Magnetoreception system in honeybees (Apis mellifera)

Honeybees (Apis mellifera) undergo iron biomineralization, providing the basis for magnetoreception. We showed earlier the presence of superparamagnetic magnetite in iron granules formed in honeybees, and subscribed to the notion that external magnetic fields may cause expansion or contraction of the superparamagnetic particles in an orientation-specific manner, relaying the signal via cytoskeleton (Hsu and Li 1994). In this study, we established a size-density purification procedure, with which quantitative amount of iron granules was obtained from honey bee trophocytes and characterized; the density of iron granules was determined to be 1.25 g/cm(3). While we confirmed the presence of superparamagnetic magnetite in the iron granules, we observed changes in the size of the magnetic granules in the trophycytes upon applying additional magnetic field to the cells. A concomitant release of calcium ion was observed by confocal microscope. This size fluctuation triggered the increase of intracellular Ca(+2) , which was inhibited by colchicines and latrunculin B, known to be blockers for microtubule and microfilament syntheses, respectively. The associated cytoskeleton may thus relay the magnetosignal, initiating a neural response. A model for the mechanism of magnetoreception in honeybees is proposed, which may be applicable to most, if not all, magnetotactic organisms.     

Effects of cold narcosis on memory acquisition,consolidation and retrieval in honeybees(Apis mellifera)

In learning and memory studies on honeybees(Apis mellifera),cold-induced narcosis has been widely used to temporarily immobilize honeybees.In this study,we investigated the effects of cold narcosis on the associative memories in honeybees by using the proboscis extension response(PER)paradigm.Severe impairments in memory acquisition was found when cold narcosis was performed 30 min,instead of 1 h before training.Locomotor activities were reduced when honeybees were tested 15 min,instead of30 min after cold narcosis.These results indicate that cold narcosis impairs locomotor activities,as well as memory acquisition in a time-dependent manner,but by comparison no such effects on memory retrieval have yet been observed.[0]     

Morphometrics and adaptatives aspects in africanized honeybees (Apis mellifera)

The introduction of the African bees (Apis mellifera scutelata) in Brazil and their expansion in the American Continent created the opportunity to study the process of species adaptation in a new environment. In that process, within intra-specific variability, normalising selection can favour individuals that present a better adaptative morphology and they will constitute the most frequent type found in the population. To test that hypothesis morphometric analyses in samples of colonies of africanized bees and in samples of the populations were performed. The development of the colonies was also evaluated in terms of the amount of their brood, honey and pollen. Analysis of the data indicates that more developed colonies are formed by individuals closer to the population average with concerning morphological traits.     

Flight machinery dimensions of honeybees, Apis mellifera

The flight muscles of different honeybee subspecies are known to have different allozymes of malate dehydrogenase (Mdh) which in turn are correlated with differences in mass-specific metabolic flight rate. Flight capacity is also affected by dimensional, morphological relationships of mass and area which allow an estimation of an “excess power index”. The dimensions of the flight machinery of honeybees (based on our own data) were coupled with the frequency distributions of Mdh (taken from the literature) to compare nine subspecies of African and nine European honeybees, Apis mellifera as miniature aircraft. The two groups differed significantly for five dimensions of flight machinery and in the distribution frequencies of Mdh phenotypes. In the African group, northern and southern subgroups occurred which significantly differed in body mass and excess power index, while flight engine and body mass varied proportionately. In the European group, wing surface was nearly constant but body mass and the thorax/body mass ratio varied significantly resulting in significantly differing wing loading values. The final excess power index (modified for allozyme phenotype) of the European bees reflected both flight machinery and allozymic differences. Mdh allozymic phenotype frequencies were correlated with the dimensional morphological components of the excess power index. As a group, the European subspecies of honeybees were 33% heavier and had 15% more wing surface area than the African group. However, the former have a thorax/body mass ratio of 0.45 and wing loading value of 0.48 against the latter's 0.53 and 0.35 respectively. This confers an advantage on the African group solely on the grounds of dimensions because there was proportionately less mass per unit area of wing surface and so lower lift requirement. The better engine to aircraft mass ratio provides greater power per unit mass in the African group taken as miniature aircraft. Differences in metabolic capacity associated with Mdh allozymes (taken from the literature) finally result in an excess power index that is 38% greater in the African than European subspecies of honeybees. Accepted: 22 December 1998     

Localization of short-term memory in the brain of the bee, Apis mellifera

ABSTRACT. Fixed honey-bees were conditioned to a scent in a one-trial learning paradigm. In contrast to free-flying colour-conditioned bees, fixed scent-conditioned bees do not show a biphasic time dependence of the conditioned response. Small metal probes were used to cool localized areas of the antennal lobes, alpha-lobes, and calyces of the mushroom bodies of the brain at various times after conditioning. Localized cooling impaired the formation of memory in all three structures. The susceptibility to impairment after conditioning lasted approximately 3 min in the antennal lobes, 7 min in the alpha-lobes, and 10 min in the calyx area. It was possible to determine the influence of the contralateral hemisphere (relative to the learning antenna) by conditioning bees with only one antenna. No contralateral impairment was found in the antennal lobes; there were minor effects in the alphalobes; contralateral cooling led to reductions of the conditioned response only in the calyx area. The temperature dependence of memory impairment was different for the antennal lobes and the mushroom bodies (alpha-lobes and calyces). The latter were most sensitive to cooling at 5°C. No correlation between cooling duration and impairment of memory was found in the antennal lobes, but there was a linear relation between impairment and cooling duration in the alpha-lobes. Brief cooling (5 or 10 s) resulted in significant impairment of memory formation only in the calyx area. A series of control experiments proved that the impairment of memory is due to a reversible block of neural activity. It was possible to show that the impairment is specific for the three neural structures analysed, by cooling the lobula of the optic system at various times after conditioning. Lesions of the brain or application of KCl also resulted in time-dependent reductions of the conditioned response. Cooling the entire animal at various times after conditioning led to similar memory impairment to that resulting from localized cooling of the alphalobes.     

Adaptation of worker honeybees (Apis mellifera) to their alarm pheromones

ABSTRACT. Honeybees rapidly became adapted to synthetic alarm pheromone components dispensed within their hives, and were less; inclined to sting both unmarked targets and targets marked with the; alarm pheromone. The possible application to beekeeping is discussed.     

Experimental infection of Apis mellifera honeybees with Nosema ceranae (Microsporidia)

In this report, an experimental infection of Apis mellifera by Nosema ceranae, a newly reported microsporidian in this host is described. Nosema free honeybees were inoculated with 125,000 N. ceranae spores, isolated from heavily infected bees. The parasite species was identified by amplification and sequencing the SSUrRNA gene of the administered spores. Three replicate cages of 20 honeybees each were prepared, along with one control cage (n=20) supplied with sugar syrup only. The infection rate was 100% at the dosage administered. The presence of Nosema inside ventricular cells was confirmed in the samples using ultrathin sectioning and transmission electron microscopy. By day 3 p.i. a few cells (4.4%+/-1.2) were observed to be parasitized, whereas by 6 days p.i. more than half of the counted cells (66.4%+/-6) showed different parasite stages, this value increasing on day 7 p.i. (81.5%+/-14.8). Only one control bee died on day 7 p.i. In the infected groups, mortality was not observed until day 6 p.i. (66.7%+/-5.6). Total mortality on day 7 p.i. was 94.1% in the three infected replicates and by day 8 p.i. no infected bee was alive. After the infection, the parasites invaded both the tip of folds and the basal cells of the epithelium and the autoinfective capacity of the spores seemed to spread the infection rapidly between epithelial cells. On day 3 p.i., mature spores could be seen inside host cell tissue implying that the developmental cycle had been completed. The large number of parasitized cells, even the regenerative ones, the presence of autoinfective spores and the high mortality rate demonstrate that N. ceranae is highly pathogenic to Apis mellifera. Possible relation with bee depopulation syndrome is discussed by authors.     

Social synchronization of circadian rhythms of metabolism in honeybees (Apis mellifera)

ABSTRACT. Groups of honeybee workers ( Apis mellifera Linn.; Hymenoptera: Apidae) show endogenous circadian rhythms in metabolic activity. Workers entrained to two different photoperiods, when put together in a group, coordinate their individual metabolic activity cycles into a synchronized group oscillation. Either physical interaction among workers, or a low volatility contact pheromone, is implicated in the control of this oscillating system.     

Influence of carbon dioxide on Nosema apis infection of honeybees (Apis mellifera)

Young workers of the honeybee Apis mellifera carnica were individually inoculated with Nosema apis spores subjected to carbon dioxide (CO(2)) treatment. The spores were kept in a CO(2) atmosphere for 30, 35 and 40 h. The course of the infection was evaluated on the basis of the survival rate of bee workers and the number of N. apis spores in their digestive tracts. CO(2) treatment of N. apis spores resulted in faster proliferation of the parasite as well as higher mortality among workers infected with spores kept in CO(2) for 30 and 35 h.     

Influence of immature queen honeybees (Apis mellifera) on queen rearing and foraging

ABSTRACT. Providing queenless colonies with five queen cells containing larvae or pupae diminished the number of queen cells and queen cell cups subsequently produced, but not as effectively as the provision of a mated laying queen. Immature queens were more effective than the mature queens in stimulating pollen collection, but were less effective in stimulating nectar collection.     

Influence of virgin queen honeybees (Apis mellifera) on queen rearing and foraging

ABSTRACT. Virgin queens are as effective as mated laying queens at inhibiting colonies from rearing queens but not from producing queen cell cups. Colonies without brood produce fewer queen cell cups than similar colonies that have brood. Colonies without queens forage much less and collect less pollen than with either a mated or virgin queen. Colonies with virgin queens forage as much as those with mated queens but collected less pollen.     

Mitochondrial DNA variability in the Canary Islands honeybees (Apis mellifera L.)

The mitochondrial DNA (mtDNA) of individuals from 79 colonies of Apis mellifera from five Canary Islands was studied using the Dra I test based on the restriction of PCR products of the tRNAleu–COII intergenic region. Five haplotypes of the African (A) lineage and one of the west European (C) lineage were found. The haplotypes A14 and A15 are described for the first time. These haplotypes have a new P sequence named P₁. The wide distribution and high frequency of haplotype A15 suggest that it is characteristic of the Canarian Archipelago. Sources of haplotype variability of honeybee mtDNA in the Canary Islands (waves of colonization from Africa, queen importations, habitat diversification) are discussed.     

Transfer of pheromone from immature queen honeybees, Apis mellifera

ABSTRACT. Immediately after visiting cells containing immature queens, workers of Apis mellifera L. were observed to engage in prolonged cleaning, particularly of their tongues when they had visited larvae, and of their antennae when they had visited pupae. Thereafter other workers usually initiated and made antennal contacts with them. During such antennal contact the bee that had visited the queen larva often donated food. The implication of these findings on the distribution of pheromone produced by immature queens is discussed. Workers were stimulated to make antennal contact with the excised heads of bees from a queen's court, providing further evidence that queen pheromone is transferred between workers' antennae.     

Learning and discrimination of individual cuticular hydrocarbons by honeybees (Apis mellifera)

In social insect colonies, recognition of nestmates, kinship, caste and reproductive status is crucial both for individuals and for the colony. The recognition cues used are thought to be chemical, with the hydrocarbons found on the cuticle of insects often cited as being particularly important. However, in honeybees (Apis mellifera) the role of cuticular hydrocarbons in nestmate recognition is controversial. Here we use the proboscis extension response (PER) conditioning paradigm to determine how well honeybees learn long-chain linear alkanes and (Z)-alkenes present on the cuticle of worker bees, and also how well they can discriminate between them. We found large differences both in learning and discrimination abilities with the different cuticular hydrocarbons. Thus, the tested hydrocarbons could be classified into those which the bees learnt and discriminated well (mostly alkenes) and those which they did not (alkanes and some alkenes). These well-learnt alkenes may constitute important compounds used as cues in the social recognition processes.