Rhamphostomella morozovi, Grischenko & Gordon & Taylor & Kuklinski & Denisenko & Spencer-Jones & Ostrovsky, 2022

Rhamphostomella morozovi n. sp.

( Fig. 7 View FIGURE 7 )

Diagnosis. Colonies initially encrusting, multiserial, unilaminar, rapidly rising into bilamellar, fan-like expansions. Zooids very large, hexagonal.Frontal shield relatively flat, finely granulated. Marginal areolae initially large, reduced in size with age. Interareolar ridges short, not reaching cystid of suboral avicularium. Umbonuloid component medium-sized. Primary orifice wider than long, broadly semicircular, with small lateral condyles; proximal margin straight or with low median prominence. Oral spines lacking. Secondary orifice irregularly quadrangular to semicircular, cormidial, with lateral peristomial lappets in ovicellate zooids. Suboral avicularian cystid large, subconical, occupying one-third to half of frontal shield, less prominent in older zooids; frontal surface across zooidal axis, facing distolaterally. Rostrum broadly triangular or semielliptical, with blunt hooked tip. Crossbar complete. Adventitious avicularia small, central to proximal, facing frontalwards to slightly angled. Rostrum and palate broadly triangular to semielliptical, with a blunt hooked tip. Crossbar complete. Ovicells hyperstomial, rapidly subimmersed by secondary calcification. Ectooecium with few radially arranged slit-like proximal pseudopores. 1–3 pore chambers in distolateral wall and two multiporous septula in transverse walls. Basal surface of zooids fully calcified, with small prominences.

Material examined. Holotype: ZIRAS 1 /50570, one colony fragment, KamchatNIRO Collection, RV Professor Probatov, Stn 62, 16 August 2013, coastal waters of western Kamchatka, Sea of Okhotsk , 57°14.9ʹ N, 155°37.7ʹ E, depth 116 m, bottom-grab “Ocean–50”, collector T. B. Morozov GoogleMaps . Paratype: ZIRAS 2 /50571, two fragments from same colony, KamchatNIRO Collection , RV Professor Probatov, Stn 82, 11 August 2013, coastal waters of western Kamchatka, Sea of Okhotsk , 58°09.0ʹ N, 156°03.0ʹ E, depth 146 m, bottom-grab “Ocean–50”, collector GoogleMaps T. B. Morozov .

Etymology. The specific name honours Mr Taras B. Morozov (KamchatNIRO, Petropavlovsk-Kamchatsky, Russia), who collected and donated the type material.

Type locality. Western Kamchatka shelf, Sea of Okhotsk , 57°14.9ʹ N, 155°37.7ʹ E, depth 116 m. GoogleMaps

Measurements. ZIRAS 1/50570, western Kamchatka, Sea of Okhotsk ( Fig. 7A–M View FIGURE 7 ). ZL, 1.11–2.03 (1.50 ± 0.26). ZW, 0.57–0.83 (0.68 ± 0.07). ZD, 0.90–1.03 (n = 2). OrL, 0.25–0.31 (0.28 ± 0.02). OrW, 0.30–0.38 (0.33 ± 0.02). OeL, 0.39–0.51 (0.45 ± 0.03). OeW, 0.46–0.60 (0.55 ± 0.03). Av(s)L, 0.15–0.31 (0.22 ± 0.04). Av(ad)L, 0.13–0.33 (0.21 ± 0.05). P(m)N, 11–18 (16). P(oe)N, 2–6 (5) (n = 10).

Description. Colonies initially encrusting, unilaminar ( Fig. 7A View FIGURE 7 ), later rising into bilamellar ( Fig. 7M View FIGURE 7 ), fan-like, ruffled expansions, about 80 × 50 mm in size. Dried colonies greyish to dark yellow. Bilaminate parts of colony up to 2.03 mm thick, adjoining layers of zooids closely adpressed ( Fig. 7M View FIGURE 7 ). Directions of development of zooids in adjoining layers not fully coinciding, with angles of 5–10° between main axes of zooid rows in opposing layers. Zooids very large, hexagonal ( Fig. 7D View FIGURE 7 ) to irregularly oval or tapering proximally ( Fig. 7E–G View FIGURE 7 ), arranged in straight, regular rows in a checkered pattern in colony lobes, or arranged irregularly in older regions of colony. Autozooids demarcated by fine undulating sutures between lateral and transverse walls ( Fig. 7A, F–H View FIGURE 7 ). Boundaries between zooids in older parts of colony often becoming occluded with increasing secondary calcification ( Fig. 7E, G View FIGURE 7 ).

Frontal shield umbonuloid ( Fig. 7A, B, D, I View FIGURE 7 ) initially relatively flat, gradually becoming more convex with age, finely granulated, granulation becoming coarser in older zooids. Relatively large oval to circular areolae along zooidal margins, separated by narrow short interareolar ridges not reaching cystid of suboral avicularium. With age, areolae reduced in size to small marginal holes separated by flat, broad areas of calcification (former interareolar ridges) ( Fig. 7E, G, H View FIGURE 7 ). Umbonuloid component occupying about 50% of length of frontal shield (49% in one measured zooid), with fine parallel lineation and accretionary banding ( Fig. 7I View FIGURE 7 ). Ring scar discrete ( Fig. 7L View FIGURE 7 ), forming regular boundary between umbonuloid exterior wall and extra-umbonuloid interior wall microstructure.

Primary orifice ( Fig. 7A, C, J View FIGURE 7 ) broadly semicircular to bell-shaped (wider than long) and transversely oval; distal and lateral margins formed by upper terminal part of distal transverse wall bearing distinct shelf distally ( Fig. 7A–E View FIGURE 7 ) and forming small, low triangular condyles with acute tips laterally ( Fig. 7J View FIGURE 7 ). Distal margin of orifice round, proximal margin more or less straight or with low, ill-defined median prominence and broadly rounded proximolateral corners ( Fig. 7C, J View FIGURE 7 ). Oral spines lacking.

Secondary orifice ( Fig. 7B–H View FIGURE 7 ) irregularly quadrangular, oval to semicircular, cormidial, proximally formed by thickened frontal shield incorporating avicularian cystid medially, and laterally by two symmetrical, oblique, low triangular lappets that are outgrowths of frontal shield. Distally, distolaterally and sometimes laterally, secondary orifice restricted by vertical walls of distal and lateral zooids. In ovicellate (maternal) zooids, lateral outgrowths of frontal shields form peristomial lappets connecting with proximal corners of ooecium distally and with lappets formed by frontal shield of neighbouring zooid proximally ( Fig. 7G, H View FIGURE 7 ).

Suboral avicularium with cystid large, broad, subconical, occupying from one-third to about half of frontal shield, strongly elevated in young zooids ( Fig. 7A–D View FIGURE 7 ), becoming less prominent in older zooids ( Fig. 7E–H View FIGURE 7 ) owing to immersion into thickening frontal shield; surface finely granulated, with 2–4 tiny communication pores on surface ( Fig. 7A–D View FIGURE 7 ). Frontal surface of avicularium (rostral/postmandibular areas) situated on left or right slope of cystid, across zooidal axis, facing distolaterally. Rostrum broadly triangular or semielliptical, directed medially, laterally or proximolaterally upwards, blunt, with terminal hook. Palate and foramen conforming to shape of rostrum, with blunt distal end; opesia oval, surrounded by narrow cryptocyst. Crossbar complete.

Adventitious avicularia small, central to proximal on zooidal frontal shield in older parts of colony ( Fig. 7F–H View FIGURE 7 ), with relatively narrow cystid, slightly elevated, with finely granulated surface; avicularian frontal surface facing frontally or slightly angled. Rostrum broadly triangular or semielliptical, directed laterally or proximally, with hooked tip, palate and palatal foramen conforming shape of rostrum, opesia oval or elliptical. Crossbar complete. Cystids of these avicularia frequently situated close to ooecia of neighbouring zooids ( Fig. 7G View FIGURE 7 ).

Ovicells hyperstomial, rapidly becoming subimmersed, with ooecium peripherally overgrown by secondary calcification from neighbouring zooids in older parts of colony ( Fig. 7F, G View FIGURE 7 ). In some ovicells, two-thirds of ooecium covered by secondary calcification ( Fig. 7H View FIGURE 7 ). Ooecium formed by distal autozooid around small, shallow arch-like concavity with communication pore at bottom, situated in proximalmost part of frontal shield just immediate to distal margin of maternal primary orifice ( Fig. 7B–D View FIGURE 7 ). Ectooecium with radial growth lines and a few radially arranged slit-like pseudopores near proximal margin. Finely granulated secondary calcification, produced by neighbouring zooids, overgrowing peripheral parts of ooecium, also forming two convex lateral lobes that fuse with lateral lappets of frontal shield to produce low peristome around orifice ( Fig. 7F–H View FIGURE 7 ).

Zooids interconnected by 1–3 mural pore chambers in each distolateral wall ( Fig. 7M View FIGURE 7 ). Communication pores usually form two multiporous septula in basal half of transverse walls. In some zooids, septulum single, as horizontal “band”. ( Fig 7A, D View FIGURE 7 ).

Basal surface of zooids ( Fig. 7K View FIGURE 7 ) fully calcified, roughly lineated, with small prominences. Boundaries between zooids recognizable basally by deep, meandering incisions.

Ancestrula and early astogeny not observed.

Remarks. Apart from the striated appearance of young parts of the colony of R. cristata , R. morozovi n. sp. resembles this species in the following characters: 1) the elevated, conical suboral avicularian cystid with a hooked tip; 2) the primary orifice is commonly bell-shaped, occasionally with a weak median convexity in the proximal margin; and 3) the secondary orifice has two symmetrical, obliquely directed triangular lateral lappets. The quadrangular primary orifices that are rather common in R. cristata and the quadrangular secondary orifices in R. morozovi n. sp. add to this similarity. These two species differ, however, in the following characters: 1) the rostrum and palate of the suboral and adventitious avicularia in R. morozovi n. sp. are broadly triangular to semielliptical, with a blunt tip, but are elongate-triangular with an acute tip in R. cristata ; 2) the suboral and adventitious avicularia are proportionally smaller relative to zooid size in R. morozovi n. sp. than in R. cristata ; 3) fully formed ooecia of R. cristata have 11–32 circular to slit-like pseudopores scattered over the entire frontal surface ( Fig. 4F–H View FIGURE 4 ), whereas ooecia have only 2–6 slit-like pseudopores near the proximal margin in R. morozovi n. sp. ( Fig. 7G, H View FIGURE 7 ).

Ecology. Rhamphostomella morozovi n. sp. was recorded from a depth of 116–146 m on a mixed seafloor, including pebbles and gravel overlying sand and silt. Substrata unknown.

Distribution. Currently known from two nearby localities in the western Kamchatka shelf, Sea of Okhotsk, this is a Pacific Asian high-boreal, sublittoral species, possibly endemic to the Sea of Okhotsk.