Diploneis latiuscula, Jovanovska & Wilson & Hamilton & Stone, 2023

Diploneis latiuscula sp. nov. (LM Figs 85–96 View FIGURES 85–96 , SEM Figs 97–107 View FIGURES 97–101 View FIGURES 102–107 )

Valves are weakly asymmetric, broadly lanceolate to rhombic-elliptic with convex margins and bluntly round apices ( Figs 85–97 View FIGURES 85–96 View FIGURES 97–101 ). Valve length is 34.5–47 μm and valve width is 19.5–26.5 μm. The axial area is narrow, lanceolate, slightly expanding into a small to indistinguishable and weakly asymmetric central area ( Fig. 85 View FIGURES 85–96 ), 4–5.3 μm wide. Externally, the longitudinal canal is lanceolate to linear, slightly expanded in the middle of the valve with three rows of cribrate areolae (>30 poroids) narrowing into one at the valve apices ( Figs 85–98, 100 View FIGURES 85–96 View FIGURES 97–101 ). Internally, a thick non-porous slightly raised silica plate encloses the longitudinal canal ( Figs 102, 105, 106 View FIGURES 102–107 ). Externally, the raphe is filiform, curved; the proximal ends are within expanded teardrop depressions ( Figs 97, 101 View FIGURES 97–101 ). The distal raphe ends are unilaterally bent to the same side and terminate at the valve face mantle junction ( Figs 97, 98 View FIGURES 97–101 ). Internally, the raphe branches are slightly arched with simple proximal and distal ends that are slightly elevated in a depression formed by the longitudinal canal ( Figs 102–104 View FIGURES 102–107 ). The striae are parallel at mid-valve becoming radiate towards the valve apices, 9–10 in 10 μm. Striae are uniseriate becoming biseriate towards the valve margins (white arrow in Fig. 99 View FIGURES 97–101 ). The striae are composed of large round to rectangular areolae covered externally with a fine pored cribra (>40 poroids), 13–15 in 10 μm. The inter-areolar thickenings have crested fin-like ridges, which are serrated into ca. 5–7 notched edges ( Fig. 100 View FIGURES 97–101 ). The areolae increase in size towards the valve margins ( Figs 97, 100 View FIGURES 97–101 ). Internally, the alveoli open via a single elongated opening covered with a thin silica layer ( Fig. 107 View FIGURES 102–107 ). The valvocopula has serrated advalvar edges ( Figs 105, 106 View FIGURES 102–107 ).

Type:— UNITED REPUBLIC OF TANZANIA, Lake Tanganyika , Jakobsen Beach, at 783 m elevation; submerged roots, 1 m water depth, 4°54’33.4” S 29°35’54.5” E, E. Jovanovska, October 7 th 2019 (holotype designated here, circled specimen BM-108973! = Fig. 91 View FIGURES 85–96 , GoogleMaps isotypes ANSP-GC17202 !, CANA-129320!). Type material CANA-129320. Registration: http://phycobank.org/103722 GoogleMaps

Pictures of the isolated specimen:— LM micrograph on 1000× magnification ( Fig. S3s View FIGURES 2–11 ).

Sequence data:— Plastid gene rbc L sequence (GenBank accession: OQ 660276).

Etymology:— The specific epithet ‘ latiuscula ’ refers to the broad width of the valves.

Ecology and distribution:— Diploneis latiuscula sp. nov. has only been observed from the type material, the northern sub-basin of Lake Tanganyika from the Tanzanian side (see Fig. 1c, d View FIGURE 1 ). Since it was found on submerged roots, the community consisted mainly of epiphytic species with occasional occurrences of D. duplex sp. nov. Diploneis latiuscula sp. nov. is very rare in the type material and could therefore have been found in these roots as a result of water currents, upwelling or turbulence, considering its proximity to the sandy areas that are probably its natural living substrate.

Main differential characters:— Valve shape, striae pattern, external like-fin ornamentations across the valve, and poroids>40 per areola.

Similar species:— Diploneis tanganyikae sp. nov., D. cristata sp. nov., Diploneis tumida sp. nov., Diploneis lecohuiana Lange-Bertalot & Fuhrmann (2017: 26) , and Diploneis ellipticasinensis Lange-Bertalot & Fuhrmann (2020: 42) .