Insulin-like hypoglycemic and immunological activities in honeybee royal jelly

An aqueous extract of royal jelly from Apis mellifera produced hypoglycemia when injected into larvae of Manduca sexta. Application of specific radioimmunoassay to the partially-purified extract showed that royal jelly contains several insulin-like peptides, the major immunoreactive component of which has an apparent mol. wt similar to that of bovine insulin. These results suggest the existence of a peptide in the honeybee having both biological and structural similarities to vertebrate insulin.     

Antiapoptotic role of major royal jelly protein 8 of honeybee (Apis mellifera) venom

The dominant protein components of honeybee royal jelly (RJ) are major royal jelly proteins (MRJPs), which exhibit various biological properties. However, the biological basis of why bee venom contains MRJPs and what role MRJPs play in bee venom remains to be elucidated. This study reports the antiapoptotic role of MRJP 8 of Apis mellifera venom (AmMRJP 8) in melittin-treated mammalian cells. Recombinant AmMRJP 8 reduced caspase-3 activity and melittin-induced cell apoptosis. Additionally, recombinant AmMRJP 8 decreased the production levels of H₂O₂ and proinflammatory molecules. These results indicate that MRJP in bee venom plays a role in cell protection in bee venom-induced inflammatory responses.     

Transcriptome differences in the hypopharyngeal gland between Western Honeybees (Apis mellifera) and Eastern Honeybees (Apis cerana)

Background

Apis mellifera and Apis cerana are two sibling species of Apidae. Apis cerana is adept at collecting sporadic nectar in mountain and forest region and exhibits stiffer hardiness and acarid resistance as a result of natural selection, whereas Apis mellifera has the advantage of producing royal jelly. To identify differentially expressed genes (DEGs) that affect the development of hypopharyngeal gland (HG) and/or the secretion of royal jelly between these two honeybee species, we performed a digital gene expression (DGE) analysis of the HGs of these two species at three developmental stages (newly emerged worker, nurse and forager).

Results

Twelve DGE-tag libraries were constructed and sequenced using the total RNA extracted from the HGs of newly emerged workers, nurses, and foragers of Apis mellifera and Apis cerana. Finally, a total of 1482 genes in Apis mellifera and 1313 in Apis cerana were found to exhibit an expression difference among the three developmental stages. A total of 1417 DEGs were identified between these two species. Of these, 623, 1072, and 462 genes showed an expression difference at the newly emerged worker, nurse, and forager stages, respectively. The nurse stage exhibited the highest number of DEGs between these two species and most of these were found to be up-regulated in Apis mellifera. These results suggest that the higher yield of royal jelly in Apis mellifera may be due to the higher expression level of these DEGs.

Conclusions

In this study, we investigated the DEGs between the HGs of two sibling honeybee species (Apis mellifera and Apis cerana). Our results indicated that the gene expression difference was associated with the difference in the royal jelly yield between these two species. These results provide an important clue for clarifying the mechanisms underlying hypopharyngeal gland development and the production of royal jelly.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-744) contains supplementary material, which is available to authorized users.     

Origin and function of the major royal jelly proteins of the honeybee (Apis mellifera) as members of the yellow gene family

In the honeybee, Apis mellifera, the queen larvae are fed with a diet exclusively composed of royal jelly (RJ), a secretion of the hypopharyngeal gland of young worker bees that nurse the brood. Up to 15% of RJ is composed of proteins, the nine most abundant of which have been termed major royal jelly proteins (MRJPs). Although it is widely accepted that RJ somehow determines the fate of a female larva and in spite of considerable research efforts, there are surprisingly few studies that address the biochemical characterisation and functions of these MRJPs. Here we review the research on MRJPs not only in honeybees but in hymenopteran insects in general and provide metadata analyses on genome organisation of mrjp genes, corroborating previous reports that MRJPs have important functions for insect development and not just a nutritional value for developing honeybee larvae.     

Antimicrobial activity of major royal jelly protein 8 and 9 of honeybee (Apis mellifera) venom

Honeybee venom is a complex mixture of toxic components, including major royal jelly protein (MRJP) 8 and 9. MRJP 8 and MRJP 9 are allergens, and MRJP 8 reduces melittin-induced cell apoptosis. However, their functional roles are poorly understood, and their antimicrobial activities have not been determined. In this study, the antimicrobial role of MRJP 8 and MRJP 9 of honeybee (Apis mellifera) venom (AmMRJP 8 and AmMRJP 9) was demonstrated. The presence of AmMRJP 8 and AmMRJP 9 in the secreted venom was observed using antibodies against recombinant AmMRJP 8 and AmMRJP 9 produced in baculovirus-infected insect cells. Recombinant AmMRJP 8 and AmMRJP 9 exhibited an inhibitory activity against microbial serine proteases. Consistent with their inhibitory activity, they induced structural damage by binding to microbial surfaces, resulting in a broad-spectrum antimicrobial activity against bacteria and fungi. They had little effect on hemolysis. Therefore, AmMRJP 8 and AmMRJP 9 could function as antimicrobial agents in honeybee venom.     

Antioxidant capacity of major royal jelly proteins of honeybee (Apis mellifera) royal jelly

Major royal jelly proteins (MRJPs) of honeybee royal jelly (RJ) exhibit antimicrobial and antioxidant activities. Although MRJPs of Apis mellifera RJ (AmMRJPs) responsible for antibacterial activity have been identified, AmMRJPs with antioxidant effects remain to be elucidated. Here we identified and compared the antioxidant activities of purified recombinant AmMRJPs 1–7, which are expressed in baculovirus-infected insect cells. Antioxidant assays of recombinant AmMRJPs 1–7 against H₂O₂ revealed that AmMRJPs reduce caspase-3 activity and oxidative stress-induced cell apoptosis and lead to increased cell viability. Consistent with these results, AmMRJPs 1–7 exhibit 1,1-diphenyl-2-picrylhydrazyl radical-scavenging activity and protect against oxidative DNA damage. These results indicate that AmMRJPs play a role as antioxidants in A. mellifera RJ.     

Antibacterial activity of major royal jelly proteins of the honeybee (Apis mellifera) royal jelly

Major royal jelly proteins (MRJPs) are the protein components in royal jelly (RJ). MRJPs 1–7 are detected in the honeybee Apis mellifera RJ. Although A. mellifera MRJP (AmMRJP) 2 exhibited antibacterial activity, the other MRJPs with antimicrobial activities in A. mellifera RJ remains largely unknown. Here, we compared the antibacterial activity of recombinant AmMRJPs 1–7 expressed in baculovirus-infected insect cells. Antibacterial assays of recombinant AmMRJPs 1–7 against the gram-negative bacterium Escherichia coli revealed that AmMRJPs 2–5 and 7 exhibited antibacterial activity, whereas AmMRJPs 1 and 6 displayed almost no antibacterial activity. Consistent with the antibacterial activity of AmMRJPs, AmMRJPs 2–5 and 7 are bound to bacterial cell walls. These results indicated that AmMRJPs 2–5 and 7 contribute directly to the antibacterial property of RJ, suggesting that MRJPs play a role in the antimicrobial property of RJ.     

Comparing the secretory pathway in honeybee venom and hypopharyngeal glands

We provide insights into the secretory pathway of arthropod gland systems by comparing the royal jelly-producing hypopharyngeal glands and the venom-producing glands of the honeybee, Apis mellifera. These glands have different functions and different product release characteristics, but both belong to the class 3 types of insect glands, each being composed of two cells, a secretory cell and a microduct-forming cell. The hypopharyngeal secretory cells possess an extremely elongate tubular invagination that is filled with a cuticular structure, the end-apparatus, anchored against the cell membrane by a conspicuous series of actin rings. In contrast, venom glands have no actin rings, but instead have an actin-rich brush border surrounding the comparatively short and narrow end-apparatus. We relate these cytoskeletal differences to the production system and utilisation of secretions; venom is stored in a reservoir whereas royal jelly and enzymes are produced on demand. Fluorescence-based characterisation of the actin cytoskeleton combined with scanning electron microscopy of the end-apparatus allows for detailed characterisation of the point of secretion release in insect class 3 glands.     

Identification of major royal jelly proteins in the brain of the honeybee Apis mellifera

The consumption of royal jelly (RJ) determines the differences between castes and behavioral development in the honeybee Apis mellifera. However, it is not known whether the proteins of RJ are related to these differences, or which proteins are responsible for the changes. To understand the functions of RJ proteins that are present in other tissues of the bee, in addition to hypopharyngeal gland, we used a polyclonal antibody anti-MRJP1 to investigate the presence of this protein in nervous system of honeybee. This study showed the presence of three polypeptides (p57, p70 and p128) in specific tissues of bee brain. Mushroom body, optic lobe and antennal lobe neuropils all contained proteins recognized by anti-MRJP1. Proteomic analysis showed that the three polypeptides are correlated with proteins of the MRJP family. p57 is correlated with MRJP1, p70 with MRJP3, while p128 may be an oligomeric form or a new polypeptide. Immunostaining of the brain and hypopharyngeal gland revealed differential expression of MRJPs in various brain regions and in different honeybee castes and subcastes. The identification and localization of these MRJPs contribute to the elucidation of the biological roles of this protein family.     

More than royal food - <Emphasis Type="Italic">Major royal jelly protein</Emphasis> genes in sexuals and workers of the honeybee <Emphasis Type="Italic">Apis mellifera</Emphasis>

Background

In the honeybee Apis mellifera, female larvae destined to become a queen are fed with royal jelly, a secretion of the hypopharyngeal glands of young nurse bees that rear the brood. The protein moiety of royal jelly comprises mostly major royal jelly proteins (MRJPs) of which the coding genes (mrjp1-9) have been identified on chromosome 11 in the honeybee’s genome.

Results

We determined the expression of mrjp1-9 among the honeybee worker caste (nurses, foragers) and the sexuals (queens (unmated, mated) and drones) in various body parts (head, thorax, abdomen). Specific mrjp expression was not only found in brood rearing nurse bees, but also in foragers and the sexuals.

Conclusions

The expression of mrjp1 to 7 is characteristic for the heads of worker bees, with an elevated expression of mrjp1-4 and 7 in nurse bees compared to foragers. Mrjp5 and 6 were higher in foragers compared to nurses suggesting functions in addition to those of brood food proteins. Furthermore, the expression of mrjp9 was high in the heads, thoraces and abdomen of almost all female bees, suggesting a function irrespective of body section. This completely different expression profile suggests mrjp9 to code for the most ancestral major royal jelly protein of the honeybee.

     

Functional analysis of the honeybee (Apis mellifera L.) salivary system using proteomics

In insects, specific proteins and physiologically active molecules whose functions are related to their lifestyles are secreted from the salivary system. To investigate proteins/molecules related to the sociality of the European honeybee (Apis mellifera L.), we performed a proteomic analysis of the honeybee salivary system. The honeybee salivary system comprises two secretory glands: the postcerebral gland (PcG) and the thoracic gland (TG), both of which are connected to a common duct that opens in the mouthpart. Although most (31 out of 35) of the major proteins identified from the PcG and TG were housekeeping proteins, the spot intensities for aldolase and acetyl-CoA acyltransferase 2 were stronger in the PcG than in the TG in the 2-dimensional gel electrophoresis. Immunoblotting confirmed that the expression of these proteins was stronger in the PcG than in the TG, whereas expression was almost not detectable in the hypopharyngeal gland (HpG), suggesting that carbohydrate metabolism is enhanced in the honeybee PcG. In addition, imaginal disc growth factor 4 (IDGF4) was synthesized in the honeybee salivary system. Immunoblotting indicated IDGF4 expression was very strong in the PcG, moderate in the TG, and very weak in the HpG. A considerable amount of IDGF4 was detected in the royal jelly, while less was detected in honey, strongly suggesting that the honeybee salivary system secretes IDGF4 into the royal jelly and honey. The secreted IDGF4 might therefore affect growth and physiology of the other colony members.     

王浆主蛋白MRJP7基因在意大利蜜蜂体内的表达

王浆蛋白是蜂王浆生物功能的物质基础,是由王浆蛋白基因家族(mrjps)编码合成的。但部分家族成员如MRJP7在王浆中的含量极少甚至检测不到。基因功能与其在生物体内的时空表达特性相关,为探究mrjp7的生物学功能,本研究利用荧光定量PCR技术对mrjp7在不同发育时期的工蜂和成年工蜂、雄蜂和蜂王的不同组织部位的表达进行定量检测。结果显示mrjp7在成年雄蜂体内的表达水平最低,成年蜂王次之,且在它们的各不同组织部位之间的表达量差异较小。该基因在工蜂幼虫和蛹期的表达同样较低,但在羽化后9日龄前后的哺育蜂王浆腺和头部特异性高表达,这与哺育蜂分泌蜂王浆哺育幼虫和蜂王的功能是相适应的,该结果在转录水平上证实了mrjp7的营养功能,为进一步的研究和应用打下了理论基础。     

Effect of juvenile hormone treatment on caste differentiation in the honeybee, Apis mellifera

Synthetic juvenile hormone (methyl trans,trans,cis-10-epoxy-7-ethyl-3,11-dimethyl-2,6-tridecadienoate, 1 μg/μl acetone per animal) (JH) was topically applied to 2- to 3-day-old worker honeybee larvae in the hive. Eighty per cent of the hormone-treated larvae were removed from their brood cell before pupation. Only 1 out of 42 adults showed characteristics of an intercaste. Fifty per cent of the control larvae (1 μl acetone) developed to adults, all of which were workers.After topical application of JH and feeding on royal jelly under in vitro conditions, the rate of survival is high (up to 85 per cent adults), but up to 67 per cent of queens and 44 per cent of workers exhibit eye malformations with characteristics of somatic mutation. Formation of a more solid web by the spinning larvae, shortening of the diapause by 1 to 2 days, and unusual shapes of mandibles, legs, and abdomen are a consequence of hormone treatment. The effects are less marked after application of 0·1 instead of 1 μg hormone or after its addition to the food (2 μg/g royal jelly). Treatment of the 2- to 3-day-old worker larvae and subsequent rearing on royal jelly is followed by a shift in caste differentiation from queens and workers to intercastes. In no case, are more queens developed after juvenile hormone treatment.Queen bee determinator, partially purified from royal jelly, induces a concentration-dependent shift from workers to queen differentiation. A threefold increase in the natural determinator concentration of royal jelly results in an almost exclusive (98 per cent) queen formation from 2- to 3-day-old worker larvae. In contrast to this direct effect, the influence of JH is explained as an indirect morphogenetic effect not directly coupled with honeybee caste differentiation.     

Vitellogenins Are New High Molecular Weight Components and Allergens (Api m 12 and Ves v 6) of Apis mellifera and Vespula vulgaris Venom

Background/Objectives

Anaphylaxis due to hymenoptera stings is one of the most severe clinical outcomes of IgE-mediated hypersensitivity reactions. Although allergic reactions to hymenoptera stings are often considered as a general model for the underlying principles of allergic disease, venom immunotherapy is still hampered by severe systemic side effects and incomplete protection. The identification and detailed characterization of all allergens of hymenoptera venoms might result in an improvement in this field and promote the detailed understanding of the allergological mechanism. Our aim was the identification and detailed immunochemical and allergological characterization of the low abundant IgE-reactive 200 kDa proteins of Apis mellifera and Vespula vulgaris venom.

Methods/Principal Findings

Tandem mass spectrometry-based sequencing of a 200 kDa venom protein yielded peptides that could be assigned to honeybee vitellogenin. The coding regions of the honeybee protein as well as of the homologue from yellow jacket venom were cloned from venom gland cDNA. The newly identified 200 kDa proteins share a sequence identity on protein level of 40% and belong to the family of vitellogenins, present in all oviparous animals, and are the first vitellogenins identified as components of venom. Both vitellogenins could be recombinantly produced as soluble proteins in insect cells and assessed for their specific IgE reactivity. The particular vitellogenins were recognized by approximately 40% of sera of venom-allergic patients even in the absence of cross-reactive carbohydrate determinants.

Conclusion

With the vitellogenins of Apis mellifera and Vespula vulgaris venom a new homologous pair of venom allergens was identified and becomes available for future applications. Due to their allergenic properties the honeybee and the yellow jacket venom vitellogenin were designated as allergens Api m 12 and Ves v 6, respectively.     

Infections of Nosema ceranae in four different honeybee species

The microsporidium Nosema ceranae is detected in honeybees in Thailand for the first time. This endoparasite has recently been reported to infect most Apis mellifera honeybee colonies in Europe, the US, and parts of Asia, and is suspected to have displaced the endemic endoparasite species, Nosema apis, from the western A. mellifera. We collected and identified species of microsporidia from the European honeybee (A. mellifera), the cavity nesting Asian honeybee (Apis cerana), the dwarf Asian honeybee (Apis florea) and the giant Asian honeybee (Apis dorsata) from colonies in Northern Thailand. We used multiplex PCR technique with two pairs of primers to differentiate N. ceranae from N. apis. From 80 A. mellifera samples, 62 (77.5%) were positively identified for the presence of the N. ceranae. Amongst 46 feral colonies of Asian honeybees (A. cerana, A. florea and A. dorsata) examined for Nosema infections, only N. ceranae could be detected. No N. apis was found in our samples. N. ceranae is found to be the only microsporidium infesting honeybees in Thailand. Moreover, we found the frequencies of N. ceranae infection in native bees to be less than that of A. mellifera.     

Diet and cell size both affect queen-worker differentiation through DNA methylation in honey bees (Apis mellifera, Apidae)

Background

Young larvae of the honey bee (Apis mellifera) are totipotent; they can become either queens (reproductives) or workers (largely sterile helpers). DNA methylation has been shown to play an important role in this differentiation. In this study, we examine the contributions of diet and cell size to caste differentiation.

Methodology/Principal Findings

We measured the activity and gene expression of one key enzyme involved in methylation, Dnmt3; the rates of methylation in the gene dynactin p62; as well as morphological characteristics of adult bees developed either from larvae fed with worker jelly or royal jelly; and larvae raised in either queen or worker cells. We show that both diet type and cell size contributed to the queen-worker differentiation, and that the two factors affected different methylation sites inside the same gene dynactin p62.

Conclusions/Significance

We confirm previous findings that Dnmt3 plays a critical role in honey bee caste differentiation. Further, we show for the first time that cell size also plays a role in influencing larval development when diet is kept the same.     

Varroa destructor changes its cuticular hydrocarbons to mimic new hosts

Varroa destructor (Vd) is a honeybee ectoparasite. Its original host is the Asian honeybee, Apis cerana, but it has also become a severe, global threat to the European honeybee, Apis mellifera. Previous studies have shown that Varroa can mimic a host''s cuticular hydrocarbons (HC), enabling the parasite to escape the hygienic behaviour of the host honeybees. By transferring mites between the two honeybee species, we further demonstrate that Vd is able to mimic the cuticular HC of a novel host species when artificially transferred to this new host. Mites originally from A. cerana are more efficient than mites from A. mellifera in mimicking HC of both A. cerana and A. mellifera. This remarkable adaptability may explain their relatively recent host-shift from A. cerana to A. mellifera.     

The chemical basis of honeybee, Apis mellifera, caste formation. Partial purification of queen bee determinator from royal jelly

On royal jelly, 1- to 2-day-old honeybee worker larvae have been reared in vitro to adults in a yield of 67±18 per cent. Up to 100 per cent and, on an average, 60 per cent of them were queens and intercaster. The preparation of a basic food from royal jelly by extensive alcohol extraction is described. With this control food, a survival rate of 47±18 per cent was achieved; 15 per cent of the adults were determined, 4·3 per cent of them were queens. Rearing of 1- to 2-day-old worker larvae on a basic food, to which unknown fractions may be added, was used as a biological test for the partial purification of queen bee determinator from royal jelly. By chromatography of the ethanol extract, previously treated with charcoal, on the cation exchanger Dowex 50 WX4 and rechromatography on silica gel, a 10⁵-fold purification of determinator was achieved. Chemical properties of the highly hydrophilic, low molecular active fraction are described.