Insectes Sociaux https://doi.org/10.1007/s00040-019-00738-4 Insectes Sociaux RESEARCH ARTICLE Nest structure engineering of the leaf‑cutting ant, Acromyrmex landolti, in the semiarid Caatinga biome S. S. Verza1,2 · R. C. R. G. Gervásio2 · O. M. Alves e Silva2 · M. O. Gomes2 · S. A. Souza1 · R. M. Mussury1 Received: 23 January 2019 / Revised: 11 November 2019 / Accepted: 22 November 2019 © International Union for the Study of Social Insects (IUSSI) 2019 Abstract Nest architecture is a key factor in the development of ant colonies. Species-specifc constructed nests can be simple such as surface-level nests or elaborate such as subterranean or arboreal nests. Subterranean nests are more difcult to study and their internal structure is little known. This study was carried out with the objective of studying the structure of leaf-cutting ant nests in an extreme environment. For such, seven nests of Acromyrmex landolti were excavated in a semiarid region of the Caatinga, an exclusively Brazilian biome. The nests were measured both externally and internally and then photographed. Nests were found in open and sunny areas and externally all nests presented a loose soil mound, straw protection over the entrance hole, and a refuse dump. The number of underground chambers found ranged from 4 to 17, with difering heights, widths, and lengths. The chambers were found from near the surface of the ground to a maximum depth of 1.70 m. Our results showed that strategies used by A. landolti include the construction of an ornate straw tower at the entrance of the nest and the construction of deep underground rooms, with the chambers of fungi near the water table. The structure of the nests of A. landolti is probably related to its habit of building their nests in open, sunny locations associated with environmental factors characteristic of the semiarid climate of the Caatinga biome. Keywords Acromyrmex · Behavioral strategies · Leafcutter ants · Nest architecture · Refuse disposal · Semiarid climate Introduction main function of the structure of these subterranean nests, as well as that of surface, arboreal, and other social insect Most ants construct subterranean nests, built by excavating nests, is to protect the queen, ofspring, and adults from and moving a large amount of soil to the surface. The soil natural enemies and other hazards. The nests also favor the placed outside the nest facilitates their location and identi- production of appropriate microclimatic conditions for the fcation (Forti 1985) and also diferentiates them from nests maintenance of the colony (Sudd 1982) and, in the case of of other social insects that are constructed with materials fungal cultivator species, for the cultivation of the symbi- such as paper, mud, or wax (Theraulaz et al. 1998; Tschinkel otic fungi (Kleineidam and Roces 2000; Bollazzi and Roces 2015). Subterranean nests are more difcult to study and 2002; Verza et al. 2017). vary in their internal complexity from shallow and simpler It should be emphasized here that the energy spent in nests to those that reach 7 m deep and have numerous cham- the construction of the nest cannot be recovered, unlike that bers of diferent shapes and functions connected by tunnels spent in the production and care of eggs and larvae, which (Hölldobler and Wilson 1990; Moreira et al. 2004a). The can serve as an alternative source of energy for adults in the event of food shortage. According to Mikheyev and Tschinkel (2004), if a colony changes nests twice a year, * S. S. Verza it would spend about 20% of its energy on building nests. [email protected] Therefore, the internal and external architecture of ant nests 1 Faculty of Biological and Environmental Sciences, Federal should provide benefts that justify the high energy cost of University of Grande Dourados, Rodovia Dourados - Itahum, their excavation. KM 12, Dourados, Mato Grosso do Sul 79.800-000, Brazil Leafcutter ants belong to the genera Atta and Acromyr- 2 Faculty of Agrarian Sciences, Federal University of the São mex and are considered to be pests in agricultural and sil- Francisco Valley, Rodovia BR 407, 12 Lote 543, Nilo Coelho vicultural areas of the Neotropics (Mariconi 1970), as they - S/N C1, Petrolina, Pernambuco CEP 56300-990, Brazil Vol.:(0123456789)1 3 S. S. Verza et al. consume a greater amount of vegetation than any other local and 40°33′39″W, with an average altitude of 376 m. The pre- herbivore (Fowler et al. 1986; Hölldobler and Wilson 1990). dominant climate in the Caatinga is semiarid, an exclusively The ants use these plants as a substrate for the fungi that they Brazilian biome. According to Sena (2011), the semiarid grow and feed, maintaining a symbiotic relationship (Weber climate of this region has approximately 400 mm of precipi- 1972; Wilson 1980). Despite the designation of these ants tation per year. In this location, signifcant droughts occur, as pest species, it is impossible to deny the benefts that they with strong winds and almost cloudless sky, high tempera- can bring from the construction of their nests. These include tures with average around 30 °C, and, according to Santos positive impacts on the chemical and physical properties of (2009), on some days, the temperature can exceed 45 °C and the soil that favor its fertility, which promotes the efcient the soil temperature can reach 60 °C. A semiarid climate is cycling of nutrients and the growth of plants in many ecosys- one of the hottest and dryest on the planet. tems (Coutinho 1982; Haines 1983; Moutinho et al. 2003). The soil of the study region is sandy, shallow, and stony Atta and Acromyrmex nests have very diferent structural and the drainage network of the area is very vast, consisting characteristics (Hölldobler and Wilson 1990). It is worth of large rivers. One such river is the São Francisco, consid- highlighting here that nest architecture can be infuenced ered the most important river in the region, because it allows by soil type, local climatic conditions, water table limit, irrigation along its banks. Among tree and shrub vegetation and colony age (Jacoby 1950; Jonkman 1980; Moreira et al. adapted to the dry climate, a predominance of species have 2004a). Mature nests of Atta may have more than 7000 sub- stems with the capacity to store water such as cacti with terranean chambers that are connected to each other and the thorns and very few leaves (Santos 2009). surface via tunnels (Moreira et al. 2004a). In contrast, Acro- Seven random A. landolti nests of differing external myrmex have small nests, which usually contain only one dimensions (length and width) were excavated in the months or a few chambers (Gonçalves 1961, 1964; Fowler 1979). of August to October (dry season) of 2015. This ant was The maximum number of chambers previously reported for selected, because it is the most abundant leaf-cutting ant a nest of this genus was 26 (Verza et al. 2007). The exteri- species in the area. The nests were all marked internally with ors of Atta nests are mainly characterized by one or several cassava starch, which was introduced via one of the entrance loose earthen mounds, formed by the accumulation of soil holes using manual sprinkling equipment, to provide better extracted from the chambers (Autuori 1942; Forti 1985; visualization of the structure of the chambers and tunnels. Moreira et al. 2004a, b), while in Acromyrmex, the mounds Before beginning the excavation, the nests were measured may not be present. Both have entry or exit holes for the externally (the greatest width and length of the mounds) foraging or removal of soil excavated by the workers (Gon- and photographed. An average distance of 10 m between çalves 1964; Della Lucia and Moreira 1993). nests was adopted. The excavation process then proceeded, Leafcutter ants are highly specialized in nest construc- following the methods of Verza et al. (2007, 2017), by care- tion. The genus Acromyrmex, for example, has nests that fully opening a small ditch around the nesting area, excavat- exhibit diferences in both structure and shape, which may ing from the inside out and digging deeper in accordance sometimes contribute to species identifcation (Gonçalves with the appearance of the chambers; attention was directed 1967; Pacheco and Berti-Filho 1987; Forti et al. 2006; Verza toward the tunnels with the aim of not losing any chambers. et al. 2007, 2017). Thus, while many species have a lot of The chambers were quantifed and the following measure- loose soil around the entrance hole, including A. rugosus ments were taken: nest depth in relation to the ground level and A. subterraneus, it is known that A. balzani, A. landolti, and the length, width, and height of the chambers. To deter- and A. fracticornis build a straw tube over the nest entry mine the contents of the fungal chambers, the entire fungal hole. Underground nests reach a depth of almost 5 m, but culture of each chamber was placed in acrylic pots and taken most are shallow and reach a maximum of 60 cm (Gonçalves to a laboratory, where its total volume was measured using 1961; Fowler 1979; Farji-Brener 2000, Verza et al. 2007, 2 L graduated cylinders. 2017). The present study was performed with the objective of studying the external and internal architecture of the nests of A. landolti in a semiarid environment. Data analysis Using the recorded measurements, the average, standard Materials and methods deviation, and maximum and minimum range of the cham- bers and tunnels were calculated. The average and standard This study was conducted in an irrigation area in the Caat- error of the depth (cm) of the chambers with diferent con- inga biome, Petrolina-PE, at the Science Campus Agrarian tents were also calculated.
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