Nemesia arboricola Pocock 1903
| Autor: | Cassar, Thomas, Mifsud, David, Decae, Arthur E. |
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| Rok vydání: | 2022 |
| Předmět: | |
| DOI: | 10.5281/zenodo.6385310 |
| Popis: | Nemesia arboricola Pocock, 1903 Figs 1–4, 9–14, 23, 25, 27–53 Nemesia arboricola Pocock, 1903: 225–226 (♀). Nemesia arboricola – Baldacchino et al. 1993: 40. — Kritscher 1994: 49–57, figs 1–18 (♀); 1996: 121 (♀). — Dandria 2001: 103–107, fig. 1 pl. 1 (tree nest). — Le Peru 2011: 77. — Decae 2012: 25, fig. 2 (species groups). New diagnosis Female Nemesia arboricola from Malta is difficult to distinguish from N. macrocephala from nearby Sicily (Kritscher 1994). Females of the two species are among the largest Nemesia species known (fully grown females in both species range from 26 to 28 mm in total body length; the average in Nemesia is around 17.5 mm), and show only slight differences in their sexual and somatic morphology. Kritscher (1994) used the following three diagnostic characters to distinguish females of N. arboricola from those of N. macrocephala: (1) a different distance between the ALE and PLE, (2) a different shape of the spermathecal receptacles, (3) the presence or absence of labial cuspules. Pocock (1903) also reports the configuration of the eyes and the presence of labial cuspules as distinctive for N. arboricola. We found that, in general, the configuration of eyes and in particular the distance between the ALE and PLE (Figs 1–2 and 5–6) are unsuitable to distinguish N. arboricola from N. macrocephala on grounds of overlapping and highly variable measurements (dis. ALE–PLE av. 0.46, sd. 0.13 and av. 0.52, sd. 0.18, respectively). Although the shape of the receptacles appears to differ between the two species (Figs 3–4 and 7–8) it is difficult to quantify these differences. We therefore regard this character as only marginally reliable as diagnostic. We confirm Kritscher’s third diagnostic character (also noted in Pocock 1903) as truly diagnostic and agree that the presence of labial cuspules in females is distinctive for N. arboricola (Figs 9–10 cf. Figs 15–16). Furthermore, we found the dark coloured and speckled opisthosoma in N. arboricola (Figs 11–12) versus the lighter coloured opisthosoma with chevron stripes in N. macrocephala (Figs 17–18), and the thicker, slightly swollen, PMS (Figs 13–14 cf. Figs 19–20) in N. arboricola as diagnostic characters to distinguish females of the two species. Male Because the male of N. macrocephala remains unknown, no characters that might distinguish this species from N. arboricola can presently be given. The male of N. arboricola however differs from nearly all Nemesia species, for which the relevant information is available, by the absence of the PTR (see section ‘terminology’ above). The only other species known in which the PTR is missing is N. simoni O. Pickard- Cambridge, 1874 from southwestern France and northern Spain. To illustrate the presence and/or absence of PTR in different species of Nemesia species, Figs 21–24 show the dorso-distal male palps of four different Nemesia species collected from geographically widely separated locations in the Nemesia distribution range (N. bacelarae Decae, Cardoso & Selden, 2007 from Portugal (Fig. 21), N. cellicola Audouin, 1826 from the Middle East (Fig. 22), N. simoni from southern France (Fig. 23) and N. arboricola (Fig. 24) from Malta). Note that species from opposite far ends of the distribution range and a new species from centrally located Malta (Fig. 56) feature a pronounced PTR only absent in N. arboricola and N. simoni (Figs 23–26). Nemesia arboricola males can be distinguished from those of N. simoni by their generally larger size (TBL » 13, n = 2 vs TBL » 11, n = 7) and on several aspects of its sexual and somatic morphology, its burrow structure and its distribution (compare the male description below with information given on N. simoni in Moggridge 1873). Figs 25–26 show distinctive differences in male palps (shape of tibia) and palpal organs of N. arboricola and N. simoni. Holotype In collection BMNH, London, not examined.See Kritscher(1994) for a detailed description and photographs of the specimen (in very poor and fragile condition), and for conformation that N. arboricola is the common and widely distributed cork-door building Nemesia species found in the Maltese Archipelago. Material examined MALTA • 1 ♂; Comino; 36.02° N, 14.33° E; 23 Mar. 1975; P.J. Schembri leg.; (no. TD.4); NHMR • 1 ♀; Wied Incita; 35.88° N, 14.43° E; 25 Oct. 1980; P.J. Schembri leg.; (no. TD.1); NHMR • 1 ♀; Siggiewi, Buskett; 35.86° N, 14.39° E; 7 Sep. 1976; P.J. Schembri leg.; (no. TD.2); NHMR • 1 ♀; St. Paul’s Island; 35.96° N, 14.40° E; 20 Apr.1975; P.J. Schembri leg.; (no. TD.3); NHMR • 1 ♂; Gudja; 35.85° N, 14.50° E; 7 Nov. 2020; T. Cassar leg.; (no. TC-011); NHMW • 1 ♀; Zebbug; 35.87° N, 14.44° E, 27 Aug. 2020; T. Cassar leg.; (no. TC.014 terrestrial); NHMW • 1 ♀; Buskett; 35.86° N, 14.39° E; 5 Sep. 2020; T. Cassar leg.; (no. TC.015, arboreal); NHMR • 1 ♀; Valetta, Imsida; 35.89° N, 14.48° E; 20 Dec. 2017; (no. TC.016 arboreal); NHMR • 1 ♀; Comino; 36.02° N, 14.33° E; 11 Sep. 2020; T. Cassar leg.; (no. TC.017 terrestrial); NHMR. Description Male reference specimen (no. TD.4, NHMR) PRESERVATION AND CONDITION. Specimen 45 years preserved in 70% ethanol, generally in good condition (Fig. 27), right bulb removed for detail study (Figs 31–35). GENERAL COLORATION. Carapace uniform dark brown, chelicerae slightly darker than carapace, abdomen dorsal dark grey with light grey speckles in two parallel rows in the cardiac region (Fig. 27), abdomen ventral light yellowish brown, palps uniform dark brown, legs dark brown proximally grading to light brown distally, sternum uniform yellowish brown, labium dark brown. CARAPACE. Longer than wide (CW/CL 0.8), with light grey pubescence cover (partly lost), bristles concentrated along the margins and posterior on the thoracic part, cephalic part slightly elevated, thoracic part bulging slightly up from the fovea before sloping down to the posterior margin (Fig. 28). EYES. Ocular-tubercle (Fig. 28) dome-shaped, clypeus narrow sloping down from eyes, eye-group rectangular, twice as wide as long (EL/PR 0.51), AME about their diameter apart (dis.AME/dia.AME 0.94), dis.ALE–PLE femur IV> tibia IV (Fem4/Met4 = 0.97, Tib4/Met4 = 0.83), patella IV 0–1 retrolateral patellar spine, PTC all tarsi double combs of teeth, leg formula: 4123. OPISTHOSOMA. Ovoid, anterior narrowing, covered with bristles, PMS small, close together and less swollen than in females, PLS short, thick, proximal segment longer than medial + distal segment, spigots restricted to apical spigot field. MEASUREMENTS. TBL = 13.0; CL = 6.9; CW = 5.7; CP = 3.8; AR = 1.07; PR = 1.07; EL = 0.55; dia.ALE = 0.25; dia.PLE 0.21; dia.AME = 0.18; dia.PME = 0.17; dis.AME–AME = 0.17; dis.ALE–PLE = 0.15; SL = 3.6; SW = 2.9; LL = 0.6; LW = 1.0; Palp = 9.5 (1.3 + 2.8 + 1.8 + 3.6); Leg I = 20.3 (2.9 + 4.3 + 4.1 + 3.1 + 5.9); Leg II = 19.6 (2.6 + 4.6 + 4.2 + 2.9 + 5.3); Leg III = 19.5 (2.7 + 5.0 + 3.9 + 2.6 + 5,3); Leg IV = 25.0 (3.2 + 6.6 + 5.5 + 3.2 + 6.5); BuL = 2.11; BuW = 0.79; EmL = 1.06. VARIATION MALES (n = 2). TBL = 12.8, 13.0; CL = 5.8, 6.9; CW = 5.0, 5.7; CP = 3.5, 3.8; AR = 1.07, 1.11; PR = 1.07, 1.08; EL = 0.55, 0.56; dia.ALE = 0.25, 0.27; dia.PLE = 0.21, 0.22; dia.AME = 0.18; dia. PME = 0.15, 0.17; dis.AME–AME = 0.17, 0.20; dis.ALE–PLE = 0.10, 0.15; SL = 3.1, 3.6; SW = 2.5, 2.9; LL = 0.5, 0.6; LW = 0.9, 1.0; Palp = 8.6, 9.4; Leg I = 18.0, 20.3; Leg II = 17.3, 19.7; Leg III = 16.9, 19.4; Leg IV = 22.5, 24.9; Bul = 1.88, 2.11; BuW = 0.71, 0.79; EmL = 0.78, 1.06. Notes on female Females of N. arboricola have been described in proper detail by Pocock (1903) and Kritscher (1994). Here we compare specimens collected from tree-nests with specimens collected from terrestrial burrows. Figures 36–42, illustrate the variation in general appearance of the specimens in our study sample. Although individual variation in size, colour patterns and shades are evident, no qualitative morphological differences were found that would distinguish tree dwelling spiders from ground dwelling spiders at the species level. Moreover, all specimens in our sample closely fit the descriptions given by Pocock (1903) and Kritscher (1994). On these grounds we feel confident to state that arboreal and terrestrial specimens studied here are conspecific members of N. arboricola Pocock (1903). Figures 43–44, show characters common to all N. arboricola specimens (terrestrial and arboreal) studied, that distinguish N. arboricola from its supposed sister species, N. macrocephala. Mesurements, variation females (n = 7) TBL = 21.1–26.9 (av. 23.2, sd. 2.5); CL = 7.8–9.1 (av. 8.3, sd. 0.6); CW = 6.4–7.5 (av. 6.8, sd. 0.4); CP = 4.8–5.6 (av. 5.1, sd. 0.3); AR = 1.33–1.51 (av. 1.41, sd. 0.07); PR = 1.29–1.51 (av. 1.38, sd. 0.09); EL = 0.53–0.77 (av. 0.71, sd. 0.09); dia.ALE = 0.26–0.41 (av. 0.35, sd. 0.05); dia.PLE = 0.21–0.34 (av. 0.29, sd. 0.04); dia.AME = 0.13–0.20 (av. 0.18, sd. 0.03); dia.PME = 0.14–0.23 (av. 0.18, sd. 0.03); dis.AME–AME = 0.20–0.34 (av. 0.26, sd. 0.05); dis.ALE– PLE = 0.10–20 (av. 0.16, sd. 0.04); SL = 3.8–5.2 (av. 4.7, sd. 0.5); SW = 3.6–4.1 (av. 3.8, sd. 0.2); LL = 0.9–1.1 (av. 1.0, sd. 0.1); LW = 1.4–1.6 (av. 1.5, sd. 0.1); Palp = 11.9–13.5 (av. 12.5, sd. 0.8); Leg I = 16.1–18.7 (av. 17.1, sd. 1.0); Leg II = 14.6–16.9 (av. 15.4, sd. 0.8); Leg III = 14.5–16.9 (av. 15.5, sd. 0.9); Leg IV = 20.1–23.4 (av. 21.5, sd. 1.2). Field observations Nemesia arboricola constructs a simple tube-shaped burrow, capped with a sturdy lid (trapdoor) fitting neatly into the shaft (Figs 46, 51). Apparently older nests have been found with a layer of moss growing on the door surface (Fig. 45). The burrows are constructed in natural settings such as in tree trunks, between rocks in rubble walls and sloping ground (Figs 45–53). Tree-nests have been found between 150 cm and 8 cm above the ground surface in the trunks of ornamental palms (Phoenix canariensis and P. dactylifera), carob trees (Ceratonia siliqua) and olive trees (Olea europaea). In such tree-nests, spiders make use of pre-existing hollows and holes in the tree trunks into which they can snugly fit, or make use of hollows which are filled with woody debris and soil into which they can easily burrow. Burrows have also been found, at similar heights above the ground surface, in old rubble walls which hold back soil at field margins; here the spiders burrow into the clayey soil which fills the cracks between the individual stones. In both tree-nests and wall-nests, the burrow lids are flush with the vertical surface and dorsally hinged so that the trapdoor opens vertically upwards, with the shaft directed into the trunk/ wall perpendicular to the vertical axis. Nemesia arboricola also nests directly in the ground, but always it seems under one of the following conditions: the ground must be steeply sloping or, if the soil is flat, located immediately beneath an overhanging structure such as large rocks or a rubble wall (Figs 52–53). No burrows have been found on level ground in full exposure (‘in plain sight’ as it were). Tree-nests and wall-nests vary from 4.5 cm to 9.5 cm in depth for mature individuals, with burrow width varying according to the size (maturity) of the individual. Ground-nests in deep soil have, on average, deeper shafts than tree or wall-nests. In all cases, the burrow shaft is relatively simple in construction; it has entire, thick lining of silk with no internal doors, plugs or other features; and it is unbranched. The resident spiders themselves respond to disturbance by holding the hinged door very tightly; if the door is prised open using forceps (which takes considerable force) the spider may either retreat immediately head-up to the bottom of the shaft, or else repeatedly attempt to close the door while striking the forceps aggressively with its chelicerae. Recently hatched juveniles are retained within the mother’s burrow, from which they disperse and apparently establish themselves in close proximity, as N. arboricola populations are always localized and often quite dense. Moulted exoskeletons are discarded from the burrow and may be observed outside near the burrows if they are sheltered from wind. During the aestivation period, the door to the burrow is sealed shut from the inside, but the door still remains exposed as under normal circumstances (i.e., the burrow lid is not concealed with soil during periods of inactivity). Most mature males emerge from their burrows and wander between the months of November and March, though a few individuals may appear outside this timeframe. Published as part of Cassar, Thomas, Mifsud, David & Decae, Arthur E., 2022, The Nemesia trapdoor spider fauna of the Maltese archipelago, with the description of two new species (Araneae, Mygalomorphae, Nemesiidae), pp. 90-112 in European Journal of Taxonomy 806 (1) on pages 93-101, DOI: 10.5852/ejt.2022.806.1705, http://zenodo.org/record/6384569 {"references":["Pocock R. I. 1903. Descriptions of four new Arachnida of the orders Pedipalpi, Solifugae and Araneae. Annals and Magazine of Natural History (7) 11: 220 - 226. https: // doi. org / 10.1080 / 00222930308678753","Baldacchino A. E., Dandria D., Lanfranco E. & Schembri P. J. 1993. Records of spiders (Arachnida: Araneae) from the Maltese Islands (Central Mediterranean). The Central Mediterranean Naturalist 2 (2): 37 - 60.","Kritscher E. 1994. Nemesia arboricola Pocock, 1903, eine durch ein Jahrhundert hindurch verschollene Spinnerart der Maltesischen Inseln (Araneae: Nemesiidae). Annalen des Naturhistorischen Museums in Wien, Serie B 96: 49 - 57.","Dandria D. 2001. Observations on the endemic Maltese trapdoor spider Nemesia arboricola Pocock, 1903 (Araneae: Nemesiidae) The Central Mediterranean Naturalist 3 (3): 103 - 107.","Le Peru B. 2011. The spiders of Europe, a synthesis of data: Volume 1 Atypidae to Theridiidae. Memoires de la Societe Linneenne de Lyon 2: 1 - 522.","Decae A. E. 2012. Geography-related sub-generic diversity within the Mediterranean trapdoor spider genus Nemesia (Araneae, Mygalomorphae, Nemesiidae). Arachnologische Mitteilungen 43: 24 - 28. https: // doi. org / 10.5431 / aramit 4304","Audouin I. V. 1826. Explication sommaire des planches d'arachnides de l'Egypte et de la Syrie. In: Savigny I. C. (ed.) Description de l'Egypte et de la Syrie. Atlas d ' Histoire Naturelle 1 (4): 99 - 186, pl. 4. Paris.","Moggridge J. T. 1873. Harvesting Ants and Trap-Door Spiders. L. Reeve & Co., London."]} |
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