Latrunculia (Latrunculia) verenae Hajdu, Desqueyroux-Faúndez, Carvalho, Lôbo-Hajdu and Willenz, 2013

Latrunculia (Latrunculia) verenae Hajdu, Desqueyroux-Faúndez, Carvalho, Lôbo-Hajdu and Willenz View in CoL sp. nov.

( Figs. 6C View FIGURE 6 , 7C View FIGURE 7 , 8 View FIGURE 8 AM–BD, 9C; Tab 6 View TABLE 6 )

Latrunculia lendenfeldi Hentschel, 1914 View in CoL ; sensu Desqueyroux, 1976: 100, in part (non sensu Hentschel, 1914: 44; = L. (L.) basalis Kirkpatrick, 1908 View in CoL )

Type material. Holotype. IZUA-POR 146, Reñihué Fjord (42°32’46.26”S – 72°32’06.30”W, Chilean Patagonia ), 29 m depth, coll. Ph. Willenz and E. Hajdu, 25 May 2007 —fragments from the holotype in MNRJ 10843 View Materials , MHNG 62840 View Materials and RBINSc-IG 32235-POR 10843 GoogleMaps . Paratypes. MNRJ 10914 View Materials , Raul Marin , Pitipalena Fjord (43°45’53.22”S – 72°53’43.62”W, Chilean Patagonia), 30 m depth, coll. G. Försterra (sample 1475), 09 March 2007 —fragments from the paratype in MHNG 82686 View Materials and RBINSc-IG 32236-POR.10914. GoogleMaps MNRJ 10942 View Materials , Pitipalena Fjord (43°45.887’S – 072°53.727’W, Chilean Patagonia), 28 m depth, Coll. N. Reiff (sample 1082), 09 March 2007 —fragments from the paratype in MHNG 82687 View Materials and RBINSc-IG 32236-POR 10942 GoogleMaps .

Additional material ( L. lendenfeldi sensu Desqueyroux, 1976 , in part; = L. verenae sp. nov.) MHNG 62580 , Compu (approx. 42°51’57’’S – 73°43’9’’ W, Chiloe ). GoogleMaps

Diagnosis. Latrunculia (L.) verenae sp. nov. is the only species of Latrunculia (L.) in the Magellanic region with dull greenish live-colour, round pore fields on top of densely arranged papillae, a single category of acanthostyles (pauciacanthose styles), anisodiscorhabds with 3 or more spine whorls, and sanidaster-like anisodiscorhabds as microscleres.

Description ( Fig. 6C View FIGURE 6 ). Globular sponge (5.1 cm in maximum diameter), with conspicuous, regularly distributed, slightly elevated (2–3 mm), round inhalant papillae, with flat, slightly expanded apical pore-bearing surfaces (1.8–6.1 mm in diameter). Excurrent papillae, much less common, are composed of a cylindrical membrane with an apical osculum (up to 10 mm in diameter). Consistency is firm and rubbery. Live-colour is dullgreen, becoming brown or dark brown in ethanol. The holotype is now markedly shrunk, with 3.5 cm in maximum diameter, the papillae collapsed and folded onto the sponge surface, which appears rather lacunose and cerebriform.

Skeleton ( Fig. 7C View FIGURE 7 ). Ectosome in two layers, an external single layer palisade of mostly erect anisodiscorhabds and sanidaster-like anisodiscorhabds frequently piercing the surface, and a dense basal layer (ca. 250 µm thick) of megascleres, more longitudinally oriented in the ectosomal skeleton of the papillae, and more criss-crossed in the ectosome of the main sponge body. The apical portion of longitudinally compressed papillae (possibly exhalant) is abundantly pierced by megascleres, and has apparently no microscleres. The inhalant papillae have apical cribriporal areas with individual pores 35–90 µm in diameter. Choanosome markedly cavernous, with a loose reticulation of megasclere tracts (70–100 µm thick) fanning out towards the surface in some places. No specialised skeleton is seen around the many channels and lacunae.

Spicules ( Figs. 8 View FIGURE 8 AM–BD, 9C). Megascleres. Acanthostyles ( Figs. 8 View FIGURE 8 BA–BD), straight, slightly curved or sinuous, isodiametric, variably sharp apices, occasionally slightly polytylote closer to the apex, pauciacanthose, with short conical spines, generally slightly slanted towards the centre of the spicule; 311–400 µm long and 5–12 µm thick. A few bent or even crooked oxeotes (N=6, 420–500 µm long, 7.5–10 µm thick) were found in one of the paratypes ( MNRJ 10914 View Materials ) amidst hundreds of acanthostyles, and interpreted as malformations of the latter. Microscleres. Anisodiscorhabds ( Figs. 8 View FIGURE 8 AM–AZ, 9C): manubrium with thorns that are mostly smooth and sharp, but notably less prominent than observed in both preceding species; shaft frequently bearing isolated thorns of various dimensions; basal whorl more commonly made of isolated thorns, but these may coalesce basally forming one ( Fig. 8 View FIGURE 8 AZ) or two incipient plates ( Fig. 8 View FIGURE 8 AN, AT, 9C), or two unmarried half plates ( Fig. 8 View FIGURE 8 AY); median whorl composed of partially ( Figs. 8 View FIGURE 8 AM, AO–AQ) to well formed plates ( Figs. 8 View FIGURE 8 AT–AU, AZ, 9C), with thorns emerging from the external third of the disk, frequently with secondary spines—in aberrant forms ( Figs. 8 View FIGURE 8 AR– AS) the median whorl does not represent the thickest sector of the microsclere; subsidiary whorl, sometimes adjacent ( Fig. 8 View FIGURE 8 AN) or even indistinguishable ( Fig. 8 View FIGURE 8 AQ) from apical one, with large variably clustered thorns usually markedly bent towards the apex; apical whorl with thorns incised variably deep, often with secondary spination and an external denticulation; 38–50 µm long and 14–33 µm across, shaft 4–7 µm wide. Isolated thorns of relatively varied morphology may occur anywhere on the shaft of the anisodiscorhabds of the holotype, which coupled to the incipiency of some whorls may render a sanidaster appearance to the microsclere ( Fig. 8 View FIGURE 8 AP–AQ, AS), but not to the stage of permitting recognition of a second category of microscleres.

Distribution and ecology. The species is this far known only from a narrow latitudinal stretch on the northern sector of the Chilean fjords region (ca. 42°33’– 42°45’S), from depths of 28– 30 m. The species occurred in high diversity assemblages, albeit the considerable sedimentation observed from in situ pictures taken at Pitipalena Fjord (Försterra & Reiff, pers. comm.). In Reñihué it is surrounded by diverse organisms such as other sponges, cnidarians, bryozoa, cirripeds, bivalves

Etymology. “Verenae” honours Dr. Verena Häussermann, Scientific Director of the Huinay Scientific Field Station, for her outstanding contribution towards our knowledge of Chilean fjords’ biota, as well as her friendly welcome in our several visits to the field station.