow encrusting sponge forming patches up to 20 cm in diameter. Surface covered with an irregular pattern of veins and pores sieves—pore sieves do not have rims so are less distinct than in many other Hymedesmia species. Preserved appearance. Firm white crust, 1 mm thick. Skeleton (Figure 9B): Hymedesmoid with a basal layer of primary and secondary acanthostyles and ascending columns (5–15 spicules thick) of tornotes. Chelae sparsely scattered throughout tissue. Spicules (for measurements of all specimens see Table 6). Primary acanthostyles (Figure 9C). With a tylote head. The head and up to the lower 1/3 of the shaft are spined with small conical spines but the majority of the shaft is smooth. The shaft is often slightly curved. Secondary acanthostyles (Figure 9D). With a tylote head. Entirely spined with small conical spines but these are densest at the head and become slightly sparser towards the tip. Ectosomal tornotes (Figure 9E, F): Anisotornotes, sometimes with one slightly rounded end so style-like in form, others with two pointed ends. Arcuate chelae (Figure 9G): Normal arcuate chelae with a slight bend in the shaft and three, fairly short, rounded alae on each end. Remarks. Of the 13 species of Hymedesmia ( Hymedesmia ) recorded from the region (see Goodwin et al. 2012) three possess two categories of acanthostyles and have tornotes as ectosomal spicules: H. antarctica Boury-Esnault & Van Beveren, 1982, H. mariondufresni Boury-Esnault & Van Beveren 1982, and H. barnesi Goodwin, Brewin & Brickle 2012. H. barnesi can be distinguished as it has smaller primary acanthostyles (272–392 µm) and is bright orange when living. Boury-Esnault & Van Beveren (1982) note that the primary difference between H. antarctica and H. mariondufresni is that the tornotes of the latter are shorter than the acanthostyles, whilst the reverse is true for the former. On this basis our specimen would be closer to H. mariondufresni , the tornotes of our species are certainly much shorter than those in H. antarctica (422–593 µm). However, the primary acanthostyles of H. mariondufresni are smaller and thinner than those in our specimens (243–512 by 13–25 µm) and only smooth at the end of the shaft, whereas the primary acanthostyles of our specimens are normally only spined for the basal third. Distribution. Currently only known from the type and holotype localities. : Published as part of Goodwin, Claire E., Berman, Jade & Hendry, Katharine R., 2019, Demosponges from the sublittoral and shallow-circalittoral (<24 m depth) Antarctic Peninsula with a description of four new species and notes on in situ identification characteristics, pp. 461-508 in Zootaxa 4658 (3) on pages 480-482, DOI: 10.11646/zootaxa.4658.3.3, http://zenodo.org/record/3376028 : {"references": ["Goodwin, C., Brewin, P. E. & Brickle, P. (2012) Sponge biodiversity of South Georgia island with descriptions of fifteen new species. Zootaxa, 3542, 1 - 48. https: // doi. org / 10.11646 / zootaxa. 3542.1.1", "Boury-Esnault, N. & Van Beveren, M. (1982) Les Demosponges du plateau continental de Kerguelen-Heard. Comit national francais des recherches antarctiques, 52, 1 - 175."]}

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