The cys-loop ligand-gated ion channel superfamily of the honeybee, Apis mellifera

Members of the cys-loop ligand-gated ion channel (cys-loop LGIC) superfamily mediate neurotransmission in insects and are targets of successful insecticides. We have described the cys-loop LGIC superfamily of the honeybee, Apis mellifera, which is an important crop pollinator and a key model for social interaction. The honeybee superfamily consists of 21 genes, which is slightly smaller than that of Drosophila melanogaster comprising 23 genes. As with Drosophila, the honeybee possesses ion channels gated by acetylcholine, γ-amino butyric acid, glutamate and histamine as well as orthologs of the Drosophila pH-sensitive chloride channel (pHCl), CG8916, CG12344 and CG6927. Similar to Drosophila, honeybee cys-loop LGIC diversity is broadened by differential splicing which may also serve to generate species-specific receptor isoforms. These findings on Apis mellifera enhance our understanding of cys-loop LGIC functional genomics and provide a useful basis for the development of improved insecticides that spare a major beneficial insect species.Sequence data from this article have been deposited with the EMBL/GenBank Data Libraries under accession nos. DQ667181–DQ667195.     

Worker honey bee ovary development: seasonal variation and the influence of larval and adult nutrition

We examined the effect of larval and adult nutrition on worker honey bee (Apis mellifera L.) ovary development. Workers were fed high or low-pollen diets as larvae, and high or low-protein diets as adults. Workers fed low-protein diets at both life stages had the lowest levels of ovary development, followed by those fed high-protein diets as larvae and low- quality diets as adults, and then those fed diets poor in protein as larvae but high as adults. Workers fed high-protein diets at both life stages had the highest levels of ovary development. The increases in ovary development due to improved dietary protein in the larval and adult life stages were additive. Adult diet also had an effect on body mass. The results demonstrate that both carry-over of larval reserves and nutrients acquired in the adult life stage are important to ovary development in worker honey bees. Carry-over from larval development, however, appears to be less important to adult fecundity than is adult nutrition. Seasonal trends in worker ovary development and mass were examined throughout the brood rearing season. Worker ovary development was lowest in spring, highest in mid-summer, and intermediate in fall.     

Modelling the role of intracolonial genetic diversity on regulation of brood temperature in honey bee (Apis mellifera L.) colonies

In polyandrous social insects such as honey bees, a worker’s affinity for a particular task may be genetically infl uenced and so some patrilines may have lower stimulus thresholds for commencing a task than others. We used simulation models to investigate the effects of intracolonial diversity in the task thresholds that stimulate workers to engage in heating and cooling during nest thermoregulation. First, we simulated colonies comprised of one or 15 patrilines that were engaged in heating the brood nest, and observed that single patriline colonies maintained, on average, less stable brood nest temperatures than multiple patriline colonies. Second we simulated colonies with five patrilines that were engaged in cooling their nest, recording the proportions of bees of different patrilines that engaged in nest cooling in response to changing temperatures. Both of our simulations show remarkably similar qualitative patterns to those that we have previously observed empirically. This provides further support for the hypothesis that geneticallybased variability in task thresholds among patrilines within honey bee colonies is an important contributor to the ability of colonies to precisely thermoregulate their nests, and we suggest that diversity is important for optimal expression of a range of other colony-level phenotypes. Received 17 June 2005; revised 27 October 2005; accepted 23 December 2005.     

Chill sensitivity of honey bee, Apis mellifera, embryos

Improved methods for preservation of honey bee, Apis mellifera L., germplasm would be very welcome to beekeeping industry queen breeders. The introduction of two parasites and the emergence of an antibiotic resistant disease have increased demands for resistant stock. Techniques for artificial insemination of queens are available, and semen has been cryopreserved with limited success. However, cryopreservation of embryos for rearing queens would mesh well with current practices and also provide drones (haploid males). Eggs at five ages between twenty-four hours and sixty-two hours were exposed to 0, -6.6, and/or -15 degrees C for various times, and successful hatch measured. Honey bee embryos show chill sensitivity as do other insect embryos, and the rate of chill injury increases dramatically with decrease in holding temperature. The 48 h embryos in both groups showed the greatest tolerance to chilling, although 44 h embryos were only slightly less so.     

蜜蜂春季增长阶段饲料适宜蛋白质水平的研究

早春将群势、蜂王年龄和质量基本一致的30群意大利蜜蜂Apis mellifera ligustica Spinola,随机分为5个处理组和1个对照组。处理组分别饲喂蛋白质水平为20%、25%、30%、35%和40%的5种代用花粉饲料,对照组饲喂油菜花粉,观测饲料蛋白质水平对蜂群群势、取食量、初生重以及蜂体组织蛋白含量的影响。结果表明对照组中蜜蜂对油菜花粉的取食量最高,但仅显著高于蛋白质水平为40%的饲料(P<0.05);蛋白质水平为25%、30%、35%的处理组群势增长差异不显著(P>0.05),但均显著高于对照组(P<0.05);随着饲料蛋白质水平升高,工蜂初生重逐渐升高,在35%到达最高值,随后又下降;饲喂蛋白质水平为20%、25%、30%饲料的蜂体组织蛋白含量与对照组差异不显著(P>0.05),饲喂蛋白质水平为35%、40%饲料的蜜蜂体组织蛋白含量显著高于对照组(P<0.05)。     

蜜蜂人工代用花粉中适宜钙磷水平的初步研究

钙磷是蜜蜂饲粮中必需的常量元素。为了探讨蜜蜂人工代用花粉中适宜的钙磷水平,本试验选取蜂王、群势基本一致的意大利蜜蜂Apis mellifera ligustica Spinola 70群,随机分为14个组,每组5群蜂,前12组饲喂采用均匀设计法配制的不同钙磷水平的人工代用花粉。第13组饲喂不加钙磷的人工代用花粉为负对照,第14组饲喂纯油菜花粉为正对照。试验从春繁开始,到刺槐流蜜期结束为止。试验期间测定蜂群的采食量、蜂群群势、幼蜂初生重,成蜂蜂体组织内钙磷含量。结果表明:当人工代用花粉中钙磷水平分别为0,0.65%时,蜂群的采食量、蜂群群势、幼蜂初生重均取得最大值;成蜂蜂体组织内钙含量与人工代用花粉中钙磷含量成正相关,成蜂蜂体组织内磷含量与人工代用花粉中钙磷含量之间没有相关性。     

Maintenance and loss of heterozygosity in a thelytokous lineage of honey bees (Apis mellifera capensis)

An asexual lineage that reproduces by automictic thelytokous parthenogenesis has a problem: rapid loss of heterozygosity resulting in effective inbreeding. Thus, the circumstances under which rare asexual lineages thrive provide insights into the trade-offs that shape the evolution of alternative reproductive strategies across taxa. A socially parasitic lineage of the Cape honey bee, Apis mellifera capensis, provides an example of a thelytokous lineage that has endured for over two decades. It has been proposed that cytological adaptations slow the loss of heterozygosity in this lineage. However, we show that heterozygosity at the complementary sex determining (csd) locus is maintained via selection against homozygous diploid males that arise from recombination. Further, because zygosity is correlated across the genome, it appears that selection against diploid males reduces loss of homozygosity at other loci. Selection against homozygotes at csd results in substantial genetic load, so that if a thelytokous lineage is to endure, unusual ecological circumstances must exist in which asexuality permits such a high degree of fecundity that the genetic load can be tolerated. Without these ecological circumstances, sex will triumph over asexuality. In A. m. capensis, these conditions are provided by the parasitic interaction with its conspecific host, Apis mellifera scutellata.     

Tactile Conditioning And Movement Analysis Of Antennal Sampling Strategies In Honey Bees (Apis mellifera L.)

Honey bees (Apis mellifera L.) are eusocial insects and well known for their complex division of labor and associative learning capability^{1, 2}. The worker bees spend the first half of their life inside the dark hive, where they are nursing the larvae or building the regular hexagonal combs for food (e.g. pollen or nectar) and brood³. The antennae are extraordinary multisensory feelers and play a pivotal role in various tactile mediated tasks⁴, including hive building⁵ and pattern recognition⁶. Later in life, each single bee leaves the hive to forage for food. Then a bee has to learn to discriminate profitable food sources, memorize their location, and communicate it to its nest mates⁷. Bees use different floral signals like colors or odors^{7, 8}, but also tactile cues from the petal surface⁹ to form multisensory memories of the food source. Under laboratory conditions, bees can be trained in an appetitive learning paradigm to discriminate tactile object features, such as edges or grooves with their antennae^{10, 11, 12, 13}. This learning paradigm is closely related to the classical olfactory conditioning of the proboscis extension response (PER) in harnessed bees¹⁴. The advantage of the tactile learning paradigm in the laboratory is the possibility of combining behavioral experiments on learning with various physiological measurements, including the analysis of the antennal movement pattern.     

First detection of Nosema ceranae, a microsporidian parasite of European honey bees (Apis mellifera), in Canada and central USA

Nosema ceranae is an emerging microsporidian parasite of European honey bees, Apis mellifera, but its distribution is not well known. Six Nosema-positive samples (determined from light microscopy of spores) of adult worker bees from Canada (two each from Nova Scotia, New Brunswick, and Prince Edward Island) and two from USA (Minnesota) were tested to determine Nosema species using previously-developed PCR primers of the 16S rRNA gene. We detected for the first time N. ceranae in Canada and central USA. One haplotype of N. ceranae was identified; its virulence may differ from that of other haplotypes.     

Nosema ceranae is a long-present and wide-spread microsporidian infection of the European honey bee (Apis mellifera) in the United States

Honey bee samples collected between 1995 and 2007 from 12 states were examined for the presence of Nosema infections. Our results showed that Nosema ceranae is a wide-spread infection of the European honey bee, Apis mellifera in the United States. The discovery of N. ceranae in bees collected a decade ago indicates that N. ceranae was transferred from its original host, Apis cerana to A. mellifera earlier than previously recognized. The spread of N. ceranae infection in A. mellifera warrants further epidemiological studies to identify conditions that resulted in such a widespread infection.