Dead or alive: deformed wing virus and Varroa destructor reduce the life span of winter honeybees

Elevated winter losses of managed honeybee colonies are a major concern, but the underlying mechanisms remain controversial. Among the suspects are the parasitic mite Varroa destructor, the microsporidian Nosema ceranae, and associated viruses. Here we hypothesize that pathogens reduce the life expectancy of winter bees, thereby constituting a proximate mechanism for colony losses. A monitoring of colonies was performed over 6 months in Switzerland from summer 2007 to winter 2007/2008. Individual dead workers were collected daily and quantitatively analyzed for deformed wing virus (DWV), acute bee paralysis virus (ABPV), N. ceranae, and expression levels of the vitellogenin gene as a biomarker for honeybee longevity. Workers from colonies that failed to survive winter had a reduced life span beginning in late fall, were more likely to be infected with DWV, and had higher DWV loads. Colony levels of infection with the parasitic mite Varroa destructor and individual infections with DWV were also associated with reduced honeybee life expectancy. In sharp contrast, the level of N. ceranae infection was not correlated with longevity. In addition, vitellogenin gene expression was significantly positively correlated with ABPV and N. ceranae loads. The findings strongly suggest that V. destructor and DWV (but neither N. ceranae nor ABPV) reduce the life span of winter bees, thereby constituting a parsimonious possible mechanism for honeybee colony losses.     

The function of juvenile hormone in adult worker honeybees, Apis mellifera

The injection of high doses of JH-III into adult worker honeybees causes the hypopharyngeal glands to degenerate and lowers the vitellogenin synthesis rate as well as the total haemolymph protein concentration. The injection of low doses increases the protein titre and stimulates vitellogenin synthesis while the hypopharyngeal glands develop.The effects of high doses of JH corresponds to the normal physiological changes in the ageing bee, especially at the time of the transformation into field bees. Hormone titre measurements show a drastic increase during adult life, which together with the injection experiments seems to indicate stimulating effects of low JH titre on protein synthesis and hypopharyngeal gland development during the first phase of adult life, and inhibiting and degeneration inducing effects of the high JH titre during the second phase of life.Thus it is possible that the physiological changes correlated with changes in behaviour of the adult worker bee are controlled by the JH titre.     

蜜蜂肠道微生物与其社会性的关系

蜜蜂是一种典型的营群居生活的社会性昆虫,相比独居生活的昆虫,其肠道微生物具有独特的区系结构。这种独特肠道微生物与其社会性之间的关系是一个重要的科学问题。现有研究显示,蜜蜂肠道的优势菌包括9大类群。消化道不同区段的优势菌种类和丰度存在差异。主要表现为前肠种类少、丰度低、后肠种类多、数量大,占了全消化道微生物的99%以上。不同社会分工的蜜蜂肠道微生物区系结构存在差异,肠道微生物会通过影响胰岛素信号的传导、保幼激素和卵黄原蛋白的合成以及蜜蜂抗氧化应激的能力等对蜜蜂的级型分化、社会分工、摄食行为及寿命长短产生调节作用。除此之外,蜜蜂肠道微生物还具有激活免疫、抑制病原菌生长、降解食物、促进养分吸收、解毒、发酵蜂蜜和蜂粮等作用。主要针对蜜蜂肠道微生物的基本特征及其与蜜蜂社会性的关系作一简要综述。     

Mate number,kin selection and social conflicts in stingless bees and honeybees

Microsatellite genotyping of workers from 13 species (ten genera) of stingless bees shows that genetic relatedness is very high. Workers are usually daughters of a single, singly mated queen. This observation, coupled with the multiple mating of honeybee queens, permits kin selection theory to account for many differences in the social biology of the two taxa. First, in contrast to honeybees, where workers are predicted to and do police each other''s male production, stingless bee workers are predicted to compete directly with the queen for rights to produce males. This leads to behavioural and reproductive conflict during oviposition. Second, the risk that a daughter queen will attack the mother queen is higher in honeybees, as is the cost of such an attack to workers. This explains why stingless bees commonly have virgin queens in the nest, but honeybees do not. It also explains why in honeybees the mother queen leaves to found a new nest, while in stingless bees it is the daughter queen who leaves.     

The gene vitellogenin has multiple coordinating effects on social organization

Temporal division of labor and foraging specialization are key characteristics of honeybee social organization. Worker honeybees (Apis mellifera) initiate foraging for food around their third week of life and often specialize in collecting pollen or nectar before they die. Variation in these fundamental social traits correlates with variation in worker reproductive physiology. However, the genetic and hormonal mechanisms that mediate the control of social organization are not understood and remain a central question in social insect biology. Here we demonstrate that a yolk precursor gene, vitellogenin, affects a complex suite of social traits. Vitellogenin is a major reproductive protein in insects in general and a proposed endocrine factor in honeybees. We show by use of RNA interference (RNAi) that vitellogenin gene activity paces onset of foraging behavior, primes bees for specialized foraging tasks, and influences worker longevity. These findings support the view that the worker specializations that characterize hymenopteran sociality evolved through co-option of reproductive regulatory pathways. Further, they demonstrate for the first time how coordinated control of multiple social life-history traits can originate via the pleiotropic effects of a single gene that affects multiple physiological processes.     

The Gene vitellogenin Has Multiple Coordinating Effects on Social Organization

Temporal division of labor and foraging specialization are key characteristics of honeybee social organization. Worker honeybees (Apis mellifera) initiate foraging for food around their third week of life and often specialize in collecting pollen or nectar before they die. Variation in these fundamental social traits correlates with variation in worker reproductive physiology. However, the genetic and hormonal mechanisms that mediate the control of social organization are not understood and remain a central question in social insect biology. Here we demonstrate that a yolk precursor gene, vitellogenin, affects a complex suite of social traits. Vitellogenin is a major reproductive protein in insects in general and a proposed endocrine factor in honeybees. We show by use of RNA interference (RNAi) that vitellogenin gene activity paces onset of foraging behavior, primes bees for specialized foraging tasks, and influences worker longevity. These findings support the view that the worker specializations that characterize hymenopteran sociality evolved through co-option of reproductive regulatory pathways. Further, they demonstrate for the first time how coordinated control of multiple social life-history traits can originate via the pleiotropic effects of a single gene that affects multiple physiological processes.     

Higher vitellogenin concentrations in honey bee workers may be an adaptation to life in temperate climates

The honey bee originated in tropical Africa and later dispersed to northern Europe. It has been suggested that a higher hemolymph storage capacity for the glycolipoprotein vitellogenin evolved in temperate regions, and that the trait constitutes an adaptation to a strongly seasonal environment. We have investigated whether the relative vitellogenin levels of European and African honey bees are in accordance with this hypothesis. Our data indicate that European workers have a higher set-point concentration for vitellogenin compared to their African origin. Considered together with available life history information and physiological data, the results lend support to the view that “winter bees”, a longlived honey bee worker caste that survives winter in temperate regions, evolved through an increase in the worker bees’ capacity for vitellogenin accumulation. Received 20 September 2004; revised 25 March 2005; accepted 13 April 2005.     

Social learning of floral odours inside the honeybee hive

A honeybee hive serves as an information centre in which communication among bees allows the colony to exploit the most profitable resources in a continuously changing environment. The best-studied communication behaviour in this context is the waggle dance performed by returning foragers, which encodes information about the distance and direction to the food source. It has been suggested that another information cue, floral scents transferred within the hive, is also important for recruitment to food sources, as bee recruits are more strongly attracted to odours previously brought back by foragers in both honeybees and bumble-bees. These observations suggested that honeybees learn the odour from successful foragers before leaving the hive. However, this has never been shown directly and the mechanisms and properties of the learning process remain obscure. We tested the learning and memory of recruited bees in the laboratory using the proboscis extension response (PER) paradigm, and show that recruits indeed learn the nectar odours brought back by foragers by associative learning and retrieve this memory in the PER paradigm. The associative nature of this learning reveals that information was gained during mouth-to-mouth contacts among bees (trophallaxis). Results further suggest that the information is transferred to long-term memory. Associative learning of food odours in a social context may help recruits to find a particular food source faster.     

蜜蜂卵黄原蛋白的作用

卵黄蛋白不仅为胚胎发生提供营养物质,它在生物体内还具有其他的生物学功能。昆虫卵黄蛋白是昆虫卵内的营养储备,它的前体主要来源于脂肪体的雌性特异血蛋白——卵黄原蛋白(Vg),它是近年来昆虫生理学和生化学最活跃的领域之一,文章介绍蜜蜂卵黄原蛋白在蜜蜂生殖过程中的作用,以及与蜜蜂社会性生活及寿命的关系。     

Diurnal and Seasonal Changes in Thermal Preference of Single,Isolated Bees and Small Groups of Bees (Apis mellifera L.)

The aim of the present study was: to compare thermoregulatory behaviour of single honeybee workers and groups of 3–15 bees over their annual activity period and to check out whether the annual fluctuations of ambient temperature selection are correlated with phases of the colony development. Thermal behaviour of both single workers and groups of bees was recorded, using a video camera, in a thermal gradient system. Thermal preferences of the insects were tested seasonally in spring (May/June), summer (July/August) and autumn (September–November). Both single bees and small groups of bees changed their thermal behaviour in daily cycle. The season of the year had distinct effect on temperature preferences of both single honeybee workers or small groups of bees. In single honeybee workers the lowest ambient temperatures were preferred in late spring (the swarming phase) while the highest temperatures were selected during the summer (the colony growing phase). There were significant seasonal changes in ambient temperature selected by groups of honeybee workers. Groups of honeybee workers tended to prefer the lowest temperatures in late spring and the highest temperatures were selected during the summer. The day-night differences exhibited by small groups of bees in our experiments are likely to represent behavioural responses of the honeybee colony. In our experiments we proved an influence of the season of the year on the honeybees’ thermal behaviour, which might be connected with seasonal shifts of temperature regulated by the honeybee colony.     

Occurrence and Significance of Vitellogenins in Female Castes of Social Hymenoptera

A female specific protein is found in queens, workers, and gvnandromorphsof several species of social Hymenoptera. Possibly it is presentalso in experimentally produced diploid males, but it couldnot be found in normal haploid drones. A high tiler of the femalespecific protein (vitellogenin) is found in the hemolymph ofhoneybee queens during periods of oviposition and even duringperiods when no eggs are laid. A high titer is also observedin egg-laying workers of the honeybee and the stingless bees.Rates of synthesis of vitellogenin are negatively correlatedwith the concentration in the hemolymph. In nursing workersrates of vitellogenin synthesis are twice as high as in egg-layingworkers. In non-laying workers vitellogenin normally only occurs in thehemolymph of nursing workers; this period of nursing is moreextended in A. florea than in A. mellifica, a fact which maysignal a more primitive level of female caste differentiationin A. florea. Aspects of genetic, endocrine, and social regulationof vitellogenin synthesis are discussed.     

Super and half-sister discrimination by honey bee workers (Apis mellifera L.) in a trophallactic bioassay

Summary Kin recognition and nepotism between honeybee workers (Apis mellifera L.) was analysed in a trophallactic bio-assay. Donor workers were fed dyed sugar syrup and introduced into a recipient group consisting of 12 to 15 workers of the same colony. After allowing for 1 hour of trophallaxis, the distribution of the dyed food was analysed with spectrophotometry. The subfamily composition in the recipient group was varied such that the donor bees had to discriminate between workers of 2 to 7 different patrilines. Donor bees preferentially fed super sisters if few patrilines were present in the recipient group. However, preferential feeding was not observed if the recipient group consisted of workers of more than three subfamilies. Since the natural degree of polyandry causes intracolonial genetic variance to exceed the genetic variability in the experiments, nepotistic behaviour among workers may not reveal intranidal subfamily recognition in honeybees.     

Detection and Identification of a Novel Lactic Acid Bacterial Flora Within the Honey Stomach of the Honeybee Apis mellifera

This investigation concerned the question of whether honeybees collect bacteria that are beneficial for humans from the flowers that contribute to formation of their honey. Bacteria originating from the types of flowers involved, and found in different anatomic parts of the bees, in larvae, and in honey of different types, were sampled during a 2-year period. 16S rRNA sequencing of isolates and clones was employed. A novel bacterial flora composed of lactic acid bacteria (LAB) of the genera Lactobacillus and Bifidobacterium, which originated in the honey stomach of the honeybee, was discovered. It varied with the sources of nectar and the presence of other bacterial genera within the honeybee and ended up eventually in the honey. It appeared that honeybees and the novel LAB flora may have evolved in mutual dependence on one another. It was suggested that honey be considered a fermented food product because of the LAB involved in honey production. The findings are seen as having clear implications for future research in the area, as providing a better understanding the health of honeybees and of their production and storage of honey, and as having clear relevance for future honeybee and human probiotics.     

The curious case of aging plasticity in honey bees

As in all advanced insect societies, colony-organization in honey bees emerges through a structured division of labor between essentially sterile helpers called workers. Worker bees are sisters that conduct all social tasks except for egg-laying, for example nursing brood and foraging for food. Curiously, aging progresses slowly in workers that engage in nursing and even slower when bees postpone nursing during unfavorable periods. We, therefore, seek to understand how senescence can emerge as a function of social task performance. The alternative utilization of a common yolk precursor protein (vitellogenin) in nursing and somatic maintenance can link behavior and aging plasticity in worker bees. Beneficial effects of vitellogenin may also be mediated by inhibitory action on juvenile hormone and insulin-like signaling.     

Impact of introduced honeybees, Apis mellifera, upon native bee communities in the Bonin (Ogasawara) Islands

The Bonin (Ogasawara) Islands are oceanic islands located in the northwest Pacific, and have ten native (nine endemic) bee species, all of which are nonsocial. The European honeybee (Apis mellifera), which was introduced to the islands for apiculture in the 1880s, became naturalized in a few islands shortly after introduction. To detect the impact of the honeybees upon native bee diversity, we analyzed pollen harvest by honeybees and surveyed the relative abundance of honeybees and native bees on flowers on several islands. Both hived and feral honeybee colonies were active throughout the year, harvesting pollen of both native and alien flowers and from both entomophilous and anemophilous flowers. Honeybees strongly depended on the alien plants, especially during winter to spring when native melittophilous flowers were rare. From June to November, honeybees exhaustively utilized native flowers, which had originally been utilized and pollinated by native bees. On Chichi and Haha Islands, where human disturbance of forests has been severe, both native and alien flowers were dominated by honeybees, and native bees were rare or extinct even in well-conserved forests. In contrast, on Ani Island and Haha's satellite islands where primary forests were well conserved and honeybees were still uncommon or absent, native bees remained dominant. These results suggest that competition for nectar and pollen of the native flowers between honeybees and native bees favors honeybees on the disturbed islands, which are thoroughly invaded by alien nectariferous, sometimes aggressive, weedy plants. Received: May 8, 1998 / Accepted: May 6, 1999     

Physiological state influences the social interactions of two honeybee nest mates

Physiological state profoundly influences the expression of the behaviour of individuals and can affect social interactions between animals. How physiological state influences food sharing and social behaviour in social insects is poorly understood. Here, we examined the social interactions and food sharing behaviour of honeybees with the aim of developing the honeybee as a model for understanding how an individual's state influences its social interactions. The state of individual honeybees was manipulated by either starving donor bees or feeding them sucrose or low doses of ethanol to examine how a change in hunger or inebriation state affected the social behaviours exhibited by two closely-related nestmates. Using a lab-based assay for measuring individual motor behaviour and social behaviour, we found that behaviours such as antennation, willingness to engage in trophallaxis, and mandible opening were affected by both hunger and ethanol intoxication. Inebriated bees were more likely to exhibit mandible opening, which may represent a form of aggression, than bees fed sucrose alone. However, intoxicated bees were as willing to engage in trophallaxis as the sucrose-fed bees. The effects of ethanol on social behaviors were dose-dependent, with higher doses of ethanol producing larger effects on behaviour. Hungry donor bees, on the other hand, were more likely to engage in begging for food and less likely to antennate and to display mandible opening. We also found that when nestmates received food from donors previously fed ethanol, they began to display evidence of inebriation, indicating that ethanol can be retained in the crop for several hours and that it can be transferred between honeybee nestmates during trophallaxis.     

Changes in weight of the pharyngeal gland and haemolymph titres of juvenile hormone,protein and vitellogenin in worker honey bees

Four physiological parameters (haemolymph-juvenile hormone titre, protein concentration, vitellogenin concentration, and pharyngeal gland dry weight) were examined in the following categories of queenright adult worker bees: summer bees 1–40 days old, winter bees 80–130 days old, 12–100-day old bees at the beginning of winter, 100–195-day old bees at the end of winter, and 1–100-day old bees experimentally induced to live longer in summer.In contrast to the continuously increasing titre of juvenile hormone in ageing summer bees, winter bees kept a constant low level. In bees at the beginning of winter, the hormone titre never reached high values. However, at the end of winter it rose from a low to a high level, comparable with the high titre of 24–40-day old summer bees. In experimentally induced longlived bees in summer, the juvenile hormone titre did not increase as in normal summer bees but remained low as in bees at the beginning of winter. Among the known natural juvenile hormones, only juvenile hormone III was present in the haemolymph of winter bees.The results support the hypothesis of polyphenism being regulated by the titre of juvenile hormone in the haemolymph.     

Altered physiology in worker honey bees (Hymenoptera: Apidae) infested with the mite Varroa destructor (Acari: Varroidae): a factor in colony loss during overwintering?

The ectoparasitic mite Varroa destructor (Anderson & Trueman) is the most destructive pest of the honey bee, Apis mellifera L., in Europe and the United States. In temperate zones, the main losses of colonies from the mites occur during colony overwintering. To obtain a deeper knowledge of this phenomenon, we studied the mites' impact on the vitellogenin titer, the total protein stores in the hemolymph, the hemocyte characteristics, and the ecdysteroid titer of adult honey bees. These physiological characteristics are indicators of long-time survival and endocrine function, and we show that they change if bees have been infested by mites during the pupal stage. Compared with noninfested workers, adult bees infested as pupae do not fully develop physiological features typical of long-lived wintering bees. Management procedures designed to kill V. destructor in late autumn may thus fail to prevent losses of colonies because many of the adult bees are no longer able to survive until spring. Beekeepers in temperate climates should therefore combine late autumn management strategies with treatment protocols that keep the mite population at low levels before and during the period when the winter bees emerge.     

Past Experiences Affect Interaction Patterns Among Foragers and Hive-Mates in Honeybees

Social insect colonies face the challenge of adjusting the behavior of individuals performing various tasks to a changing environment. It has been shown in several species that characteristics of interaction patterns between nestmates provide social information that allows individuals to adjust their behavior in adaptive ways. A well-studied example is the modulation of recruitment by dancing in honeybees ( Apis mellifera ) in response to the time, the foragers have to search for unloading partners and the number of unloading bees. Here we tested if experiences that hive bees acquired during past social interactions affect interactions with the incoming foragers. Bees returning with food containing a floral scent that was familiar to the hive bees from previous interactions had more food receivers during unloading and more followers during dancing displays compared with foragers returning with food containing a novel scent or unscented food. We also confirm that the number of receivers during food unloading is positively related to the motivation to dance immediately after unloading. Our results show that prior social experiences affect the ways in which individuals interact in the context of honeybee nectar collection and, therefore, how learning in hive bees contributes to the organization of this collective task.     

Nurse bees support the physiological development of young bees (Apis mellifera L.)

Newly emerged worker honeybees (focal bees) were caged individually for 8 days either isolated or together with one companion bee of known age (2–30 days) taken from a colony. The companion bee was replaced every 2nd day. After 8 days, various parameters were investigated in the focal bees as indicators of the level of development. Focal bees which had been caged with 6-day-old companion bees were better developed than isolated focal bees, newly emerged bees, or focal bees caged with almost all other ages of companion bees. They had hypopharyngeal glands that were larger and contained more protein, their thoraces had a higher protein content, and they had a higher rate of proteolytic activity in the midgut. Although the focal bees were supplied with pollen as well as honey, they consumed only small amounts of pollen. We attribute their better development to their having been fed worker jelly by the accompanying companion bees. The 6-day-old companion bees consumed high quantities of pollen and spent more time (18.7 ± 11.85 s/h) feeding focal bees than 12-day-old bees (6.5 ± 4.09 s/h) or foragers (no feeding of focal bees). The results show that even under such artificial conditions, the exchange of food (trophallaxis) promotes the development of young honeybee workers. Accepted: 26 February 1999