Cocconeis churalis Hide. Suzuki, 2012

Cocconeis churalis Hide. Suzuki , sp. nov. ( Figs 1–32 View FIGURES 1–10 View FIGURES 11–18 View FIGURES 19–24 View FIGURES 25, 26 View FIGURES 27–32 )

Frustules heterovalvate. Valve small, elliptical to oval, 8.5–20.0 µm long, 6.0–15.0 µm wide. Raphid valve (RV) concave, raphe slightly sigmoid, central area small, elliptic to orbicular. Striae uniseriate, radiate, 29–36 in 10 µm. Submarginal hyaline area absent. Araphid valve (ARV) convex. Striae alveolus, radiate, 32–38 in 10 µm. Alveolus opens by means of circular to elliptical foramen, viewed internally. Alveolus occluded by hymen. Cingulum consisting of four girdle bands, valvocopula non fimbriate.

Type:— JAPAN. Okinawa Pref., Ishigaki-shi, the Southwest Islands, Ishigaki Island, Ibaruma (24˚31’16.20” N, 124˚16’48.72” E). Sample collected from surface Murrayella periclados (J. Agardh) Schmitz ( Rhodomelaceae , Rhodophyceae) on 4 March 2005. Holotype material and slide; BM 101651 (holotype represented by valves on Figs 1, 5 View FIGURES 1–10 ).

Distribution and ecology: — Cocconeis churalis has been found only from the type locality and was not recorded in the previous study of the Nansei Islands (including Ishigaki Island and other tropical and subtropical regions) ( Takano 1962, Nagumo & Hara 1990, Nagumo & Tanaka 1990, Witkowski et al. 2000, Hein et al. 2008).

Cocconeis churalis grows abundantly on Murrayella periclados in Ishigaki Island, Japan ( Fig. 10 View FIGURES 1–10 , arrows). Tabularia parva (Kütz.) D.M. Williams & Round and Gomphonemopsis pseudexigua (Simonsen) Medlin were found growing epiphytically ( Fig. 10 View FIGURES 1–10 , arrowheads).

Etymology: —The specific epithet “chura” is derived from the Okinawa dialect meaning ‘beautiful’.

Observations: —Frustules with a single flat plastid, C-shaped, which is either simple or elaborately lobed ( Fig. 9 View FIGURES 1–10 ) as in some other species of Cocconeis (cf. Suzuki et al. 2001b –d, 2008, Suzuki & Nagumo 2003b).The frustules are composed of very small and elliptic to oval valves ( Figs 1–8 View FIGURES 1–10 ), measuring 8.5–20.0 µm in length, 6.0–15.0 µm in breadth. Striae densities at the centre of the valves are 29–36 in 10 µm for the raphid valve (RV), 32–38 in 10 µm for the araphid valve (ARV). The RV is concave ( Fig. 11 View FIGURES 11–18 ); the curvature of the valve face is concave at the transapical axis not at the apical axis, as in Cocconeis convexa Giffen (1967: 257 , see Suzuki et al. 2001c). The raphe appears simple, with a slightly sigmoid slit ( Fig. 11 View FIGURES 11–18 ) as in Cocconeis subtilissima Meister (1935: 99 , see Suzuki et al. 2008) but not more curved than that found in Cocconeis heteroidea Hantzsch (in Rabenhorst 1863: 21, see Suzuki et al. 2001a). The inner raphe fissures lie in a very narrow, but raised, axial area ( Fig. 12 View FIGURES 11–18 ). The proximal raphe ends are coaxial and somewhat dilated externally ( Fig. 14 View FIGURES 11–18 ) but internally they are undilated and deflected in opposite directions ( Fig. 16 View FIGURES 11–18 ). The distal raphe ends are dilated externally ( Fig. 13 View FIGURES 11–18 ) but, internally, terminate in short, narrow and small helictoglossa ( Fig. 15 View FIGURES 11–18 ). The central area is round and small ( Fig. 14 View FIGURES 11–18 ). The striae consist of small round areolae and are radiate and uniseriate ( Fig. 11 View FIGURES 11–18 ). Each areola is circular and occluded by a hymen with perforations arranged in a centric array ( Figs 17, 18 View FIGURES 11–18 , see Mann 1981). These hymenes are circular in outline and located near the internal surface of the valve ( Fig. 18 View FIGURES 11–18 ). A submarginal hyaline area is not recognizable; a narrow marginal hyaline area is visible ( Fig. 11 View FIGURES 11–18 ).

The ARV is convex and corresponds to the curvature of the RV. The axial area is a narrow, slightly sigmoid furrow on the outer surface ( Fig. 19 View FIGURES 19–24 ) and, internally, lanceolate ( Fig. 20 View FIGURES 19–24 ). In some valves, a vestigial raphe is observed ( Fig. 26 View FIGURES 25, 26 , arrows). The striae that consist of several alveoli ( Fig. 21 View FIGURES 19–24 ) are radiate and uniseriate ( Fig. 19 View FIGURES 19–24 ). Internally, each alveolus opens by means of a circular to elliptic foramen ( Figs 20, 22 View FIGURES 19–24 ). Each alveolus is occluded by a hymen located near the outer surface ( Fig. 24 View FIGURES 19–24 , arrows). The perforations of the hymen are linear, oblique and arranged in a parallel array ( Fig. 23 View FIGURES 19–24 , see Mann 1981). The structure of the alveolus of Cocconeis churalis is essentially the same as that of Cocconeis dirupta Gregory (1857: 491 , see Kobayasi & Nagumo 1985), C. pellucida Grunow (1863: 145 , see Kobayasi & Nagumo 1985 and Suzuki et al. 2008), C. heteroidea ( Suzuki et al. 2001a) , C. shikinensis Hide. Suzuki ( Suzuki et al. 2001b: 138), C. convexa ( Suzuki et al. 2001c) , C. pseudomarginata Gregory var. intermedia Grunow (1867: 13 , see Suzuki et al. 2001d and Suzuki et al. 2008), C. nagumoi Hide. Suzuki (Suzuki in Suzuki & Tanaka 2006: 282) and C. subtilissima ( De Stefano & Romero 2005, Suzuki et al. 2008). The external face of an immature ARV illustrates the structure of the internal perforations of alveoli ( Fig. 25 View FIGURES 25, 26 ).

The mature cingulum consists of four girdle bands ( Figs 27, 28 View FIGURES 27–32 ): a valvocopula and three bands (the second, the third and the fourth bands), which are all narrower and thinner than the valvocopula. The valvocopula of each valve is open at one pole ( Figs 29, 30 View FIGURES 27–32 , arrows) and has no fimbriae; their inner edges are smooth ( Fig. 32 View FIGURES 27–32 ). The second band, adjacent to the valvocopula, is open at the opposite pole and possesses a ligula ( Fig. 31 View FIGURES 27–32 , L). The third and fourth bands are also open ( Figs 27, 28 View FIGURES 27–32 ). The structure of the cingulum is like that of: C. dirupta ( Kobayasi & Nagumo 1985) , C. pellucida ( Kobayasi & Nagumo 1985) , C. heteroidea ( Suzuki et al. 2001a) , C. convexa ( Suzuki et al. 2001c) , C. pseudomarginata var. intermedia ( Suzuki et al. 2001d) and C. subtilissima ( Suzuki et al. 2008) .

The RV morphology of Cocconeis churalis is similar to that of C. subtilissima ( De Stefano & Romero 2005, Suzuki et al. 2008) but Cocconeis churalis can be readily distinguished by the following characters:

i) The curvature of the RV is concave at the transapical axis;

ii) The slightly sigmoid raphe slits terminate in short, narrow and small helictoglossa, not hooked;

iii) The terminal hyaline area is small and round, not an arrowhead type; and

iv) The density of striae is higher than that of C. subtilissima (26–28 in 10 µm; Suzuki et al. 2008).

Cocconeis churalis is similar to C. dirupta ( Kobayasi & Nagumo 1985) but can be readily distinguished from it as C. dirupta lacks a stauros in the central area of the RV, has a broad, sigmoid lanceolate axial area on the ARV, and a higher density of the areolae on both valves (22 in 10 µm on the RV, 20 in 10 µm on the ARV; Kobayasi & Nagumo 1985).