Richtersius tertius, Pogwizd & Stec, 2022

Pogwizd, Justyna & Stec, Daniel, 2022, An Integrative Description Of A New Richtersius Species From Greece (Tardigrada: Eutardigrada: Richtersiusidae), Acta Zoologica Academiae Scientiarum Hungaricae 68 (1), pp. 1-21 : 6-15

publication ID

https://doi.org/ 10.17109/AZH.68.1.1.2022

persistent identifier

https://treatment.plazi.org/id/03A1297C-C93B-7E75-FE3C-FE6844DA7A01

treatment provided by

Felipe

scientific name

Richtersius tertius
status

sp. nov.

Richtersius tertius sp. n.

( Figs 1–7 View Fig View Fig View Fig View Fig View Fig View Fig View Fig )

Richtersius sp. 7 (GR.008; MK214323 View Materials –5) in STEC et al. 2020 a

Richtersius sp. (OTU6; MK214323 View Materials –5) in KAYASTHA et al. 2020 a

Etymology: The name “ tertius ” refers to the fact that the new species is the third formally described in the genus Richtersius .

Material examined: 171 animals and 73 eggs: specimens mounted on microscope slides in Hoyer’s medium (134 adult animals + 12 hatchlings + 59 eggs), fixed on SEM stub (12 + 9 + 14), and used for DNA extraction and sequencing (4 + 0 + 0; in STEC et al. 2020 a).

Description of the new species – Adults (measurements and statistics in Table 2).

Body yellow, after fixation in Hoyer’s medium, all specimens become transparent ( Fig. 1A View Fig ). Eyes present both in live animals and specimens mounted in Hoyer’s medium. Body and leg cuticle without granulation ( Figs 1A View Fig , 3A–D View Fig ).

Claws slender, primary branches with distinct accessory points ( Fig. 3A–D View Fig ) and a system of internal septa as described by LISI et al. (2020). Secondary branches approximately 80% of the length of the primary branches. An evident stalk system connecting the claws to the lunulae is visible under PCM and SEM ( Fig. 3A–D View Fig ). The stalk system consists of a thin laminar stalk connecting the claw to the lunula and two posterior lateral extensions ( Fig. 3A–D View Fig ). The distal tips of these lateral extension under PCM appear to be connected to the stalk where it contacts the lunula ( Fig. 3A–B View Fig ) whereas under SEM the stalk system is visible as a cuticular plate with a protuberant laminar stalk ( Fig. 3C–D View Fig ). Lunulae large, smoothly unified with the leg cuticle and with a crown of long, numerous and densely arranged spikes (2.0–3.1 μm long) ( Fig. 3A–D View Fig ). Lunulae I–III trapezoidal, whereas lunulae IV ovate ( Fig. 2A–F View Fig ). Divided cuticular bars, double muscle attachments, and horseshoe structures are visible in PCM ( Fig. 3A–B View Fig ).

Mouth antero-ventral. Sensory lobes merged into a single circular sensory field surrounding the mouth ( Fig. 4A View Fig ). Anteriorly, the mouth begins with fused peribuccal lamellae forming a circular velum/lamina which is posteriorly folded into a pre­mouth ventricle ( Fig. 4A–B View Fig ). With the exception of the second band of teeth, which is rarely and only faintly visible in larger specimens, the oral cavity armature is not visible under PCM. ( Fig. 5B–C View Fig ). Under SEM, the oral cavity armature is clearly seen to be composed of three bands of teeth ( Fig. 4A–B View Fig ). The first and the second band form continuous rings around the axis of the mouth, whereas the third band is divided into a dorsal and a ventral portion ( Fig. 4A–B View Fig ). The first band of teeth lies on the inner surface of the velum and is composed of numerous small granular cones forming about twenty irregular rows with slightly bigger teeth positioned on the edge closest to the velum ( Fig. 4A–B View Fig ). The second band of teeth consists of about ten irregular rows of densely packed, elongate, sharp cones which lie on a cuticular fold protruding from the pre-mouth ventricle ( Fig. 4A–B View Fig ). The discontinuous third band of teeth is situated between the second band of teeth and buccal tube opening and is divided into a dorsal and a ventral portion, both in the form of a single large tooth, resembling a beak ( Fig. 4A–B View Fig ). The ventral tooth resembles an isosceles trapezium standing on its longer base, with a ragged upper edge. The dorsal tooth is semicircular in shape, with a crescentshaped indentation in its middle ( Fig. 4 A–B View Fig ).

mens; SD = standard deviation).

Buccal apparatus massive. The oral cavity is followed by a system of massive apophyses forming a buccal crown ( Fig. 5A–C View Fig ). Anteriorly, the system consists of dorso-lateral and ventro-lateral triangular apophyses ( Fig. 5A, C View Fig ). The dorsal and ventral apophyses, are composed of anteriorly positioned large cuticular hooks followed by longitudinal crests which in case of ventral apophyses might be homologous to the ventral lamina found in ordinary macrobiotids ( Fig. 5B View Fig ). The hook in the ventral apophyses is smaller than the dorsal hook ( Fig. 5B View Fig ). The buccal tube wall exhibits variable thickness, but the internal diameter of the buccal tube is almost uniformly narrow ( Fig. 5A View Fig ). From mouth opening to the stylet support insertion point, the thickens of the buccal tube wall increases only slightly before also slightly expanding to its greatest thickness beyond this point before then shrink posteriorly ( Fig. 5A View Fig ). Pharynx spherical, with bilobed apophyses, three anterior cuticular spikes (typically only two are visible in any given plane) and two granular macroplacoids (2<1). The first and the second macroplacoid with a faint constriction positioned centrally and subterminally, respectively ( Fig. 5A–E View Fig ).

Hatchlings (measurements and statistics in Table 3). Same as adults, except for small- er body size ( Fig. 1B View Fig ) and round pores (1.2–4.1 μm in diameter) with wavy edges, clearly visible both under PCM and SEM, scattered randomly on the entire body cuticle ( Figs 1B View Fig , 2A–E View Fig ), with a PD range of 3–6.

anterior and posterior claws. Scale bars in Μm

standard deviation).

Eggs (measurements and statistics in Table 4). Large, oval, light yellow, laid freely ( Figs 6A–B View Fig , 7A View Fig ). The surface between processes is smooth but with refracting dots faintly visible only under PCM, but difficult to observe because of the amount of debris that is typically attached to the egg surface ( Figs 6C View Fig , 7A–D View Fig ). Processes in the shape of elongated, thin, cones with a ragged surface ( Figs 6 D–E View Fig , 7B–D View Fig ). Terminal portions of the egg processes are flexible, sometimes divided into two or three short filaments ( Figs 6D–E View Fig , 7A–D View Fig ). Terminal discs or spatulas absent.

Reproduction – The new species is dioecious: both males with testes and females with ovaries were recorded within the examined population ( STEC et al. 2020 a).

third band are marked with D and V, respectively. Scale bars in Μm

DNA sequences – The DNA sequences of four molecular markers (18S rRNA, 28S rRNA, ITS-2 and COI) associated with the species description have been previously published by STEC et al. (2020 a). The respective GenBank accession numbers are given in Table 1.

Locality: 35°16’16’’N, 23°57’41’’E; Greece, Crete, Chania, Omalos ; forest; moss and lichen from a tree in a forest; coll. 04.07.2015 by Małgorzata Mitan and Małgorzata Osielczak GoogleMaps .

Type depositories: The holotype (slide GR.008.15 with 4 paratypes), as well as 162 paratypes (slides: GR.008.*, where the asterisk can be substituted by any of the following numbers, 03–29; SEM stub: 19.12) and 73 eggs (slides: GR.008.* 30–33; SEM stub: 19.12) are deposited at the Institute of Zoology and Biomedical Research , Jagiellonian University , Gronostajowa 9, 30–387, Kraków, Poland whereas 51 paratypes (slides: GR.008.*, where the asterisk can be substituted by any of the following numbers, 20–29) and 31 eggs (slides: GR.008.* 34–37) are deposited at the Institute of Systematics and Evolution of Animals , Polish Academy of Sciences , Sławkowska 17, 31­016, Kraków, Poland .

egg surface is often covered by dirt). Scale bars in Μm

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