Adeonellopsis sparassis ( Ortmann, 1890 )

Adeonellopsis sparassis ( Ortmann, 1890)

Figs 12–13 View Fig View Fig

Adeonella sparassis Ortmann, 1890: 54 , pl. 4, fig. 10.

Adeonella hexangularis Okada, 1920: 630 , text fig. 7, pl. 8, fig. 10.

Adeonella hexangularis – Okada 1934: 17, pl. 2, fig. 2. — Mawatari 1952: 285.

Adeonellopsis sparassis – Hirose 2010: 52, pl. 88, figs A–G.

Reptadeonella View in CoL sp. – Hirose 2010: 53, pl. 90, figs A̅D.

Material examined

Lectotype [designated herein]

JAPAN: colony, Sagami Bay , 1882, collected by L. Döderlein, MZS 1-2 View Materials ( SEM specimen NSMT-Te745).

Paralectotypes [designated herein]

JAPAN: colony, Yokohama, 1891, collected by Rolle, MZS 1-1 ( SEM specimen NSMT-Te747); colony, Sagami Bay, 1882, collected by L. Döderlein, MZS 1-3 ( SEM specimen NSMT-Te740).

Other material examined

JAPAN: colonies collected from Suzaki, Izu, Sagami Sea, in the Emperor Showa collection at NSMT (NSMT-BryR362); colonies collected from Ariake Sea (NSMT-Te770), from near Yakushima and Tanegashima (NSMT-Te772, Te773, Te774); from off Shimoda (NSMT-Te890); from south of Nagannu Island (NSMT-Te750, Te803); from Ogasawara (NSMT-Te771).

Measurements

Autozooids. ZL: 358̅659 (527±64); ZW: 186̅379 (263±39); n = 75. SOrL: 46̅91 (63±8); SOrW: 72̅118 (89±9); n = 53. SAvL: 106̅174 (139±15); SAvW: 48̅105 (75±13); n = 75. SpL: 29̅76 (54±11); SpW: 32̅83 (52±11); n = 74.

Gonozooids. ZL: 623̅855 (722±54); ZW: 445̅630 (534±54); n = 24. SOrL: 52 ̅112 (77±14); SOrW: 136̅265 (223±26); n = 21. SAvL: 137̅218 (162±22); SAvW: 88̅117 (104±8); n = 21. SpL: 97̅185 (129±20); SpW: 99̅267 (159±33); n = 23.

Young autozooids in ancestrular complex. ZL: 320̅396 (361±32); ZW: 198̅283 (231±31); n = 6. SOrL: 67̅83 (77±6); SOrW: 93̅109 (100±7); n = 6. SAvL: 56̅75 (67±8); SAvW: 28̅55 (46±12); n = 6. SpL: 18̅31 (23±5); SpW: 31̅56 (41±9); n = 6.

Vicarious avicularia at branch margins. L: 253̅476 (327±69); W: 154̅228 (174±26); n = 8.

Description

Colony brownish yellow, dichotomously branching, irregularly spreading, many proximal branches anastomosing, forming compact three-dimensional structure ( Fig. 12A View Fig ); anastomosed basal region can exceed 4 cm high (3.67–4.64 cm). Branches flat, ribbon-like, variable in width ( Fig. 12B View Fig ); 1.6–8.6 mm wide (average 4.0 mm; n = 101); much wider basally. Autozooids on both sides of branch, oval or hexagonal, outlined by deep marginal groove ( Figs 12C View Fig , 13B View Fig ); younger zooids at end of branch shorter (average 382 μm; n = 6) and broader (average 324 μm; n = 9) than older zooids in anastomosed basal region. Frontal shield minutely granulate, with numerous marginal pores and small ascopore ( Figs 12C View Fig , 13B View Fig ). Spiramen almost circular in younger zooids, divided into 3̅5 denticulate pores ( Fig. 13B, E View Fig ); slightly broader in older zooids in basal part of colony (average 66 μm; n = 12). Peristome transversely oval, roughly semicircular in outline, not tubular; primary orifice submersed in peristome. Triangular suboral avicularium in center of frontal shield, between spiramen and orifice, directed distally ( Figs 12F View Fig , 13B View Fig ). Rarely autozooids have an additional, smaller frontal avicularium, budded from frontal areolae near proximal margin of zooid, directed distally ( Fig. 12C View Fig ). Gonozooids ( Figs 12D View Fig , 13C, F View Fig ) occur at branch bifurcations ( Fig. 13C, F View Fig ); larger than autozooids, hexagonal; with single or double rows of marginal pores ( Fig. 12D View Fig ); slightly crescentic orifice compressed, much wider than long; spiramen large, rounded-triangular or oval in outline, divided into 6̅10 small, denticulate pores ( Figs 12D View Fig , 13C View Fig ). Gonozooids in basal part of colony much broader (average 602 μm; n = 6), and with a slightly larger spiramen (average 142 μm long by 199 μm wide; n = 5). Vicarious avicularia ( Fig. 13A View Fig ) often along edges of branches; triangular, directed distally; about same length as autozooids; rostrum length about half of autozooid length. One young colony observed ( Fig. 13D View Fig ); encrusting, circular, 1.2 cm in diameter; ancestrular complex consisting of six zooids radiating from center. Autozooids in young, encrusting colonies ( Figs 12 View Fig E–F, 13D) oval, surrounded by distinct shallow groove; frontal shield with few marginal pores and 4–6 knobs ( Fig. 12F View Fig ); secondary orifice broadly semicircular; spiramen circular, divided into 2–4 small, denticulate pores; triangular suboral avicularium much smaller than that of mature autozooids; between spiramen and orifice, directed distally, often partly overlapping proximal orificial margin ( Fig. 12F View Fig ).

Remarks

Ortmann’s specimens comprise only the basal, anastomosed parts of colonies ( Fig. 8A View Fig ), and zooidal characters in these specimens are identical to those in the basal parts of the more-complete Adeonellopsis sparassis colonies that I studied. Adeonellopsis sparassis resembles A. sulcata (Milne Edwards, 1836) in having a multiporous spiramen and small, distally directed suboral avicularia, but differs from the latter in having a smaller, circular spiramen. MacGillivray’s (1880: plate 48, fig. 7) illustration of Eschara mucronata (MacGillivray, 1868) (= A. sulcata ) appears to represent the basal part of a colony of Adeonellopsis that resembles A. sparassis . However, as I did not examine MacGillivray’s type specimen, I do not include it in the synonymy of A. sparassis .

I identified an encrusting colony in the Emperor Showa collection as a young colony of A. sparassis based on the small, round multiporous spiramen and the triangular suboral avicularium between the ascopore and orifice. Hayward & McKinney (2002) described a similar ancestrular complex consisting of six zooids in the closely related encrusting genus Reptadeonella . Bock & Cook (2000) also reported a similar encrusting ancestrular complex in Adeonellopsis , but they described a remarkably different bipolar ancestrular colony in the articulated genus Adeona . I conclude the ancestrular complex in the Emperor Showa collection to be A. sparassis rather than Reptadeonella or the other genera, based on the orifice shape and the multiporous spiramen. The knobs on the frontal shield of zooids in the encrusting colony appear to be a character common to young zooids in several adeonid species.

Okada (1920) described another adeonid bryozoan, Adeonella hexangularis Okada, 1920 , from Misaki (Sagami Bay) and the Kagoshima Gulf (southern Kyushu), which surely is Adeonellopsis according to his description of a multiporous spiramen. Due to the limited original description and apparent loss of the type specimens, the identity of A. hexangularis is unclear, but Okada’s description of an anastomosed colony morphology, frontal shields with a single or double rows of marginal pores, and gonozooids located at branch bifurcation and having a broad, proximodistally compressed orifice indicate that it is conspecific with A. sparassis and constitutes a junior synonym of the latter. Mawatari (1952) reported nominal A. hexangularis from off Wakayama and Minabe, Kii Peninsula, without a description; according to this record, A. sparassis is probably also distributed around the Kii Peninsula.

Distribution

Japan: detected in this study from Sagami Bay, Tokyo Bay (Yokohama), Sagami Sea (Izu Peninsula), Ariake Sea, Nansei Islands (near Yakushima and west of Okinawa), and Ogasawara, at depths of 24– 141 m. It was collected from eastern Sagami Bay and western Sagami Sea by Döderlein and Emperor Showa, but was not found recently in those areas by NSMT.