Gesaia

Gesaia View in CoL sp.

( Fig. 1 View FIGURE 1 )

Material examined. AM W.47551, Queensland, Osprey Island, 14°40'S, 145°26'E, 6–15 m, plankton tow, 7 Oct 1979, larva on SEM stub.

Description. Colour pattern. Preserved specimen lacking pigmentation.

Body. Larva almost spherical in shape, 650 µm long and 550 µm maximum width excluding chaetae and paleae; with four clearly demarcated segments corresponding to the parathoracic region (chaetigers 3–6).

Operculum. Operculum completely divided into two free short lobes with distal ends nearly perpendicular to longitudinal body axis ( Fig. 1 View FIGURE 1 A–C). Outer row with 8–10 paleae on each lobe. Outer paleae circular in cross section at base, tapering distally ( Fig. 1 View FIGURE 1 A–C); shaft ornamented for most of its length with thecae as compact rings with smoothly parallel edges ( Fig. 1 View FIGURE 1 E). Inner row of paleae with 6–8 paleae on each lobe ( Fig. 1 View FIGURE 1 A–C), with stout bases (thicker than outer paleae) and either ellipsoid or circular cross section at base ( Fig. 1 View FIGURE 1 B, G), distally tapering, hollowed, with truncated tip ( Fig. 1 View FIGURE 1 F); smooth for about half of their length, and distally ornamented with thecae as compact rings with irregular edges proximately, becoming parallel towards the tip ( Fig. 1 View FIGURE 1 F). Opercular papillae not developed or not observed. One pair of stout nuchal hooks, strongly recurved; margins smooth without limbations ( Fig. 1 View FIGURE 1 G). Tentacular filaments small, forming a cluster partially covered by paleae and not clearly arranged in rows ( Fig. 1 View FIGURE 1 A, B). Two wide and short palps at dorsal junction of opercular lobes, with ciliation on its surface particularly, long and dense at the base ( Fig. 1 View FIGURE 1 D, E). Median organ between palps, with dense ciliation along its dorsal edge ( Fig. 1 View FIGURE 1 D, F).

Thorax. Chaetigers 1 and 2, and corresponding features not yet defined.

Parathorax. Four chaetigers with two types of notochaetae arranged transversely; four large, lanceolate chaetae, slightly concave and with frayed tips ( Fig. 1 View FIGURE 1 H–I) interspersed with four small and straight capillaries ( Fig. 1 View FIGURE 1 H–I). Incipient conical branchiae present dorsally on notopodia ( Fig. 1 View FIGURE 1 H). Parathoracic neurochaetae not formed.

Abdomen and cauda. Abdominal chaetigers not observed. Cauda not yet developed ( Fig. 1 View FIGURE 1 A–C).

Remarks. The larva studied seems it is at an advanced stage of metamorphosis, after comparison with those from other sabellariids (e.g., Dales 1952; Eckelbarger 1977). Provisional chaetae typical of early larval stages have already disappeared, and the opercular lobes are already well defined and provided with primary paleae. The opercular spines or hooks that appear in advanced larval stage and remain in the adults (e.g., Bhaud 1975a, b; Mauro 1975; Eckelbarger 1977; Wilson 1977; Bhaud & Fernández-Álamo 2001) are present. Nevertheless, paleae have still not rotated to the dorsal position, and the mouth or building organ are not yet differentiated as observed in ready to settle larvae.

This Gesaia View in CoL larva bears a conspicuous organ between the palps, similar to the structure referred to as the dorsal hump in Idanthyrsus Kinberg, 1867 View in CoL , Sabellaria Lamarck, 1818 View in CoL and Phragmatopoma Mörch, 1863 View in CoL species ( Dales 1952; Eckelbarger 1977; Bhaud & Fernández-Álamo 2001). This ‘dorsal hump’ apparently disappears before settlement in species that either lack median organ in the adult stages or it is poorly developed. The position and morphology of the structure herein described show some signs of being an early form of the median organ observed in the benthic stages of other members of the family.

The Gesaia View in CoL larva described herein bear ornamented paleae with thecae as compact perpendicular rings in both outer and inner opercular rows, different to any other described species from the genus. Some congeners bear poorly expressed thecal margins or smooth outer paleae ( Gesaia lanai Kirtley, 1994 View in CoL and G. ryani Kirtley, 1994 View in CoL ) and only a few species (e.g., G. elegans ( Fauvel, 1911) View in CoL , G. fauchaldi Kirtley, 1994 View in CoL , and G. fossae Kirtley, 1994 View in CoL ) are known to have ornamented thecae, but these form rings with irregular edges or oblique and with spikes ( Kirtley 1994), not in regular parallel rings like the Australian larva. The inner paleae described herein have stout bases, similarly to Gesaia hessi Kirtley, 1994 View in CoL and G. r y a n i. In addition, several circular holes were observed on the surface of inner paleae in G. hessi View in CoL , possibly attributed to endobiotic activity ( Kirtley 1994), whereas in the described Gesaia View in CoL larva a unique hollow was observed at the tip. It is well known that sabellariids replace their opercular paleae in later larval stages, and these can differ from the primary larval paleae (e.g., Eckelbarger 1977; Wilson 1977; Lezzi et al. 2015). Therefore, is not clear if the paleae morphology described herein would have remained after settlement and description of a new species based on larvae paleae morphology is avoided.

The paleae show some similarities to those present in members of Phalacrostemma View in CoL . Nevertheless, members of these two genera are distinguished, among other features, by the number and shape of the nuchal hooks, with multiple pairs and well-developed limbation in Phalacrostemma View in CoL that is absent in Gesaia View in CoL species, and the arrangement of outer paleae is a spiral in most Phalacrostemma View in CoL species, while they are arranged in semicircles in members of Gesaia View in CoL ( Kirtley 1994; Hutchings et al. 2012; Capa & Hutchings 2014).

This is the first report of Gesaia View in CoL in Australia, and also the first record of a typically deep-water sabellariid in surface water plankton samples. Members of Gesaia View in CoL have been reported from all major oceans and from depths ranging from 770 to 5790 m ( Kirtley 1994), but the eight species described to date have each been reported only once or a few times from nearby localities, leading workers to assume that species were allopatric and narrowly distributed. Undoubtedly, the potential for dispersal over long distances is greater when larvae reach shallower waters, due to low speed currents in deep water ( Kelly et al. 1982; Shanks 1986; Bouchet & Waren 1994; Arellano et al. 2014; Pochelon et al. 2014). This suggests a larval ability to survive under a range of physical factors encountered if migrating vertically from the deep to the euphotic zone (e.g., including a broad variation in temperature and pressure). However, before the ability of larvae of Gesaia View in CoL to disperse long distances can be accepted, substantial investigations on energy content in the oocytes, the velocity of larvae when they migrate upwards and their planktonic larval duration are needed. Interpreting the biogeographic patterns of Gesaia View in CoL remains a major challenge, and the potential for larval dispersal is important in understanding the spatially fragmented radiation of species distribution in the major oceans.

Distribution. Only known from off Lizard Island, close to shore, collected in a plankton tow in 6–15 m water depth.