Cymbopleura laszlorum Bahls & Luna, 2018
publication ID |
https://doi.org/ 10.11646/phytotaxa.349.1.5 |
persistent identifier |
https://treatment.plazi.org/id/038F9D50-FF91-5E4B-FF38-528AFE0F1248 |
treatment provided by |
Felipe |
scientific name |
Cymbopleura laszlorum Bahls & Luna |
status |
sp. nov. |
Cymbopleura laszlorum Bahls & Luna spec. nov. Figs 3–12 View FIGURES 3–23 , 24–29 View FIGURES 24–29
Valves are elliptic-lanceolate with convex margins and rostrate to subrostrate apices. Length 41–54 μm; width 9.7–11.4 μm. Valves are symmetric with respect to both the apical and transapical axes. The axial area is about three times the width of the raphe and widens gradually towards the central area. The central area is moderately large and variable in shape, most often transversely elliptic to rectangular, sometimes shaped like a bow tie. The raphe is lateral, narrowing towards the ends. Proximal raphe ends are deflected gently towards the ventral margin and tipped with slightly inflated pores. Terminal raphe fissures are hook-shaped and concave towards the dorsal margin. Striae are uniseriate and radiate throughout, 14 in 10 μm at the valve center, up to 22 in 10 μm at the apices. Areolae are also variable in density, 20 in 10 μm in striae at the valve center, up to 30 in 10 μm at the apices. [n = 26 specimens]
SEM:—In external valve view, areolae are simple and transapically oblong ( Figs 25, 26 View FIGURES 24–29 ). Occlusions and secondary structures (e.g., vimines) are absent. Striae continue around the valve apices ( Fig. 26 View FIGURES 24–29 ); apical pore fields are absent. Costae between striae are wide relative to the striae themselves. External raphe fissures are narrow, becoming much wider at the terminal fissures ( Fig. 26 View FIGURES 24–29 ). Internally, areolae are arranged end-to-end in trough-like alveoli and separated by narrow intercostae ( Figs 28, 29 View FIGURES 24–29 ). Internal raphe fissures are wide, narrowing towards the terminal and proximal ends. Raphe branches terminate in simple helictoglossae ( Figs 27, 29 View FIGURES 24–29 ). Proximal raphe ends are hooked and separated by a wide intermissio ( Fig. 28 View FIGURES 24–29 ). A flap of silica with a curved edge overlies the central nodule on one side and merges with it at its center ( Fig. 28 View FIGURES 24–29 ).
Holotype:— USA, Montana: East Fork O’Dell Creek , fen pool no. 4, 1567 m a.s.l., 45.2743 °N, - 111.2750 °W, 24 July 2017, coll. Tara Luna, Slide No. 49-69, MONTU GoogleMaps ! Holotype specimen is in Fig. 5 View FIGURES 3–23 .
Isotype:—Slide No. 136-34, Montana Diatom Collection (MDC), Helena.
Paratype:— USA, Montana: East Fork O’Dell Creek, fen pool no. 2, 1567 m a.s.l., 45.2738 °N, - 111.7255 °W, 24 July 2017, coll. Tara Luna, Slide No. 49-67, MONTU!, Slide No. 136-32, Montana Diatom Collection (MDC), Helena.
Differential diagnosis:—The species most similar to C. laszlorum in North America is C. stauroneiformis (Lagerstedt) Krammer (2003: 86) , an Arctic species described from Spitsbergen ( Figs 13–19 View FIGURES 3–23 ). The two species have very similar morphometric values and both have central areas in the shape of a fascia, however C. laszlorum has wider (10–12 μm vs. 8–11 μm) and more elliptic valves with wider apices ( Table 2). Other North American species of Cymbopleura , including C. geofriedana Reichardt (2004: 428) and C. tynnii (Krammer) Krammer (2003: 30) , have similar valve and end shapes as well as comparable striae and areolae densities ( Figs 20–23 View FIGURES 3–23 , Table 2), however Cymbopleura geofriedana ( Fig. 20 View FIGURES 3–23 ) is much smaller (17–30 μm long) than C. laszlorum (41–54 μm long) and C. tynnii ( Fig. 23 View FIGURES 3–23 ) is much larger (48–94 μm long).
Two undescribed taxa from Kazakhstan and the Swiss Alps ( Figs 21, 22 View FIGURES 3–23 ) have wider (13–15 μm), more elliptic valves than C. laszlorum , but otherwise similar shapes, central areas and stria densities ( Table 2). The taxon from Kazakhstan ( Fig. 21 View FIGURES 3–23 ) appears to be conspecific with Cymbopleura mongolica Metzeltin et al. (2009: 30) , which has valves with comparable shape and morphometrics ( Table 2). The taxon that most closely resembles C. laszlorum lives at 4800 m a.s.l. in the Everest region of Nepal: Cymbopleura cf. mongolica ( Van de Vijver et al. 2011: 257) . This taxon differs from C. mongolica by its smaller dimensions (10–11 vs. 12– 14 μm wide) and slightly higher stria density (17–19 vs. 15–17 in 10 μm). It differs from C. laszlorum by the shape of the ends, which are subcapitate rather than rostrate, and by a higher areola density (30–35 vs. 20–30 in 10 μm) ( Table 2). All of the taxa discussed above are from boreal or alpine habitats in the northern hemisphere.
Diatom associates:—At the type locality, Cymbopleura laszlorum was an uncommon (<1 % abundance) but visually conspicuous element of a benthic diatom association dominated numerically by Mastogloia lacustris (Grunow) Grunow in Van Heurck (1880: 70), Cymbopleura florentina (Grunow) Krammer (2003: 99) , and Epithemia argus (Ehrenberg) Kützing (1844: 35) , in decreasing order of abundance.
Etymology:—The new species is dedicated to the Jeff Laszlo family for its steadfast stewardship of this rare and invaluable wetland resource.
MONTU |
University of Montana |
No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.
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