Stingless bee nesting biology David W. Roubik To cite this version: David W. Roubik. Stingless bee nesting biology. Apidologie, Springer Verlag, 2006, 37 (2), pp.124-143. hal-00892207 HAL Id: hal-00892207 https://hal.archives-ouvertes.fr/hal-00892207 Submitted on 1 Jan 2006 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Apidologie 37 (2006) 124–143 124 c INRA/DIB-AGIB/ EDP Sciences, 2006 DOI: 10.1051/apido:2006026 Review article Stingless bee nesting biology* David W. Ra,b a Smithsonian Tropical Research Institute, Apartado 0843-03092, Balboa, Ancón, Panamá, República de Panamá b Unit 0948, APO AA 34002-0948, USA Received 2 October 2005 – Revised 29 November 2005 – Accepted 23 December 2005 Abstract – Stingless bees diverged since the Cretaceous, have 50 times more species than Apis,andare both distinctive and diverse. Nesting is capitulated by 30 variables but most do not define clades. Both architectural features and behavior decrease vulnerability, and large genera vary in nest habit, architecture and defense. Natural stingless bee colony density is 15 to 1500 km−2. Symbionts include mycophagic mites, collembolans, leiodid beetles, mutualist coccids, molds, and ricinuleid arachnids. Mutualist bacteria and fungi preserve food and brood provisions. Nest associates include trees, termite, wasp and ant colonies. Ventilation is the means of nest environment regulation, achieved by fanning worker bees. Permanence of stingless bee nests, with annual mortality ca. 13%, implies a colony has 23 years to reproduce. Inability to freely swarm and single mating may all increase nesting specificity, competition, symbiosis and cleptobiosis in communities, while disease is rare. Meliponini / Apidae / nest architecture / nest microclimate / evolutionary ecology “Behind this door lives a town. They are 1. OVERVIEW dynamic and hardworking members of a na- tion whose origins go back millions of years 1.1. Nesting and diversity – years of persistent and gradual evolution. If nature be treated with only steel and fire, in a Stingless bees have populated tropical earth short time such actions will destroy the town for over 65 million years – longer than Apis, and its inhabitants. If, however, the heart feels the stinging honey bees (Camargo and Pedro, kinship with the wonders that have been cre- 1992; Michener, 2000). Both groups make ated, this tiny kingdom will be kept, so to bet- honey in perennial nests founded by a swarm ter understand the earth and its residents. The of sterile workers and a queen, and colonies well being of natural resources lies in your occasionally produce male bees.Yet stingless hands.” bees have 50 times more species and, as em- phasized here, differ from Apis in many bio- P. Nogueira-Neto, 1970, interpretation by logically significant ways. present author. Meliponines cannot migrate. Also unlike “As we have stated before, honey bees are honey bees, they produce brood in the manner not domesticated animals. It is possible to keep of solitary bees, with an egg placed on top of a bees in a hive only because we understand food mass in a sealed cell. In general, colonies their biology. Beekeeping is the application of make far less honey, and therefore have less our knowledge of bee behavior.” economic appeal, compared to honey bees (see R.A. Morse, 1994. Fig. A online only). In contrast to Apis, meliponines generally Corresponding author: D.W. Roubik, have no sting, mate only once, do not use wa- [email protected] ter to cool their nest or pure wax to build * Figures A–L are available at it, cannot freely swarm to reproduce (but in- http://www.edpsciences.org stead must first make a new domicile), and Article published by EDP Sciences and available at http://www.edpsciences.org/apido or http://dx.doi.org/10.1051/apido:2006026 Meliponine nesting 125 Figure 1. Distributional map of two distinctive nest entrance tubes constructed by workers of Ptilotrig- ona lurida (Camargo, from Camargo and Pedro, 2004). the males feed at flowers, while the gravid queens cannot fly. The manifold consequences of a single mating in stingless bees, in contrast Figure 2. Nest entrances of Partamona gregaria to multiple mating in Apis, are not explored and P. vicina in a termite nest on the side of a here (see, e.g. Peters et al., 1999). Instead, a hut (Amapá, Brazil) (Camargo, from Camargo and Pedro, 2003). view is given of general ecological and evo- lutionary settings in which stingless bee colo- nial life takes place. The nest is the central 1974). Colonies are active every day and there- place from which stingless bees mate, forage fore have sustained impact among the biota and pass through life stages. Nests are immo- (Roubik, 1989; Hansell, 1993). The individual bile fixtures and potentially long-lived, much species are recognizable from nest entrances like trees in forests where meliponines live. and often their particular site – much obvious Dispersion (spatial arrangement) of colony re- variety exists. Inside the nest, there are dif- sources and ‘stress sources’ have much signif- ferent shapes and arrangements of brood cells icance, thus a primary evolutionary response and food storage containers. Honey and pollen of meliponines to such critical factors de- are stored in separate ‘pots’. Stored nectar or fines their nesting biology (Michener, 1974; ripened honey are in nest cavity extremes (for Roubik, 1989; Nogueira-Neto, 1997; Camargo storage during heavy flowering periods), while and Pedro, 2002a, b; Biesmeijer et al., 2005). pollen and some honey surround the brood Published data on stingless bee nesting span area. However, robber bee genera Lestrimelitta over three centuries (Schwarz, 1948) and re- and Cleptotrigona collect and then store some cent syntheses include Michener (1961, 1974, mixed honey and brood provisions (Sakagami 2000) Wille and Michener (1973), Sakagami et al., 1993). The brood cells are spherical (1982), Wille (1983), Roubik (1989), and to ovoid, while food storage containers are Nogueira-Neto (1997). Research primarily small to large spheres, or are egg-shaped, or considers Neotropical stingless bees, because even conical or cylindrical. Often pots are roughly three-fourths of all species are Amer- pressed together in odd conglomerates, as are ican (Camargo and Pedro, 1992). the brood cells, ranging from individual cells on pillars, to sheets of orderly cells on combs, separated by the pillars (Fig. 3 and Figs. A, C, 1.2. Nest biology I online only). Nests made by stingless bee workers and Because nests are notable points of bee ac- habit (specific location) within forests (Kerr tivity, often spectacular examples of animal et al., 1967; Posey and Camargo, 1985; architecture, nesting biology is a highly visi- Camargo and Pedro, 2003) are foremost ble aspect of stingless bee behavior (Michener, among traits that, along with the workers, 126 D.W. Roubik males and queens, potentially help organize tivity, reproduction, and community ecology biological information with application to of stingless bees are intimately related to nest- research, economics, and conservation of pol- ing biology of each stingless bee species, and linators and honey sources. It is important to await thorough studies. intensify analysis and data collection now, be- Some large genera display considerable cause in many places the original forests occu- species-level variation in nesting habit, likely pied by hundreds of stingless bee species are produced by adaptive radiation. Large varia- degraded, threatened, or gone. tion occurs, for example, within the Neotrop- ical genus Plebeia. The nest sites and archi- tecture include nesting habits on tree trunks, 1.3. Nesting evolution and variability in crevices within rocks, in holes made by other animals, hollow stems (including tree It is a reasonable guess that not half of trunks) and in active termite nests. Some Ple- all meliponine nests are known, and few have beia build the regular pancake-like stack of been studied adequately. Architectural innova- brood cells separated by pillars and arranged tions may occur in a taxon after its divergence in circular combs, like that made by most stin- from ancestors, and at the same time, unrelated gless bees, whereas the smallest species do not species may converge due to the similarity of build combs but instead make loose chains of nesting materials or sites (see Tab. I). There cells or clusters (see Fig. A online only). Aus- is currently no clear picture as to what influ- troplebeia build loose combs, perhaps an in- ence the environment versus pre-programmed termediate comb condition (Michener, 1961). bee behavior supply to nest structures. For the Bee size appears decisive because, among tiny purpose of exploring stingless bee nesting, I Meliponini, clustered cells are the architec- generally refer to clades as genera, of which tural rule among phylogenetically diverse bees several dozen exist (see Camargo and Pedro, (Michener, 2001). In Melipona, Plebeia, Ple- 1992; Michener, 2000; Camargo and Roubik, beina, Nannotrigona, Trigona and Tetragona, 2005). In Table I, without an exhaustive list of stacked combs or a continuous spiral of comb species, it is evident the majority of nest char- are sometimes built by the same colony at acteristics are shared between various genera different times (pers. obs.). Pronounced dif- (see Kerr et al., 1967; Camargo, 1970; Wille ferences may occur geographically, as doc- and Michener, 1973; Roubik, 1979, 1983, umented for nest entrance tubes of Amazo- 1992; Sakagami, 1982; Dollin et al., 1997; nian Ptilotrigona lurida (Camargo and Pedro, Camargo and Pedro, 2003).