Honeybee Queen mandibular pheromone induces starvation in Drosophila melanogaster, implying a role for nutrition signalling in the evolution of eusociality.

Eusocial insect societies are defined by the reproductive division of labour, a social structure that is generally enforced by the reproductive dominant or queen. Reproductive dominance is maintained through behavioural dominance in some species as well as production of queen pheromones in others, or a mixture of both. Queen mandibular pheromone (QMP) is produced by honeybee (Apis mellifera) queens and has been characterised chemically. How QMP acts to repress worker reproduction, and how it has evolved this activity, remains less well understood. Surprisingly, QMP is capable of repressing reproduction in non-target arthropods which have not co-evolved with QMP, are never exposed to QMP in nature, and are up to 530 million years diverged from the honeybee. Here we show that, in Drosophila melanogaster, QMP treatment mimics nutrient limiting conditions, leading to disrupted reproduction. Exposure to QMP induces an increase in food consumption, consistent with that observed in D. melanogaster in response to starvation conditions. This response induces the activation of two checkpoints within the ovary that inhibit oogenesis. The first is the 2a/b ovarian checkpoint in the germarium, which reduces the flow of presumptive oocytes. A stage 9 ovarian checkpoint is also activated, causing degradation of oocytes. The magnitude of activation of both checkpoints is indistinguishable between QMP treated and starved individuals. As QMP seems to trigger a starvation response in an insect highly diverged from honeybees, we propose that QMP originally evolved by co-opting nutrition signalling pathways to regulate reproduction, a key step in the evolution of eusociality.

A Pugnacious ant (Anoplolepis custodiens) confounds ant assemblage responses to bush encroachment

Habitat structure is a key determinant of variation in biodiversity. The effects of increased vertical and horizontal vegetation structure can result in marked shifts in animal communities. This is particularly true for ants in response to woody thickening, with predicted negative impacts on ant diversity. We used pitfall traps to study the response of epigeic ants in two co-occurring dominant habitats (closed and open) of an African savanna biome experiencing extensive woody thickening. Although species richness was higher in open habitats, evenness was significantly lower. Thickening explained significant amounts of variation in ant composition, but site-specific characteristics and seasonality were more important. These site-specific characteristics were largely linked to Anoplolepis custodiens, a species that were locally abundant in open habitats with clayey soils, where they often accounted for more than 90% of all ant activity. As A. custodiens also responds positively to disturbance, indiscriminate bush clearing could lead to knock on effects associated with the numerical and behavioural dominance of this species.

The Dominance Behavioural System: A Review of Psychophysiological Features and Neurobiological Markers

This article provides a review of the literature data on the association between personal characteristics belonging to the behavioural dominance system and various psychophysiological, hormonal, and neurobiological indices. Social and behavioural features characteristic of dominance and subordination are described. The review discusses the studies showing the relationship between the indices of dominant or subordinate behaviours and adaptive capacity as well as levels of trait and state anxiety of individuals in different social contexts. Further, the key hormonal mechanisms underlying social dominance are reviewed. The dual-hormone hypothesis of dominance regulation under social stress is illustrated through studies showing the correlation between the changes in adrenocortical and sex hormone levels and their joint effect on the regulation of hierarchical status. Individual characteristics of prevalence or balance between the behavioural activation (motivation of gaining reward) and inhibition (motivation of avoiding failure) systems were found to play a crucial role in achieving higher dominance and the formation of ideas about one’s own social status. In addition, the neurophysiological and neurochemical mechanisms involved in the regulation of social hierarchical relationships are discussed. The review describes the features of brain activation during social interaction, including dominance and subordination, as well as context-dependent perception of one’s own social status and that of the opponent. The behavioural dominance system is proposed to be considered in the framework of the theory of functional systems, its architectonics, and central principles (interaction between its components, afferent synthesis, decision making, action program, and action result acceptor). Based on the systemic principles, social factors can be viewed as major environmental and triggering stimuli which affect the afferent synthesis, modulate the action program, and change the appraisal of results achieved by individuals during social interactions.

Behavioural dominance of the invasive red-billed leiothrix (Leiothrix lutea) over European native passerine-birds in a feeding context

Behavioural dominance and aggressiveness may be crucial traits facilitating the establishment of invasive species. Few studies considered agonistic interactions between exotic and native bird species in feeding contexts, particularly when the exotic has social habits. We aimed to know if individuals of a social invasive species, the red-billed leiothrix Leiothrix lutea, are: more aggressive; the initiators of the first interaction; and dominant (i.e., won most interactions) over native opponents in a feeding context. We performed an experiment in a closed environment forcing dyadic interactions between an individual of a native species facing a leiothrix individual. We found that the leiothrix was the initiator in most experiments, being apparently dominant over natives. However, the invader was not more aggressive than natives. This can increase the risk of injury for natives because the leiothrix has a relatively larger body size. We discuss possible negative impacts of the leiothrix on native species.

Sibling competition and hunger increase allostatic load in spotted hyaenas

Allostatis is the process of maintaining homeostatis through behavioural or physiological responses to challenges, and its cumulative energetic cost is termed allostatic load. The allostatic load hypothesis predicts that hunger and the mechanisms that establish and maintain social dominance should have a strong impact on allostatic load. In spotted hyaenas, dominance between twin siblings emerges during intense early competition for maternal milk and involves trained winner/loser effects . Conflict over access to teats declines with age as behavioural dominance conventions are established. In young litters, the allostatic load of subordinates measured in terms of faecal glucocorticoid metabolite concentrations (fGMCs) should be higher than that of dominants. When low milk provisioning threatens survival, hungry subordinates are more assertive, particularly when competing against a dominant sister. Dominants challenged by assertive subordinates should have allostatic loads and fGMCs above those of dominants with subordinates that adhere to dominance conventions. We show that in young litters, subordinates had significantly higher fGMCs than dominants, and dominant sisters had significantly higher fGMCs than dominant brothers. When hungry, both dominants and subordinates had significantly higher fGMCs than when fed. Our results provide evidence that hunger and sibling competition affect allostatic load in spotted hyaenas.

Interspecific aggression and behavioural dominance among four sympatric species of shrews

Level of interspecific aggression should reflect intensity of interference competition, and large dominant and small subordinate species should develop aggressive and passive agonistic behaviours, respectively, to achieve stable coexistence. We tested these ideas, investigating interspecific behavioural dominance in a four-species community of shrews varying in body size (Sorex minutus L., 1766; Sorex araneus L., 1758; Neomys anomalus Cabrera, 1907; Neomys fodiens (Pennant, 1771)) by placing interspecific pairs in a neutral field. The order of dominance (determined on the basis of duration of offensive and defensive behaviours, total time spent in the shelter, and a "final shelter resident" index) corresponded to the order of body size: N. fodiens > N. anomalus > S. araneus > S. minutus. The highest number of conflicts and the least pronounced dominance of N. anomalus over S. araneus suggest that the interference competition was strongest between these species. The different social organization of N. anomalus (tolerant and gregarious versus intolerant and solitary in the other three species) did not decrease its aggressiveness and dominance rank. The larger Neomys species were more aggressive and initiated relatively more offensive behaviours, whereas the smaller Sorex species initiated more defensive behaviours. The presence of food and shelter did not intensify conflicts. Nevertheless, dominant species restricted the access of subordinate species to the shelter.