Canadell J, Riba M, Andrés P (1988) Biomass equations for Quercus ilex L. in the Montseny massif, northeastern Spain. Forestry 61:137-147.
Franch J, Espadaler X (1988) Ants as colonizing agents of pine stumps in San Juan de la Peña (Huesca, Spain). Vie et Milieu 38:149-154.
Masó J., Pons X., Zabala A. (2012). Tuning the second-generation SDI: Theoretical aspects and real use cases. International Journal of Geographical Information Science 26: 983-1014.
Sgolastra F., Kemp W.P. Maini S., Bosch J. (2012) Duration of prepupal summer dormancy regulates synchronization of adult diapause with winter temperatures in bees of the genus Osmia. Journal of Insect Physiology 58: 924-933.
Carter M.S., Larsen K.S. Emmett B., Estiarte M., Field C., Leith I.D., Lund M., Meijide A., Mills R.T.E., Niinemets Ü., Peñuelas J., Portillo-Estrada M., Schmidt I.K. Selsted M.B. Sheppard L.J., Sowerby A., Tietema A., Beier C. (2012). Synthesizing greenhouse gas fluxes across nine European peatlands and shrublands – responses to climatic and environmental changes. Biogeosciences, 9: 3739-3755.
Hui C, Roura-Pascual N, Brotons L, Robinson RA, Evans KL (2012) Flexible dispersal strategies in native and non-native ranges: environmental quality and the ‘good–stay, bad–disperse’ rule. Ecography 35: 1024-1032.
Sardà-Palomera F, Brotons L, Villero D, Sierdsema H, Newson S, Jiguet F (2012) Mapping from heterogeneous biodiversity monitoring data sources. Biodiversity and Conservation 21: 2927-2948.
Arnan X., Cerda X., Retana J. (0) Ant functional responses along environmental gradients. Journal of Animal Ecology. 83: 1398-1408.EnlaceDoi: 10.1111/1365-2656.12227
Understanding species distributions and diversity gradients is a central challenge in ecology and requires prior knowledge of the functional traits mediating species' survival under particular environmental conditions. While the functional ecology of plants has been reasonably well explored, much less is known about that of animals. Ants are among the most diverse, abundant and ecologically significant organisms on earth, and they perform a great variety of ecological functions. In this study, we analyse how the functional species traits present in ant communities vary along broad gradients in climate, productivity and vegetation type in the south-western Mediterranean. To this end, we compiled one of the largest animal databases to date: it contains information on 211 local ant communities (including eight climate variables, productivity, and vegetation type) and 124 ant species, for which 10 functional traits are described. We used traits that characterize different dimensions of the ant functional niche with respect to morphology, life history and behaviour at both individual and colony level. We calculated two complementary functional trait community indices ('trait average' and 'trait dissimilarity') for each trait, and we analysed how they varied along the three different gradients using generalized least squares models that accounted for spatial autocorrelation. Our results show that productivity, vegetation type and, to a lesser extent, each climate variable per se might play an important role in shaping the occurrence of functional species traits in ant communities. Among the climate variables, temperature and precipitation seasonality had a much higher influence on functional responses than their mean values, whose effects were almost lacking. Our results suggest that strong relationships might exist between the abiotic environment and the distribution of functional traits among south-western Mediterranean ant communities. This finding indicates that functional traits may modulate the responses of ant species to the environment. Since these traits act as the link between species distributions and the environment, they could potentially be used to predict community changes under future global change scenarios.
Boulay R., Arnan X., Cerda X., Retana J. (0) The ecological benefits of larger colony size may promote polygyny in ants. Journal of Evolutionary Biology. 27: 2856-2863.EnlaceDoi: 10.1111/jeb.12515
How polygyny evolved in social insect societies is a long-standing question. This phenomenon, which is functionally similar to communal breeding in vertebrates, occurs when several queens come together in the same nest to lay eggs that are raised by workers. As a consequence, polygyny drastically reduces genetic relatedness among nestmates. It has been suggested that the short-term benefits procured by group living may outweigh the costs of sharing the same nesting site and thus contribute to organisms rearing unrelated individuals. However, tests of this hypothesis are still limited. To examine the evolutionary emergence of polygyny, we reviewed the literature to build a data set containing life-history traits for 149 Palearctic ant species and combined this data set with a reconstructed phylogeny. We show that monogyny is the ancestral state and that polygyny has evolved secondarily and independently throughout the phylogenetic tree. The occurrence of polygyny is significantly correlated with larger colony size, dependent colony founding and ecological dominance. Although polydomy (when a colony simultaneously uses several connected nests) tends to occur more frequently in polygynous species, this trend is not significant when phylogenetic history is accounted for. Overall, our results indicate that polygyny may have evolved in ants in spite of the reduction in nestmate relatedness because large colony size provides immediate ecological advantages, such as the more efficient use of temporal food resources. We suggest that the competitive context of ant communities may have provided the conditions necessary for the evolution of polygyny in some clades.
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