First description of the male of Agraecina agadirensis (Araneae: Liocranidae), an eyeless spider from the Moroccan High Atlas

Abstract. The female of Agraecina agadirensis was discovered during a scientific internship in autumn 2019 in a cave system of the Moroccan High Atlas. Since then, several surveys were needed to find a male of the species, which was finally collected in April 2021. Based on this specimen, a detailed description, an extended taxonomic diagnosis, photos of the habitus, as well as drawings of the male pedipalpus are presented. Furthermore, we draw attention to anthropogenic threats to this endemic troglobionte species and propose the legal protection of the Imi Ougoug cave system.

Diagnosis. Examination of the male specimen confirms the generic placement proposed for the female. Considering the somatic characteristics, A. agadirensis  most closely resembles the troglobiont Agraecina cristiani (Georgescu, 1989) in the lack of eyes and general colouration (light orange to pale yellowish) (Weiss & Sárbu 1994). Considering the genitalia, A. agadirensis resembles Agraecina scupiensis Deltshev, 2016 from grassland habitats in the Balkans (Del- tshev & Wang 2016), but in its distal part, the curved median apophysis of A. agadirensis does not narrow abruptly, and the conductor (translucent membrane surrounding the embolus) is not triangle-like. Agraecina agadirensis is also very close to Agraecina canariensis Wunderlich, 1992, which is mostly found in caves (Wunderlich 1992), but in its proximal part, the conductor of A. agadirensis shows an evagination and the median apophysis is distinctly more curved in its middle part. Furthermore, the palpal tibia of A. agadirensis is not clearly longer than the cymbium, but it is shorter (1.32 times).

Chelicerae. As in female.
Legs. Length of legs order: IV/I/II/III. Femora with three strong dorsal spines; tibiae I-II with three pairs of ventral spines, the third one in a distal position, distinctly shorter; metatarsi I-II with two pairs of ventral spines. Claws, number of teeth in the following order I/II/III/IV: 6/6/4/4. Trochanters notched. Opisthosoma. As in female. Pedipalp (Figs 2d-h, 3a-c). Tibial apophysis fairly robust, pointed in the axis of the tarsus, hardly bent in the middle part as seen from retrolateral side; median apophysis with broad base, gradually curved and narrowing towards the tip; embolus nearly straight, long and thin, tip surrounded by the conductor (translucent membrane), long and narrow. Distribution and habitat. Only known from the type locality (Tizgui, Morocco) (see Lecigne et al. 2020).

Notes on conservation
Currently, Agraecina agadirensis is only known from a single cave system. This makes the species highly vulnerable to anthropogenic disturbance and climatic changes, similar to many other troglobiont spider species (Mammola & Isaia 2017).
The example of the scorpion species Akrav israchanani Levy, 2007 (Scorpiones: Akravidae) from Levana Cave (Israel) (Fet et al. 2017) demonstrates the sensitivity of underground species to changes in their environment. Since its discovery no living specimens have been found in the caves where it had occured and the species became potentially extinct simply by a drop of the water level in the cave.
The threat for A. agadirensis is all the more real as Imi Ougoug has become the main or even the only destination for local speleological associations and tourist groups, as it is relatively close to the city and easy to access. Extensive tourist visits could predominately affect the first area where the species was observed, which is fairly easy to access from the entrance.
As explained by Mammola et al. (2018), another -indirect -threat is also expected to affect subterranean biocoenosis and ecosystems: changes in temperature. Indeed, specialized hypogean arthropods are known to have a reduced physiological tolerance to temperature fluctuations, which is especially problematic due to the current anthropogenic climate change.
To date, Agraecina agadirensis has only been observed at three different locations in the downstream part of the main gallery of Ifri Ouado. It would be interesting to study the population in order to evaluate its dispersal capacity and thermal tolerance. We do not have temperature records for the three relatively distant sectors of the cave system, which could give an indication of the temperature range of the species' environment. Searching for the species in other parts of the gallery, but also in neighbouring cave systems, should also be considered. To date, seven caves have been surveyed, five of which are in the same locality of Imi Ougoug, without the species being observed. If a study was to be carried out on Ifri Ouado, it could, on the one hand, help assess threats to this species using the International Union for Conservation of Nature (IUCN) red List criteria (see also recommendations in Mammola et al. 2019). Furthermore, such a study would also contribute to the discussion undertaken by Mammola et al. (2018) on understanding how climate change may impact troglobiont species.
The male of A. agadirensis was recorded in a deeper area that is difficult to access (large cavern, about 1500m from the entrance; unmapped, after the last siphon, clayey area and apparently often submerged in water) which suggests that this area may be currently relatively undisturbed by humans.
As discussed by Mammola & Isaia (2017), subterranean habitats support exceptional forms of life and represent critical habitats to be preserved and prioritized in conservation policies. Thus, for these reasons, we propose the legal protection of the Imi Ougoug cave system to conserve the ecosystems of these caves, including Agraecina agadirensis.