Holger Scharpenberg scite author profile

Queen pheromones interfere with worker reproduction in social insects. However, there is still an unresolved question as to whether this pheromone acts as an "honest" signal for workers, giving a reliable indication of the queen's reproductive value, or as a suppressive agent, inhibiting worker reproduction independent of the queen's reproductive capacity. In honeybees (Apis mellifera), the queen's mandibular gland secretion, a mix of fatty acids and some aromatic compounds, is crucial for regulating the reproductive division of labor in the colony inhibiting ovary development in workers. We quantified the mandibular gland secretions of virgin, drone-laying, and naturally mated queens using gas chromatography to test whether the queens' mating, ovary activation, or the reproductive value for workers correlated with the composition of the secretion. Although the absolute amounts of the "queen substance" 9-oxo-2(E)-decenoic acid (9-ODA) were similar among the three groups, the proportions of 9-ODA decreased with increasing reproductive quality. Furthermore, the ratios of queen to worker compounds were similar in all three treatment groups, irrespective of the reproductive capacity. A multivariate analysis including all six compounds could not separate drone-laying queens from naturally mated ones, both with active ovaries but only the latter ensuring colony survival. We suggest that the mandibular gland pheromones are unlikely to function as reliable indicators of queen reproductive value and rather operate as an agent to suppress worker reproduction. This does not exclude the possibility that other "honest" pheromone signals exist in the honeybee colony, but these would have to arise from other semiochemicals, which could be produced by both the queen and the brood.

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Pupal developmental temperature and behavioral specialization of honeybee workers (Apis mellifera L.)

Becher

Scharpenberg

Moritz

2009

J Comp Physiol A

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Honeybees (Apis mellifera) are able to regulate the brood nest temperatures within a narrow range between 32 and 36 degrees C. Yet this small variation in brood temperature is sufficient to cause significant differences in the behavior of adult bees. To study the consequences of variation in pupal developmental temperature we raised honeybee brood under controlled temperature conditions (32, 34.5, 36 degrees C) and individually marked more than 4,400 bees, after emergence. We analyzed dancing, undertaking behavior, the age of first foraging flight, and forager task specialization of these workers. Animals raised under higher temperatures showed an increased probability to dance, foraged earlier in life, and were more often engaged in undertaking. Since the temperature profile in the brood nest may be an emergent property of the whole colony, we discuss how pupal developmental temperature can affect the overall organization of division of labor among the individuals in a self-organized process.

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Male fitness of honeybee colonies (Apis mellifera L.)

Kraus

Neumann

Scharpenberg

et al. 2003

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Honeybees (Apis mellifera L.) have an extreme polyandrous mating system. Worker offspring of 19 naturally mated queens was genotyped with DNA microsatellites, to estimate male reproductive success of 16 drone producing colonies. This allowed for estimating the male mating success on both the colony level and the level of individual drones. The experiment was conducted in a closed population on an isolated island to exclude interferences of drones from unknown colonies. Although all colonies had produced similar numbers of drones, differences among the colonies in male mating success exceeded one order of magnitude. These differences were enhanced by the siring success of individual drones within the offspring of mated queens. The siring success of individual drones was correlated with the mating frequency at the colony level. Thus more successful colonies not only produced drones with a higher chance of mating, but also with a significantly higher proportion of offspring sired than drones from less successful colonies. Although the life cycle of honeybee colonies is very female centred, the male reproductive success appears to be a major driver of natural selection in honeybees.

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A technical note for using microsatellite DNA analyses in haploid male DNA pools of social Hymenoptera

et al. 2003

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The analyses of haploid male DNA pooled (MDP) samples can increase the cost efficiency in population genetic studies for a variety of applications in fundamental and applied screening of social Hymenoptera populations. Depending on the research problem addressed it can reduce the number of genotyped samples per study by orders of magnitude. In this study we show the feasibility of MDPs for assessing population allele frequencies, mother queen genotypes and mutation rates for microsatellite loci in the honeybee (Apis mellifera). The main purpose of MDP genotyping is not to replace individual based analyses but to discard non-informative samples and monomorphic loci from further analyses.

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Reliability of an island mating apiary under routine management

Scharpenberg

Neumann

Praagh

et al. 2006

Journal of Apicultural Research

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