Hornera currieae, Batson & Tamberg & Gordon & Negrini & Smith, 2021

Hornera currieae n. sp.

( Figs 4–14 View FIGURE 4 View FIGURE 5 View FIGURE 6 View FIGURE 7 View FIGURE 8 View FIGURE 9 View FIGURE 10 View FIGURE 11 View FIGURE 12 View FIGURE 13 View FIGURE 14 , 16 View FIGURE 16 )

‘Homeohornera’ nom. nud.: Clark et al. 2010, p. 38. ‘Homeohornera’ n. sp. nom. nud.: Clark et al. 2019a, p. 254.

Etymology. Named for Dr Kim I. Currie in recognition of her contributions to the fields of chemical oceanography and ocean acidification, and her generous support of marine research on the Otago Shelf.

Material Examined. Holotype: NIWA 8449 View Materials from cruise TAN0104, stn 115, 42.8022 –42.8047 ° S, 179.9878‒ 179.9883° E, Ghoul Seamount , Graveyard Seamount Complex, northern Chatham Rise, 931–1013 m, 17 April 2001 GoogleMaps . Paratype: NIWA 8443 View Materials , same locality as holotype GoogleMaps . Other material: NIWA 3154 View Materials , stn E800, Fiordland slope, 45.3417° S, 166.6917° E, 1003 m, 20 October 1967 GoogleMaps ; NIWA 2276 View Materials , stn TAN 0104/389, Scroll Seamount, Graveyard Seamount Complex, Chatham Rise, 42.7812° S, 179.994° E, 870–1000 m, 21 April 2001 GoogleMaps ; NIWA 3711 View Materials stn KAH 0204/40, Cavalli Seamount, 34.1642° S, 173.964° E, 1040–1086 m, 18 April 2002 GoogleMaps ; stn TAN 0104/399, Morgue Seamount, Chatham Rise, 42.7200° S, 179.9605° W, 890–1012, 21 April 2001; NIWA 27875 View Materials , stn TAN 0604/6, Chatham Rise, 42.7657° S, 179.9792° W, 1040–1086 m, 28 May 2006 GoogleMaps ; NIWA 8441 View Materials ; stn TAN0104/3, Graveyard Seamount, Chatham Rise, 42.758° S, 179.9912° W, 943–1097 m, 18April 2001 GoogleMaps ; stn TAN 0104/153, Gothic Seamount, Chatham Rise, 42.7325° S, 179.8985° W, 990–1076 m, 15 April 2001; NIWA 25439 View Materials , stn TAN0604/113, Gothic Seamount, Chatham Rise, 42.7275° S, 179.8990° W, 1000–1107 m, 7 June 2006 GoogleMaps ; NIWA 25325 View Materials , stn TAN0604/104, Pyre Hill, Chatham Rise, 42.7162° S, 179.9057° W, 1005–1070 m, 4 June 2006 GoogleMaps ; NIWA 25433 View Materials , stn TAN0604/112, Gothic Seamount, 42.7270° S, 179.8983° W, 990–1040 m, 7 June 2006 GoogleMaps ; NIWA 70966 View Materials , stn TAN0803/38, Macquarie Ridge, 50.0972° S, 163.4742° E, 1070–1123 m, 1 April 2008 GoogleMaps .

Diagnosis. Gracile, erect, open-branched hornerid with thick, porcellanous secondary calcification and sparse threadlike cancelli that propagate proximally or distally. Small, widely spaced zooidal apertures; peristomes emerge at high angles (>75°) relative to branch axis. Nervi absent or greatly reduced. Branch/peristomial anastomoses and adventitious struts absent.

Description. Colony erect, open-branching fan, flat or curled planar, up to ~ 40 mm in height and/or width. Recently living colonies strikingly porcellanous, grading from hyaline at branch tips to pearlescent or off-white hue in thicker branches ( Fig. 4 View FIGURE 4 ). Colony bases often attached to coral fragments, commonly light- to mid-brown, possibly from exogenous staining ( Fig. 4B View FIGURE 4 ).

Branches gracile, bifurcating (rarely trifurcating); branching generally anisotomic ( Fig. 4A–G View FIGURE 4 ). Branches in small colonies generally subequal in length, but distinct ‘leader’ branches develop with increasing colony size ( Fig. 4A View FIGURE 4 ). Colonial branching patterns varying from regular to very irregular. When space in growth plane limited, strictly alternating pinnae arising from leaders; if space is available, branches bifurcate more equably, and higher-order branch subsystem may develop locally (containing secondary/ tertiary branches per Horton–Strahler classification). Branch internodes varying widely in length, and often bending—but not twisting—within growth plane in response to other branches development (cf. other hornerids). Branch angles ranging across 35–100°; branches not approaching closer than 0.36 mm to each other.

Newly budded branches tapering gently towards tips, roughly triangular or square in cross-section ( Fig. 4C–G View FIGURE 4 ). With secondary wall thickening, branches becoming subcircular, usually within a distance of 1–3 internodes from tip ( Fig. 4G View FIGURE 4 ). Basal stem up to 6× thicker than distal branches. Branch and peristomial anastomoses absent. Basal branches typically shed (probably by resorption) in medium–large colonies, leaving clean transverse stumps of varied length. Branch stumps overgrown with smooth secondary calcification, forming solid, domed tips ( Fig. 4A–C View FIGURE 4 ); alternatively, branch regeneration may occur. Basal branch crown usually absent; if present it may contain 2–3 main branches. Broad attachment disc (up to 11 mm wide; Figs 4A–C View FIGURE 4 , 5A View FIGURE 5 ) composed of proximally growing kenozooids ( Fig. 5A View FIGURE 5 ).

Autozooid openings on frontal/lateral branch surfaces only. Zooids in strictly alternating series, always comprising two longitudinal lines of frontal zooids and a single line of lateral zooids on each side ( Fig. 5B–D View FIGURE 5 ). Transverse branch sections invariably containing 4–6 autozooidal chambers. Apertures round, measuring 60–87 µm in diameter (mean 78 µm). Relative to aperture diameter, autozooids are widely spaced; mean nearest-neighbor distance of frontal autozooids 407 µm (range 346–481 µm). Peristomes long and tubular, especially laterals ( Fig. 5B–D View FIGURE 5 ). Mean lateral peristome length, 367 µm (range 160–690 µm). Peristomes becoming progressively thicker towards their bases, emerging from branch surface in a smooth curve ( Fig. 5B–D View FIGURE 5 ). Lateral peristomes emerging at high angle to branch axis (>75°). Spacing between adjacent lateral peristomes on same side highly variable (0.42– 1.23 mm). Autozooidal chambers, estimated from micro-CT, long and narrow (~1.0– 1.3 mm); proximally they may be enlarged and/or flattened in cross-section. Lophophore has 9 tentacles (1 measurement); tentacles ~300 µm long (3 measurements). In the atrial region, membranous sac attached to zooidal chamber with ~8–9 large ligaments in circular arrangement. Colonial and zooidal morphometric ranges are summarised in Table 1.

Interzooidal communication (mural) pores are patchily distributed within the zooidal walls ( Fig. 5D View FIGURE 5 ), or in lines. Pores ~5–8 µm in diameter, lined with fine inward-facing spines; viewed from within zooidal chamber, each pore lies in a shallow pit 10–12 µm wide. Mural pores sparse or absent on abfrontal surfaces of lateral autozooids not in apposition with other zooidal chambers ( Fig. 5D View FIGURE 5 ); however, a single abfrontal pore invariably present at proximal tip of chamber (close to or corresponding to locus of septate budding).

Secondary calcification: branch tips pustulose. Pustules relatively large (~20–25 µm diameter), scattered across frontal and abfrontal wall surfaces, sometimes in longitudinal lines along abfrontal keels at branch tips ( Fig. 6A View FIGURE 6 ). Pustules also present at sites of branch regeneration. Proximal to tips, pustules often immured by massive secondary calcification, usually by the second internode; away from tips, wall surfaces becoming smooth, porcellanous and may appear pearlescent ( Fig. 6B, C View FIGURE 6 ). Occasional specimens mostly or fully pustulose, especially abfrontally. Ongoing calcification resulting in secondary walls that may be 500 µm or thicker in basal branches. Nervi (longitudinal striae) usually absent or, if present, have subdued relief; nervi more pronounced at tips and regeneration loci.

Skeletal ultrastructure of extrazooidal skeleton of laminated calcite, principally comprising hexagonal seminacre grading into pseudofoliated fabric ( Fig. 6D–H View FIGURE 6 ). Individual hexagonal tablets up to ~10 µm across, 180–600 nm thick ( Fig. 6E View FIGURE 6 ). Pseudofoliated fabric containing laminae tens of µm across ( Fig. 6F View FIGURE 6 ). Subdominant rhomboidal and rectangular tablets may be present in crystallite seeding zones ( Fig. 6G, H View FIGURE 6 ). Crystallite imbrication direction is patchy across colony: distal, proximal, lateral or near-neutral. EBSD indicates that the majority of crystallites are hexagonal calcite, with c -axes {0001} aligned perpendicular to body wall; crystalline a -axes {11-20} and m -axes {10-10} lie predominantly in the plane of the wall, but are randomly oriented in that plane ( Fig. 7 View FIGURE 7 ).

Cancelli ~15–35 µm at outer entrance, threadlike and sparsely distributed, especially in older branches ( Fig. 8A–D View FIGURE 8 ); cancelli are connected with some, but not all, hypostegal pores. Ratio of ~3 visible cancelli per autozooid aperture typical in mid-colony branches when viewed frontally (ratio changes with branch age due to cancellus coalescence). Away from branch tips, cancellus openings typically hooded, resembling lunaria, causing opening to face proximally or distally when viewed under SEM ( Fig. 8B, C View FIGURE 8 ). Adjacent cancelli may coalesce into single cancellus with ongoing calcification ( Fig. 8D View FIGURE 8 ). Owing to semi-transparent skeleton, passage of cancelli through body wall usually visible by light microscopy ( Figs 8A View FIGURE 8 , 9A View FIGURE 9 ). Most cancelli trending proximally, but outer regions of cancelli within 4–7 branch internodes of distalward gonozooid usually change direction and propagate towards gonozooid. Towards colony base, cancelli intersecting with wall surfaces at increasingly shallow angles, coalescing into shallow longitudinal grooves or parallel lines; on basal stem of larger colonies, cancelli grading into proximally oriented kenozooids with low, arcuate openings up to 70 µm wide, and sparse scattered mural pores ( Fig. 8E, F View FIGURE 8 ). Atypical cancellus-like structures also common; these tubes or cavities are not connected with hypostegal pores, and commonly become obscured by ongoing wall calcification. These may be microborings or resorption traces.

Seven fertile H. currieae n. sp. colonies examined, each with 1–5 gonozooids, all located on distalmost 1– 3 branch internodes ( Figs 9A–F View FIGURE 9 , 10A–C View FIGURE 10 ). Colony-base-to-gonozooid internode count 8‒20 (see Fig. 2 View FIGURE 2 ). Inflated incubation chamber of gonozooid positioned on abfrontal wall, but arising from rapidly immured tube growing from frontal aperture of developmentally proximal portion of gonozooid ( Figs 9D, F View FIGURE 9 , 10C View FIGURE 10 ). Cryptic tube wrapping around outside of branch (cf. Schäfer, 1991), expanding into bulbous flask-shaped or irregular incubating portion 0.94–1.38 mm long ( Fig. 9A–F View FIGURE 9 ). Unlike other Hornera species , the inflated chamber of gonozooid is wrapped most of the way around the autozooidal bundle ( Fig. 10A, B View FIGURE 10 ). Gonozooid thickly calcified (walls/roof 100 µm+), with scattered large cancelli (~40–80 µm) ( Figs 9 View FIGURE 9 , 10A, B View FIGURE 10 ). Ooeciostome distal, medial or laterally offset; ooeciostome varying from short spout to simple rimmed or rimless opening. Terminal ooeciopore large (~245 µm, 1 measurement; Fig. 9D View FIGURE 9 ), a flattened elliptical shape, opening in distal or distofrontal direction. Removal of gonozooid roof reveals numerous pores and holes (6–17 µm in diameter) lining interior, resembling skeletal resorption structures ( Figs 9E View FIGURE 9 , 11A View FIGURE 11 ). Interzooidal walls near gonozooids often heavily resorbed. Gonozooidal wall cancelli may coalesce, forming complex morphologies ( Fig. 11B View FIGURE 11 ). One or more larvae may settle on or near gonoozooid and metamorphose; such ancestrulae typically expire at early stage (or potentially become fused with the parent colony) and become immured seamlessly into skeleton, creating distinctive, truncated, chimney-like structures ( Fig. 11C, D View FIGURE 11 ). Gonozooid shedding scars absent (cf. other hornerids).

Several ancestrulae observed growing on abfrontal branches and gonozooids of several H. currieae n. sp. colonies ( Fig. 11E, F View FIGURE 11 ). Ancestrula broad and pustulose, with centered, vertical ancestrular tube. Protoecium ~410 µm in diameter, zooidal aperture ~100 µm. One or more periancestrular daughter zooids budding vertically from protoecium roof, sharing wall with ancestrular tube ( Fig. 11F View FIGURE 11 ).

Remarks. Despite its atypical morphology, Hornera currieae n. sp. meets the diagnostic criteria for the genus Hornera set out in Mongereau’s (1972, p. 316) redescription. These include: (1) vertical growth of the ancestrular tube; (2) distinct frontal and abfrontal surfaces, with autozooids emerging from the frontal/lateral surfaces only; (3) abfrontal position of the inflated region of the gonozooid; and (4) a ‘vacuole’-bearing (= cancellate) body wall contoured by nervi. In addition, we found probable evidence of skeletal-resorption-mediated branch shedding and regrowth of basal branches in older colonies. Although not specified in Mongereau’s description, shedding of parts is ubiquitous in Hornera ( Batson et al. 2020) . Finally, H. currieae n. sp. polypides bear nine tentacles, as in other Hornera species ( Tamberg & Smith 2020).

Nevertheless, several characters make H. currieae n. sp. readily distinguishable from all other Hornera species. Although nervi can occur, they are weakly developed and are usually immured by continued secondary calcification. Most of the colony outer wall comprises smooth porcellanous skeleton—the polar opposite of the ropey, pustulose, anastomosing nervi that exemplify other hornerids (e.g., Hornera robusta MacGillivray, 1883 ). Cancelli of H. currieae are thin, threadlike and sparse in number. The reproductively induced variability in cancellus growth direction is unique to this species. Colonies always have two longitudinal rows of alternating frontal autozooids, and their apertures are unusually widely spaced.

We examined described and undescribed hornerids from Australasia and beyond. Morphologically, the mostsimilar taxon to H. currieae n. sp. is an undescribed New Zealand hornerid (‘ Hornera cf. caespitosa’, sequenced by Waeschenbach et al. 2009; GenBank accession numbers FJ409614 View Materials , FJ409590 View Materials ). This small hornerid has nervi, cancelli and autozooidal parameters intermediate between those of H. currieae n. sp. and coastal Australasian hornerids (Smith et al. in prep.). It also occurs in offshore oceanic settings around southern New Zealand, although at shallower depths than H. currieae n. sp.

While the assignment of H. currieae n. sp. to Hornera is justifiable in our view, we recognise that considerable differences exist between this species and other described Hornera species. A revision of the austral Horneridae , including molecular sequencing, which is currently underway (Smith et al. in prep.) may result in genus reassignment.

The porcellanous secondary calcification of H. currieae n. sp. colonies is striking under a light microscope. The pearlescent or hyaline appearance probably arises from the laminated, semi-nacreous ultrastructure and the relative lack of light-refractive surface texturing (e.g., pustules, nervi). In some specimens, faint patches of varying colours are visible within the skeleton; these may mark horizons where the drying skeleton has become delaminated, forming very thin slit-like air spaces that cause structural iridescence.

Given the unusual structure of the skeleton of H. currieae n. sp., its crystallographic attributes are of interest. EBSD mapping revealed the crystalline c -axes of the constituent crystallites to be roughly perpendicular to the branch surface, indicating that the {0001} crystalline planes lie in the same plane as the flat crystallites laminating the branch wall ( Fig. 7 View FIGURE 7 ). This arrangement is broadly similar to that of other Hornera species documented by Taylor & Weedon (2000), and is consistent with the observed skeletal ultrastructure in H. currieae —i.e., mostly hexagonal calcite semi-nacre and/or pseudofoliated laminae with roughly hexagonal (~120°) interfacial angles along their exposed faces. One difference, however, is that relative to other hornerids, the absence of topography-altering nervi and pustules in mature H. currieae branches greatly reduces scattering of the c -axes at a fine scale of ~100 µm (Batson et al. unpublished data).

The crystalline a -axes and m -axes represent the orientation of the three {11–20} planes and three {10-10} planes, respectively, and describe the rotation of the hexagonal calcite lattice around the c -axis. In H. currieae n. sp., the mapped a-/m- axes were widely scattered and are probably randomly distributed around the corresponding c- axes ( Fig. 7 View FIGURE 7 ). This observation, along with the alignment of crystalline c- axes, may have biomechanical implications, given the strong radial anisotropy of the hexagonal calcite crystal.

In addition, based on observed crystallite morphology, other configurations of calcite are also likely to be present in the skeletal wall of H. currieae n. sp. Flat rectangular and rhomboidal tablets were common, especially in seeding zones ( Figs 6G–H View FIGURE 6 ). Such crystallites might correspond to c -axis angles of ≤45° and ~22° relative to the wall surface, respectively (A. Checa, pers. comm.). Focused EBSD indexing of individual crystallites will be needed to determine whether these morphologies truly reflect different crystallographic orientations, and it should be noted that many crystallites appear only roughly crystalline in form.

The characteristic ‘triple spikes’ reported from the centres of newly seeded crystallites in other Hornera species ( Taylor & Jones 1993) were not seen in H. currieae ; in their place, single raised bumps ~ 200–500 nm across were common. Compared to its use in other biomineralizing phyla, EBSD has been underutilised as a tool to study crystallographic properties of bryozoan skeletons (a notable exception is Jacob et al. 2019).

Hornera currieae n. sp. may be among the most-calcified of living stenolaemates—which is surprising for such a gracile species. This characteristic results from extensive secondary-wall thickening combined with an unusually low density of autozooids and cancelli ( Fig. 11G, H View FIGURE 11 ). Transverse branch sections can have an internal skeletal- to non-skeletal-volume ratio of up to ~93% ( Fig. 11H View FIGURE 11 ). This value is comparable to that of other very heavily calcified unilaminate cyclostomes (e.g., crisinids), and palaeostomates such as fenestellids—e.g., see Fig. 7C View FIGURE 7 of Penniretepora pseudotrilineata Ceretti, 1963 , in Ernst & Minwegen (2006). In terms of absolute calcimass, however, the thickened colony margins of the fenestrates such as Lyropora Hall, 1857 can contain solid skeletal walls up to 5 mm thick (A. Ernst, pers. comm.). While the Bryozoan Skeletal Index proposed for radial-exozone-bearing taxa by Wyse Jackson et al. 2020, is not directly comparable, owing to methodological differences, H. currieae n. sp. is more calcified than any of the trepostomes and cystoporates assessed by this metric.

Hornera currieae n. sp. branches grow thicker on the abfrontal side, forming a zone of near-solid skeleton up to 500 µm thick. Heavy calcification is not restricted to the basal regions of the colony—tips of fertile and/or load-bearing leader branches are often thickly calcified within two or three internodes of the branch tip (e.g., Fig. 4A View FIGURE 4 ). This observation is intriguing with respect to life history, the energetics of calcification and the deep-sea environment in which this species occurs. It suggests a long-lived, slow-growing life strategy, with multi-annual to multi-decadal lifespans. Energy-dispersive X-ray spectroscopy of H. currieae n. sp. shows anticorrelated banding of sulphur and magnesium in the secondary skeleton (P. Batson et al., unpublished data). Similar S/Mg oscillations are reported in European Corallium rubrum (Linnaeus, 1758) , with a periodicity corresponding to validated annual growth rings ( Vielzeuf et al. 2013). Elemental variation may prove instructive for investigation in future growth and ageing studies of deep-sea cyclostomes that cannot be reared in the laboratory or marked in situ.

Observations of fertile colonies support an interpretation of a slow-paced life strategy. Only seven of the 43 specimens of H. currieae n. sp. examined had developed gonozooids. This is similar to some Antarctic tubuliporids collected from shallower depths, which also have a low proportion of fertile colonies ( Ostrovsky & Taylor 1996). Low metabolic rates or/and rare fertilization events could be potential reasons (discussed in Nekliudova et al. 2021), although gonozooid shedding is a possibility, as it is common in other hornerids; see Batson et al. 2020). Five colonies possessed one or two gonozooids, whereas the two largest specimens had three and five gonozooids. Micro-CT of one gonozooid revealed that two fertile zooids grew tubes leading into the same abfrontal incubation chamber ( Fig. 9F View FIGURE 9 ) suggesting fusion reminiscent of lichenoporids possessing a ‘colonial’ incubation chamber ( Borg 1926). Fertile colonies with intact bases had 16–21 branch nodes between the base and the tip of the fertile branch (including pinnae). None of the broken branches bearing gonozooids had fewer than 10 nodes. Reproduction may by contingent on exceeding a certain colony-size threshold relating to resource allocation (e.g., Nekliudova et al. 2021). Indeed, some gonozooids apparently fail to develop fully, and become aborted and overgrown, as revealed by micro-CT ( Fig. 10C View FIGURE 10 ). Similarly failed gonozooids were observed in Hornera mediterranea by Harmelin (2020). We did not see obvious gonozooid shedding scars, but the absence of gonozooids away from the distal three internodes suggests that shedding might occur as it does in other hornerids.

None of the H. currieae n. sp. colonies examined were small enough to reveal early colony development— which, in hornerids, is invariably immured in secondary calcification ( Borg 1926). However, a number of putative ancestrulae were found growing on fertile colonies ( Figs 9F View FIGURE 9 , 10A View FIGURE 10 , 11C View FIGURE 11 ). These were concentrated around gonozooids, suggesting settlement of larvae on the parent colony (an alternative possibility is that these structures are pseudoancestrulae generated by the parent colony). Inferred ancestrula development is similar to that documented in Hornera cf. robusta , with a fully interior-walled protoecium, vertical ancestrular tube and peri-ancestrular budding ( Batson et al. 2019). The protoecium is large (410 µm diameter), equating to an approximate larval diameter of ~275 µm using the 1:1.5 cyclostome larvae-to-protoecium size relationship reported by Taylor & Jenkins (2017). The large (~245 µm) gonozooidal ooeciopore is also consistent with a large larval size. Assuming larvae are this large, H. currieae n. sp. is probably less fecund than continental-shelf hornerids, since the gonozooids are 2–5 times smaller.

Distribution. Most records of Hornera currieae n. sp. are from depths of ~ 700 to 1100 m across the Zealandia undersea continent ( Fig. 1 View FIGURE 1 ). A single anomalous record from 260 to 280 m depth was collected from Mahina Knoll, northwest of Whakaari/White Island, Bay of Plenty (NIWA 2534). Hornera currieae n. sp. occurs in tectonically passive and active continental margins and on the subduction-associated Macquarie Ridge, with a latitudinal range of 34‒ 51° S. It is locally common on seamounts of the Graveyard Seamount Complex on the northern flank of the Chatham Rise. There it appears to be closely associated with the scleractinian coral Solenosmilia variabilis , often growing on its degraded fragments. H. currieae n. sp. is not recorded beyond the New Zealand Exclusive Economic Zone, so is potentially endemic.