Trilamina westiana (Greville) J. Witkowski, P.A. Sims, N.I. Strelnikova & D.M. Williams, 2015

3. Trilamina westiana (Greville) J. Witkowski, P.A. Sims, N.I. Strelnikova & D.M. Williams , comb. nov.

(SEM: Figs 239–242 View FIGURES 239–242 ; LM: Figs 243–248 View FIGURES 243–248 )

BASIONYM: Triceratium westianum Greville (1861a , Transactions of the Microscopical Society of London, New Series 9: 43, pl. IV, fig. 11).

TYPE: ‘Barbadoes deposit’ (BM2029, holotype! = Fig. 245 View FIGURES 243–248 ; Williams 1988: 60).

Valves tri-to quadripolar ( Figs 243–248 View FIGURES 243–248 ), with broadly rounded projections, usually distinctly capitate ( Figs 244–247 View FIGURES 243–248 ), and deeply concave sides. Valve face undulate: central area and the marginal zone are raised, whereas the central part of each projection is depressed ( Fig. 240 View FIGURES 239–242 ). The central area bears a small hyaline field, with a single rimoportula offset toward one of the projections ( Figs 239, 242 View FIGURES 239–242 ). In the marginal part of the central area there are few poorly defined rings of areolae ( Figs 243–248 View FIGURES 243–248 ). The projections are perforated by poroid areolae: those within the depressed part are slightly larger, while the marginal areolae are slightly smaller. A field of smaller areolae that possibly represents a pseudocellus is located at each pole ( Fig. 241 View FIGURES 239–242 ). The larger areolae are arranged in rows parallel to the major axis of the projection. The marginal areolae are aligned in rows parallel to the pervalvar axis, and continue down the shallow mantle ( Fig. 240 View FIGURES 239–242 ). Valve face-mantle transition is gradual; a thickened, hyaline area comparable in width to the diameter of the central area is located at the mid-point of each side ( Fig. 240 View FIGURES 239–242 ). Mantle margin is smooth, hyaline, slightly expanded inwardly ( Fig. 240 View FIGURES 239–242 ). On the valve interior, there are numerous costae radiating from the distal part of the depressed area within each projection ( Figs 243–248 View FIGURES 243–248 ). Valvocopula is closed, its depth comparable to that of the mantle ( Fig. 240 View FIGURES 239–242 ). Large clasping devices on the valvocopula attach to the thickenings at the mid point of each side, and the fossa attaches to the inwardly expanded margin of the mantle ( Fig. 240 View FIGURES 239–242 ). Except for a single row of poroid areolae, interrupted at the locations of the large clasping devices and located adjacent to the fossa, entire valvocopula is hyaline ( Fig. 240 View FIGURES 239–242 ). Measurements (n= 8): average side length: 32.2–60.3 µm; 3–4 costae in 10 µm; 3–3.5 areolae in 10 µm.

Geographic and stratigraphic distribution ( Fig. 10, sites 9*, 14, 15*, 16; possible questionable records are indicated with an asterisk): (a) specimens: Eocene: Mascarene Ridge, Indian Ocean, dredging DODO-123-D1: BM stub P.1324 ( Figs 239–242 View FIGURES 239–242 ). Middle Eocene-early Miocene: Barbadoes: BM2029 ( Fig. 245 View FIGURES 243–248 , holotype), BM52820 ( Fig. 243 View FIGURES 243–248 ), BM coll. Adams F1414 ( Fig. View FIGURES 243–248

246). Oceanic Formation outcrops at Springfield: BM38130, BM63799, BM coll. Adams GC3466 ( Fig. 244 View FIGURES 243–248 ), J4252 ( Fig. View FIGURES 243–248

247); Newcastle: BM coll. Adams F 1413 ( Fig. 248 View FIGURES 243–248 ) .

(b) records:

Middle Eocene : Northern Indian Ocean: ODP Site 707, Core 707C-9R: Fenner & Mikkelsen (1990: 448, pl. 3, fig. 5) and ODP Site 713, Core 713A-9R: Fenner & Mikkelsen (1990: 448, pl. 3, fig. 6). 4

Middle Eocene-early Miocene: Barbadoes: Greville (1861a: 43, pl. IV, fig. 11). Oceanic Formation outcrop at Springfield: Schmidt (1882: taf. 77, figs 30–32).

Age und locality unspecified: Jousé (1977: pl. 63, fig. 2).

4. These records are questionable and judging by valve outline, they likely represent Trilamina tripes (Site 707) and Trilamina figurata (Site 713).

ENTOGONIOPSIS GEN. NOV. AND TRILAMINA GEN. NOV. (BACILLARIOPHYTA)

Phytotaxa 209 (1) © 2015 Magnolia Press • 33 Observations:— The poor preservation of the specimen examined here in SEM does not allow inspection of the radial internal costae for the attachment mode of its valvocopula. However, small clasping devices are present in both T. nitescens and T. wittiana , with which T. westiana shares a number of morphological features. Therefore, we assume that this species also has a three-fold mechanism for valvocopula attachment.

Regardless of the locality, valves of T. westiana are consistently small, with an average side length less than 35 µm. Although no specimens of Trilamina tripes ( Fig. 249 View FIGURES 249–252 ) were available for SEM examination, its valve morphology resembles T. westiana . The sparse records of T. tripes show that its valve diameter is close to the upper limit of the variation range in T. westiana . Both species have areolated depressed parts of the projections, and a small hyaline field within the central area. It is unclear, however, whether rimoportulae are present in T. tripes . Given the uncertainty in dating of the deposits from which both T. westiana and T. tripes are reported, it is impossible to state with confidence whether the stratigraphic ranges of these species overlap. However, T. tripes could potentially belong within the range of variation of T. westiana (but see also discussion under T. wittiana ).

New combinations

Trilamina denticulata (Greville) J. Witkowski, P.A. Sims, N.I. Strelnikova & D.M. Williams , comb. nov. (LM: Fig. 250 View FIGURES 249–252 )

BASIONYM: Triceratium denticulatum Greville (1863 , Quarterly Journal of Microscopical Science, New Series 3: 233, pl. IX, fig. 14).

TYPE: ‘Barbadoes deposit, from Cambridge estate’ (BM2763, holotype! = Fig. 250 View FIGURES 249–252 ).