Macrobiotus horningi, Kaczmarek & Michalczyk, 2017

Macrobiotus horningi View in CoL sp. nov.

( Tables 1, 4, Figs 1–4 View FIGURE 1 View FIGURE2 View FIGURE3 View FIGURE 4 )

Macrobiotus anderssoni Richters, 1907 View in CoL ( Horning et al. 1978)

Material examined ( Fig. 1 View FIGURE 1 ). Eight animals and one egg (holotype and 8 paratypes) on nine slides designated as: 1) Macrobiotus anderssoni Richters , 605, Pegleg Flat, Arthur’s Pass Nat. Pk., SI, New Zealand, V-18-70, D.S. Horning, NZ 154, Museum of New Zealand (adult, now designated as a holotype of Macrobiotus horningi sp. nov.); 2) Macrobiotus anderssoni? Richters , egg, proc 14x, Pegleg Flat, Arthur’s Pass Nat. Park, SI, New Zealand, V-18-1970, D.S. Horning, NZ 154, Museum of New Zealand (egg, at present designated as a paratype of Macrobiotus horningi sp. nov.); 3) Macrobiotus anderssoni Richters , 300, Pegleg Flat, Arthur’s Pass Nat. Pk., SI, New Zealand, V-18-70, D.S. Horning, NZ 152, Museum of New Zealand (adult, now designated as a paratype of Macrobiotus horningi sp. nov.); 4) Macrobiotus anderssoni Richters , 570, Pegleg Flat, Arthur’s Pass Nat. Park., SI, New Zealand, V-18-1970, D.S. Horning, NZ 154, Museum of New Zealand (adult, now designated as a paratype of Macrobiotus horningi sp. nov.); 5) Macrobiotus anderssoni Richters , 370, Pegleg Flat, Arthur’s Pass Nat. Pk., SI, New Zealand, V-18-70, D.S. Horning, NZ 152, Museum of New Zealand (adult, now designated as a paratype of Macrobiotus horningi sp. nov.); 6) Macrobiotus anderssoni Richters , 435, Pegleg Flat, Arthur’s Pass Nat. Pk., SI, New Zealand, V-18-70, D.S. Horning, NZ 166, Museum of New Zealand (adult, now designated as a paratype of Macrobiotus horningi sp. nov.); Macrobiotus anderssoni Richters , 435, Pegleg Flat, Arthur’s Pass Nat. Pk., SI, New Zealand, V-18-70, D.S. Horning, NZ 152, Museum of New Zealand (adult, now designated as a paratype of Macrobiotus horningi sp. nov.); 7) Macrobiotus anderssoni Richters, Pegleg Flat , Arthur’s Pass Nat. Pk., SI, New Zealand, V-18-70, D.S. Horning, NZ 152, Museum of New Zealand (adult, now designated as a paratype of Macrobiotus horningi sp. nov.); 8) Macrobiotus anderssoni Richters, Pegleg Flat , Arthur’s Pass Nat. Pk., SI, New Zealand, V-18-70, D.S. Horning, NZ 152, Museum of New Zealand (adult, now designated as a paratype of Macrobiotus horningi sp. nov.); 9) Macrobiotus anderssoni Richters , 220, Pegleg Flat, Arthur’s Pass Nat. Pk., SI, New Zealand, V-18-70, D.S. Horning, NZ 157, Museum of New Zealand (adult, now designated as a paratype of Macrobiotus horningi sp. nov.).

We also examined 32 other animals identified as M. anderssoni , collected from a number of localities in New Zealand (i.e. Mount Egmont National Park, Mountain House Road ; Arthur’s Pass National Park , Halpin Creek and Kellys Creek ; Abel Tasman National Park, Canaan Road terminus; Mount Aspiring National Park , Haast Pass ; Broken Hill ; Tongariro National Park , Ohakune Road ; Eglington River ; Norsewood ; Lake Manapouri ; Rangatira Island , Triangulation Station ; Coopers Knob ; Lewis Pass ; Wainaua Gorge ). However , as none of these specimens were accompanied by eggs, we did not include them in the type series (see also below).

Type locality. 42°54'S, 171°34'E, ca. 850 m asl: New Zealand, South Island , Arthur’s Pass National Park, Pegleg Flat, under shrubs, liverwort ( Porella elegantula ) from rocks. GoogleMaps

Description (measurements and statistics in Tables 1, 4). Animals: Body colour unknown, eyes absent ( Fig. 2A View FIGURE2 ) (but these character may have been affected by the slide mounting media). Entire cuticle covered with round and oval pores not arranged in bands ( Fig. 2B View FIGURE2 ). Poorly visible granulation present only on legs IV. Buccopharyngeal apparatus of the Macrobiotus type, with the ventral lamina and ten peribuccal lamellae ( Fig. 3A–C View FIGURE3 ). Mouth antero-ventral. The oral cavity armature of the patagonicus type (see, Kaczmarek & Michalczyk 2017 for details), with only the second and the third band visible under LM ( Fig. 3B–C View FIGURE3 ). The second band of teeth composed of small granules just above the third band of teeth. The third band of teeth composed of three dorsal and three ventral teeth in the shape of transverse ridges. Pharyngeal bulb spherical with triangular apophyses, two rodshaped macroplacoids and a thin microplacoid. Macroplacoid length configuration 2<1. The first macroplacoid with a central constriction. The second macroplacoid without constrictions, but with latero-terminal globular projections ( Fig. 3A View FIGURE3 ). Claws of the hufelandi type, stout ( Fig. 3D View FIGURE3 ). Primary branches with distinct accessory points. All lunules smooth. Thin paired bars under claws I–III present. Other cuticular thickenings on legs absent.

Eggs: Spherical, ornamented and laid freely ( Fig. 4A View FIGURE 4 ), with the chorion surface of the hufelandi type (reticulated; Fig. 4B View FIGURE 4 ). The reticulum well defined, with a limited mesh between egg processes. The mesh size almost uniform (1.0–1.8 µm in diameter), but the mesh forming peribasal rings around processes slightly larger than the interbasal mesh. Process trunks mostly sigmoidal, sometimes concave, wide at the base and very narrow just below the disc, occasionally bifurcated, and terminated with a concave disc ( Fig. 4C View FIGURE 4 ). Disc edges indented, with well-developed teeth ( Fig. 4D View FIGURE 4 ).

CHARACTER N RANGE MEAN SD Holotype µm pt µm pt µm pt µm pt Body length 7 214 – 612 – 425 – 150 – 612 – Buccal tube

Length 8 25.0 – 47.7 – 38.2 – 7.6 – 47.7 – Original measurements according to Horning et al. (1978), including the original terminology: Body length (190–605 µm, mean 390 µm); body width (200 µm); mouth tube length (60 µm); mouth tube width (6 µm, and 9 µm at base); stylet supports attached 12 µm from base; apophyses length (5 µm); I macroplacoid length (15 µm); II macroplacoid length (9 µm); microplacoid length (3 µm); claws length (16 µm); lunules (3–5 µm); egg diameter excluding processes (75–80 µm); height of egg processes (14–20 µm).

Etymology. We dedicate this species to Donald S. Horning, the first author of the “Tardigrada of New Zealand ” monograph, who collected the samples containing the species.

Type depositories. Holotype and paratypes are preserved at the Museum of New Zealand Te Papa Tongarewa, Tory Street, PO Box 467, Wellington , New Zealand.

Remarks. Specimens described here as M. horningi sp. nov. were originally classified by Horning et al. (1978) as “ Macrobiotus anderssoni Richters, 1907 ”. This was a clear misidentification that had already been noticed by Ramazzotti & Maucci (1983) (translation Beasley 1995) and again by Pilato et al. (2006), as the specimens collected by Horning et al. (1978) belong to the M. hufelandi group, whereas M. anderssoni is probably a member of the Mesobiotus furciger complex. Similar doubts about the taxonomic status of M. anderssoni were formulated by Roszkowska et al. (2016). Therefore, as M. horningi sp. nov. and M. anderssoni are not similar and even belong to different genera, we decided to not compare them in the differential diagnosis (below). Horning et al. (1978) reported “ M. anderssoni ” in 60 samples collected from 39 New Zealand localities, but “ M. anderssoni ” eggs were reported only from the following five localities: 175 (Arthur’s Pass National Park, Kellys Creek), 382 (Mount Aspiring National Park, Haast Pass), 391 (Banks Peninsula, Otepatotu Bush), 536 (Abel Tasman National Park, Canaan Road terminus), and 746 (Mount Egmont National Park, Mountain Road House). However, when examining Horning’s New Zealand collection, we only found an “ M. anderssoni ” egg in sample 154 (Arthur’s Pass National Park, Pegleg Flat) but no eggs on slides from localities 175, 382, 391, 536 and 746. Thus, although animals from all localities exhibit very similar morphology, we chose to be conservative and have only included in the type series specimens from the locality 154, i.e. the only locality in which, both animals and an egg were present. The eight animals and the egg from the locality 154 correspond perfectly with the description and microphotographs in Horning et al. (1978).

Differential diagnosis. Macrobiotus horningi sp. nov. is characterised by having the oral cavity armature of the patagonicus type and eggs chorion of the hufelandi type (see Kaczmarek & Michalczyk 2017 for details). Thus, it is most similar to the following six species but can be distinguished from:

M. personatus Biserov, 1990 View in CoL , reported from the type locality in Russia, by: the absence of granulation on legs I–III, the apparent absence of eyes, the presence of teeth on concave terminal discs of the egg processes (terminal discs flat and smooth in M. personatus View in CoL ), longer egg processes (11.8–20.0 µm in the new species vs. 7.0–10.5 µm in M. personatus View in CoL ), and a smaller diameter of terminal disc on egg processes (6.0–6.6 µm in the new species vs. 7.0– 9.0 µm in M. personatus View in CoL ).

M. sandrae Bertolani & Rebecchi, 1993 View in CoL , reported from the type locality in Germany, by: the absence of granulation on legs I–III, the absence of teeth on lunules IV, the apparent absence of eyes, the presence of teeth on terminal discs of egg processes (terminal discs jagged, ragged or almost smooth, but never dentate in M. sandrae View in CoL ), a lower process base/height ratio (65–69% in the new species vs. 109–111% in M. sandrae View in CoL ), and higher egg processes (11.8–20.0 µm in the new species vs. 4.3–7.6 µm in M. sandrae View in CoL ).

M. serratus Bertolani et al., 1996 View in CoL , recorded from the type locality in Italy, by: the absence of teeth on lunules IV, the apparent absence of eyes, a higher pt of buccal tube width (11.6–15.1 in the new species vs. 7.5–9.9 in M. serratus View in CoL ), a lower number of processes on the egg circumference (ca. 20 in the new species vs. ca. 29 in M. serratus View in CoL ), higher egg processes (11.8–20.0 µm in new species vs. 5.5–8.0 µm in M. serratus View in CoL ), wider egg processes (8.2–8.6 µm in the new species vs. ca. 6.5 µm in M. serratus View in CoL ), and larger diameter of terminal discs of egg processes (6.0–6.6 µm in the new species vs. ca. 2.5 µm in M. serratus View in CoL ).

M. sottilei Pilato et al., 2012 View in CoL , reported from the type locality in Belarus, by: the absence of granulation on legs I–III, the absence of teeth on lunules IV, the apparent absence of eyes, a higher pt of stylet supports (77.0– 80.2 in the new species vs. 75.3–76.6 in M. sottilei View in CoL ), a lower number of processes on the egg circumference (ca. 20 in the new species vs. ca. 29 in M. sottilei View in CoL ), a lower process base/height ratio (65–69% in the new species vs. 84–89% in M. sandrae View in CoL ), higher egg processes (11.8–20.0 µm in the new species vs. 5.4–6.2 µm in M. sottilei View in CoL ), wider bases of egg processes (8.2–8.6 µm in the new species vs. 4.8–5.2 µm in M. sottilei View in CoL ), and a larger diameter of terminal discs of egg processes (6.0–6.6 µm in the new species vs. 3.6–4.4 µm in M. sottilei View in CoL ).

M. terminalis Bertolani & Rebecchi, 1993 View in CoL , recorded from several localities in Italy, by: the absence of granulation on legs I–III, absence of teeth on lunules IV, the apparent absence of eyes, the presence of teeth on terminal discs of egg processes (terminal discs jagged in M. terminalis View in CoL ), a lower number of processes on the egg circumference (ca. 20 in the new species vs. ca. 26 in M. terminalis View in CoL ), a lower process base/height ratio (65–69% in the new species vs. 111–123% in M. terminalis View in CoL ), longer egg processes (11.8–20.0 µm in the new species vs. 4.6–6.0 µm in M. terminalis View in CoL ), wider egg processes (8.2–8.6 µm in the new species vs. 5.1–7.4 µm in M. terminalis View in CoL ), and a larger diameter of terminal discs of egg processes (6.0–6.6 µm in the new species vs. 3.8–4.8 µm in M. terminalis View in CoL ).

M. vladimiri Bertolani et al., 2011 View in CoL , reported from the type locality in Italy, by: the absence of granulation on legs I–III, the absence of teeth on lunules IV, the apparent absence of eyes, the presence of teeth on terminal discs of egg processes (terminal discs jagged in M. vladimiri View in CoL ), a lower process base/height ratio (65–69% in the new species vs. 78–91% in M. vladimiri View in CoL ), higher egg processes (11.8–20.0 µm in the new species vs. 6.5–8.0 µm in M. vladimiri View in CoL ), wider bases of egg processes (8.2–8.6 µm in the new species vs. 5.1–7.3 µm in M. vladimiri View in CoL ), and a larger diameter of terminal discs of egg processes (6.0–6.6 µm in the new species vs. 3.8–4.8 µm in M. vladimiri View in CoL ).