Behavioral rhythmicity, age, division of labor and period expression in the honey bee brain.

Young adult honey bees work inside the beehive "nursing" brood around the clock with no circadian rhythms; older bees forage for nectar and pollen outside with strong circadian rhythms. Previous research has shown that the development of an endogenous rhythm of activity is also seen in the laboratory in a constant environment. Newly emerging bees maintained in isolation are typically arrhythmic during the first few days of adult life and develop strong circadian rhythms by about a few days of age. In addition, average daily levels of period (per) mRNA in the brain are higher in foragers or forager-age bees (> 21 days of age) relative to young nest bees (approximately 7 days of age). The authors used social manipulations to uncouple behavioral rhythmicity, age, and task to determine the relationship between these factors and per. There was no obligate link between average daily levels of per brain mRNA and either behavioral rhythmicity or age. There also were no differences in per brain mRNA levels between nurse bees and foragers in social environments that promote precocious or reversed behavioral development. Nurses and other hive-age bees can have high or low levels of per mRNA levels in the brain, depending on the social environment, while foragers and foraging-age bees always have high levels. These findings suggest a link between honey bee foraging behavior and per up-regulation. Results also suggest task-related differences in the amplitude of per mRNA oscillation in the brain, with foragers having larger diurnal fluctuation in per than nurses, regardless of age. Taken together, these results suggest that social factors may exert potent influences on the regulation of clock genes.

Changes in period mRNA levels in the brain and division of labor in honey bee colonies.

Previous research showed that age-related division of labor in honey bees is associated with changes in activity rhythms; young adult bees perform hive tasks with no daily rhythms, whereas older bees forage with strong daily rhythms. We report that this division of labor is also associated with differences in both circadian rhythms and mRNA levels of period, a gene well known for its role in circadian rhythms. The level of period mRNA in the brain oscillated in bees of all ages, but was significantly higher at all times in foragers. Elevated period mRNA levels cannot be attributed exclusively to aging, because bees induced to forage precociously because of a change in social environment had levels similar to normal age foragers. These results extend the regulation of a "clock gene" to a social context and suggest that there are connections at the molecular level between division of labor and chronobiology in social insects.

Isolation of seven unique biogenic amine receptor clones from the honey bee by library scanning.

The biogenic amine receptor genes constitute an ancient and highly divergent family within the larger superfamily of G-protein-coupled receptors. These receptors play a central role in modulating nerve cell activity and thus behaviour. Because the honey bee offers numerous advantages for behavioural studies we endeavoured to isolate as many members of this gene family as possible from the bee. We compared numerous approaches to gene isolation and found that PCR amplification from small subfractions of cDNA or genomic DNA libraries enabled us to isolate clones that are otherwise undetectable. In total we isolated seven biogenic amine receptor clones and identified five additional related sequences by low-stringency Southern hybridization. Two clones, AmBAR4 and AmBAR6, are 84% and 72% identical to the Drosophila 5-HT2 and D1b receptors, respectively, and probably represent orthologous genes. Phylogenetic analysis indicates that AmBAR5 clusters loosely with a variety of tyramine and octopamine receptors with which it shares <66% identity. The other four clones, AmBAR1, AmBAR2, AmBAR3 and AmBAR7, are weakly to moderately related (28-45% identical) to Drosophila dopaminergic or mammalian adrenergic receptors and probably represent receptors of these classes whose orthologues have not previously been isolated from any insect. The honey bee clones expand the size of the known insect biogenic amine receptor gene family to sixteen members. Therefore the size of the biogenic amine receptor gene family of insects approaches that of vertebrates. This is true despite the reduced behavioural and genetic complexity of the insects relative to vertebrate animals.