Toxarium hennedyanum (Gregory) Pelletan, 1889

Toxarium hennedyanum (Gregory) Pelletan, 1889

Fig. 22 View Figure 22

References.

Hustedt 1931-1959, p. 222, 224, fig. 713 (as Synedra hennedyana ); Round et al. 1990, p. 422-423; Lobban et al. 2012, p. 260, pl. 17, figs 1-5; Kooistra et al. 2003, fig. 1A-R (as T. undulatum ); Hein et al. 2008, p.33, pl. 15, fig. 3; Álvarez-Blanco and Blanco 2014, p. 128, pl. 63, figs 4-6.

Description from literature.

Colonial on stout mucilage stalks. Long, narrow valves, usually straight, inflated at the poles and the middle, valve lengths ranging from 300 to>1000 µm ( Álvarez-Blanco and Blanco 2014); widths 6-8 µm in the middle, 5-6 µm at poles, and about 2 µm elsewhere; transapical striae very short, 9-11 in 10 µm, with scattered areolae in wider central and polar areas ( Hustedt 1931-1959). Lobban et al. (2012, pl. 17, figs 4, 5) illustrated variants with few/no pores in the central part of the valve face. Girdle bands are all closed ( Kooistra et al. 2003). The valvocopula has a single row of pores along junction between the pars interior and pars exterior and an asymmetrical, notched shelf that fits against the pseudoseptum. The copula has striae that are either porate or become slit-like with broadly fimbriate margins of the pars interior (compare their fig. 1I, L with our Figs 22J View Figure 22 , 23J View Figure 23 ). The narrow pleura has a single row of pores along the junction between the pars interior and pars exterior.

Materials examined.

Guam: GU21AK-11!, GU44AK-4!, GU44BJ-4!. Federated States of Micronesia: Chuuk, TK28!. Marshall Islands: Majuro: M1!; Jaluit: J5!; Bikar: BA2!; inter alia.

Observations.

Valves 156-334 µm long, usually straight but sometimes curved, 7 µm wide at middle, 4-5 µm at poles, with a single row of areolae on the shallow mantle (Fig. 22H, J View Figure 22 , asterisk) and two rows before the scattered areolae (Fig. 22B, D, I View Figure 22 ), making the short transverse striae 3 areolae long; stria density 10-14 in 10 µm (Fig. 22A, B, D, I, J View Figure 22 ). In the context of the present analysis, we confirm the presence of an asymmetrical pseudoseptum (Fig. 22E View Figure 22 ), asymmetrical valvocopula poles with apical notch (Fig. 22F-H View Figure 22 ), valvocopula finely fimbriate (Fig. 22I View Figure 22 ), and the copula structure tending toward slits, the striae 28 in 10 µm at the poles (Fig. 22G View Figure 22 ) increasing to 36 in 10 µm with broadly fimbriate pars interior (Fig. 22J View Figure 22 ). There is a knuckle-like series of arched slits on the valvocopula pars interior (Fig. 22F View Figure 22 ), different from the structure in Synedrosphenia (compare with Fig. 8B View Figure 8 and Fig. 10D, E, G View Figure 10 ). Spines absent. We note that the pars exterior of the copula is hyaline around the poles. However, the fine fimbriae on the pars interior of the valvocopula (Fig. 22I View Figure 22 ) are absent from the specimens in Kooistra et al. (2003 fig. 1J, K). A pleura was present (Fig. 22H View Figure 22 ), the pars interior also fimbriate (not shown).

Taxonomic comments.

Kooistra et al. (2003) show a single row of pores on the mantle and a copula that matches those shown here for T. hennedyanum . They do not state a stria density, but we count 11 in 10 µm, measured from their fig. 1E. There has been a tendency to ignore stria density, reflecting the marginal striae and the domination of the valve face by scattered areolae. Kooistra et al. (2003) had monoclonal cultures in which both Toxarium hennedyanum -like and Toxarium undulatum -like cells were present, and they proposed a merger of the two species. The specimens they show had a rippled edge, but not a strongly wavy outline (contrast Poulin et al. 1986; Hein et al. 2008, and our Fig. 23 View Figure 23 ); i.e., a midline along the apical axis is straight, whereas that in T. undulatum is sinusoidal. If the Micronesian specimens shown here are indeed T. hennedyanum and T. undulatum (by no means certain), our results would suggest that the rippled edge seen in the cultures of Kooistra et al. (2003) was a phenotypic expression of T. hennedyanum and was not T. undulatum. We previously noted ( Lobban et al. 2012) the significant genetic variation in Guam isolates of T. hennedyanum and T. undulatum reported by Theriot et al. (2010, 2011) and this is even more evident now; however, in reviewing the vouchers, we find no data from specimens attributable to T. undulatum ; all the variation shown in Fig. 33 View Figure 33 appears to be part of a T. hennedyanum complex.