Herentia hyndmanni ( Johnston, 1847 )

Herentia hyndmanni ( Johnston, 1847) View in CoL

( Figure 1 View Figure 1 )

Lepralia hyndmanni Johnston 1847, p. 306 , Plate 54, Figure 6 View Figure 6 .

Lepralia hyndmanni: Busk 1854, p. 74 , Plate 87, Figures 5–8 View Figure 5 View Figure 6 View Figure 7 View Figure 8 .

Mastigophora hyndmanni: Hincks 1880 , part: p. 281, Plate 37, Figures 3 View Figure 3 , 4 View Figure 4 ; non Figures 5 View Figure 5 , 6 View Figure 6 .

Herentia (Herentia) hyndmanni: David and Pouyet 1978, p. 170 View in CoL , Plate 1, Figures 5 View Figure 5 , 6 View Figure 6 . Escharina hyndmanni: Hayward and Ryland 1979 View in CoL , part: p. 196, Figure 82A, B, non C; Hayward and Ryland 1999, part: p. 232, Figures 95C, D, 98A, B, non C; De Blauwe 2006, p. 137, Figure 20.

Non Escharina hyndmanni: Norman 1909, p. 302 View in CoL .

Material examined

Lectotype: NHM 1847.9.16. 156, off Sanda Island, Scotland, four colonies on a bored and abraded shell. Paralectotypes: NHM 1847.9.16. 82, 1847.9.16. 132, 1847.9.16. 142, off Sanda Island, Scotland. Additional material: MNHN 6764 (part), off southern Portugal, ‘‘Jean Charcot’’ cruise 1969, Stn 076 (36 ° 34,99N, 11 ° 38,29W), 600 m, two colonies on shell; NHM 1899.5.1. 1154, Antrim, Northern Ireland, figured by Hayward and Ryland (1979, Figure 82A, B; 1999, Figures 95C, D, 98A, B), four colonies encrusting shells and rocks; NHM 1899.5.1. 911, Madeira; NHM 1996.8.29. 1, off Blanes, NE Spain, 200 m, on Lophelia pertusa ; PMC. R.I.H.B-3a, Gulf of Noto, Ionian Sea, ‘‘Piattaforma Siciliana’’ PS/81, and ‘‘Noto ‘96’’ cruises, 33–78 m, living and dead colonies from several stations; PMC. R.I.H.B-3b, Gulf of Catania, Ionian Sea, ‘‘Ciclopi 2000’’ and ‘‘LCT/80’’ cruises, 90–130 m, living and dead colonies on bioclasts from three stations; PMC. R.I.H.B-3c, off Santa Maria di Leuca, Ionian Sea, ‘‘Aplabes 2005’’ cruise, several stations (between 39 ° 28,099– 39 ° 34,849N, 18 ° 239– 18 ° 24,429E), 505–747 m, several living and dead colonies, mostly on colonies or fragments of Madrepora oculata and L. pertusa ; SMF 3028, Cabo de Gata, SE Spain, ‘‘Meteor’’ cruise M51-1, Stn 495 (36 ° 48,0719N, 01 ° 57,1549W), 120 m, dead colony on pectinid bivalve; SMF 3029, Cabo de Gata, SE Spain, ‘‘Meteor’’ cruise M51-1, Stn 496 (36 ° 48,3969N, 01 ° 57,7359W), 70 m, dead colony on cardiid bivalve.

Measurements

ZL 541¡65, 449–710 (2, 20); ZW 466¡74, 349–641 (2, 20); OL 123¡9, 111–139 (1, 20); OW 120¡9, 106–134 (1, 20); ApL 149¡12, 120–159 (2, 12); ApW 153¡7, 142– 168 (2, 12); OvL 281¡26, 228–315 (2, 12); OvW 370¡33, 311–435 (2, 12); AL 118¡8, 103–136 (1, 20); AW 97¡6, 88–112 (1, 20); AnL 261, 233–286 (3, 3); AnW 278, 262–301 (3, 3).

Description

Colony forming small irregular incrustations. Zooecia hexagonal to polygonal, separated by deep grooves between slightly thickened ridges; vertical walls and demarcated areas extended, with a single, comparatively small, round to oval communication pore per neighbouring zooid. Frontal wall flat proximally, rising distally towards slightly elevated orifice, surface even yet very finely grained, imperforate except for a row of 6–12 relatively large marginal pores, reduced to five or six in periancestrular zooecia. Orifice dimorphic, inner distolateral orifice rim with an immersed narrow shelf; anter of primary orifice horseshoe-shaped, about as broad as long and widest distal to mid-distance, proximal margin in autozooecia straight with drop-shaped sinus, condyles conspicuous, as long as proximal margin, extremely broad at lateral margins with the slope-angle increasing towards sinus; aperture in ovicellate zooecia more or less semicircular, larger and slightly broader than long, proximal margin also broader than in autozooecia, condyles distinctly narrower and sloping at a constantly low angle towards sinus. Proximolateral orifice margin framed by a low, narrow, smooth rim of gymnocystal calcification slightly raising laterally and being continuous with the lateral zooecium margin, distolateral border of autozooecium orifice bounded by a slightly raised and curved rim of thick calcification originating from distal basal pore chambers. Four oral spines in the first autozooid, absent in zooids formed during later astogeny.

Ooecium initially spherical, later for most part immersed by distal zooecium; exposed frontal surface a broad, curved, flattened and thickened rim, variably inclined to, and rising from, frontal plane.

Avicularium single, situated slightly distal to mid-distance of zooid and proximolateral to orifice near right or left zooid margin, proximal to one (or rarely two) distalmost marginal pore, on a slightly swollen cystid more or less continuous with frontal wall, no zooidal areolar pores between cystid and lateral zooid wall; in earliest astogenetic zooecia the avicularium is situated near proximal zooid margin, progressively moving distally in later zooecia; rostrum suborbicular to oval with a broad, smooth and slightly raised rim sloping towards opesium, distolaterally or laterally oriented; mandible long and slender, setiform, slightly sigmoidal, up to twice the length of an autozooid; crossbar bilateral symmetrical, strong, slightly arcuate with the apex at centre, proximal margin of crossbar (with respect to long axis of rostrum) relatively narrow, straight or slightly concave when viewed from above except from a small semicircular extension protruding from its basal centre, distal part of crossbar set off from the proximal part by a suture, calcification distinctly thickening towards the lateral rostral margins, creating a U-shaped distal margin.

Ancestrula kenozooidal, about as long as wide, with an irregular lobate outline, gymnocystal frontal wall moderately convex, rather flat centrally, smooth, lightly but entirely calcified apart from a small central hole, some six articulated spines forming a circle at about mid-distance between margin and ancestrula centre. Budding pattern as described for genus.

Remarks

We here designate lecto- and paralectotypes from Johnston’s suite of specimens that were listed by Brown (1952, p. 229). The lectotype ( NHM 1847.9.16.156) is shown in Figure 1D View Figure 1 .

In contrast to the description of H. hyndmanni by Hayward and Ryland (1979, 1999), oral spines in adult zooids at the colony periphery were neither observed in the available British nor in any other material of this species. Only in the first formed autozooid are four spine bases evident ( Figure 1A View Figure 1 ). Because very early ontogenetic zooids were not observed during this study we cannot rule out the possibility that these are, indeed, formed in zooids at this stage of development and are lost during ontogeny when the thick rim encroaches the distal orifice margin. However, it seems rather likely that one of the specimens Hayward and Ryland (1979, 1999) described and figured (Figures 82C and 98C, respectively) belongs to H. thalassae from the northern Spanish shelf (see below). This species has three or four spines and also a more proximally positioned avicularium in adult zooids. Both characters are present in their figures.

Kenozooidal ancestrulae have been observed only in a few small colonies from central Mediterranean deep-waters, in which the ancestrula remained exposed due to fan-shaped colony growth in a single direction. Usually, the ancestrula was found to be either damaged or, in larger colonies, overgrown by periancestrular zooids. Besides the rare occurrence of kenozooidal ancestrulae in bryozoans (see Discussion), another curious feature is the tiny hole in the central gymnocyst ( Figure 1A View Figure 1 ), which we initially interpreted as accidental damage. However, all of the five ancestrulae with an undamaged central region had this hole and we are therefore inclined to consider it as representing the remnant of an extremely reduced opesium.

H. hyndmanni View in CoL has often been reported from the NE Atlantic (Jullien and Calvet 1903; Canu and Bassler 1925; d’Hondt 1970, 1974, 1975, 1979; Hayward and Ryland 1978; Grant and Hayward 1985) and Mediterranean Sea (e.g. Calvet 1907; Gautier 1962; Harmelin 1969, 1978; d’Hondt 1977, 1984; Di Geronimo et al. 1990, 1993). Yet in the absence of detailed descriptions and (SEM) illustrations of the orifice and avicularium, a synonymy is impossible to establish because of morphological similarities with the other species occurring in these regions ( H. majae View in CoL n. sp., H. andreasi View in CoL n. sp., H. thalassae View in CoL , see below). The specimen shown in Zabala and Maluquer (1988, p. 129, Figure 292; Plate 15, Figure E) is very similar to H. hyndmanni View in CoL but the condyles seem to be distinctly smaller, the avicularium is situated more proximally and its cystid lacks the areolar pores. Important close-ups of orifice, aperture and avicularium necessary for verification are, however, not provided.

H. hyndmanni View in CoL occurs off the western coasts of the British Isles, as far north as the Shetland Isles (Hayward and Ryland 1979, 1999), and was recently also found at depths of c. 20 m in the southern North Sea off Belgium ( De Blauwe 2006). Furthermore, several specimens from off southern Portugal ( d’Hondt 1973), Madeira, and from the western and central Mediterranean Sea (e.g. Poluzzi and Rosso 1988; Di Geronimo et al. 1998; Rosso 1996 a, 1996b), proved to be morphologically identical to British representatives, confirming the presence of H. hyndmanni View in CoL in these regions. The easternmost occurrence in the Mediterranean is in the Ionian Sea, from where it was reported by Poluzzi and Rosso (1988), Rosso (1996 a, 1996b) and Mastrototaro et al. (in press). However, it must be noted that some living (Mastrototaro et al., in press) and dead (Rosso et al., in press) specimens from Ionian Sea deep waters (PMC.R.I.H.B-3c) have considerably longer zooecia [ZL 720¡91; 590–918 (4, 15)], whereas all other skeletal characters are of similar size. Furthermore, these colonies usually consist of broad fanshaped lobes spreading in a single direction, which may be an adaptation to deepwater environments (see H. thalassae View in CoL and Discussion below), while proximal colony regions are often iron oxide-stained. Part of the material listed by d’Hondt (1973, p. 1218) from the Portuguese continental slope belongs to H. hyndmanni View in CoL . It co-occurs with a species that is closely related to, or possibly conspecific with, H. thalassae View in CoL (see below).

H. hyndmanni View in CoL is an offshore species that has been reported from depths between 20 and 750 m encrusting hard substrata in offshore environments to the edge of the continental shelf and the upper slope. However, in the Ionian Sea several small colonies have been recovered from c. 500 m encrusting hardgrounds and even slightly consolidated silty substrata ( AR, pers. observation). Brooding colonies were observed in the Ionian Sea in October ( AR, pers. observation) and, off the Isle of Man, in November ( Eggleston 1969 fide Hayward and Ryland 1979, 1999) .