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.     

Towards posttranslational modification proteome of royal jelly

Royal jelly (RJ) is a secretory protein from the hypopharyngeal glands of nurse honeybee workers, which contains a variety of proteins of which major royal jelly proteins (MRJPs) are some of the most important. It plays important roles both for honeybee and human. Each family of MRJP 1-5 displays a string of modified protein spots in the RJ proteome profile, which may be caused by posttranslational modifications (PTMs) of MRJPs. However, information on the RJ PTMs is still limited. Therefore, the PTM status of RJ was identified by using complementary proteome strategies of two-dimensional gel electrophoresis (2-DE), shotgun analysis in combination with high performance liquid chromatography-chip/electrospray ionization quadrupole time-of-flight/tandem mass spectrometry and bioinformatics. Phosphorylation was characterized in MRJP 1, MRJP 2 and apolipophorin-III-like protein for the first time and a new site was localized in venom protein 2 precursor. Methylation and deamidation were also identified in most of the MRJPs. The results indicate that methylation is the most important PTM of MRJPs that triggers the polymorphism of MRJP 1-5 in the RJ proteome. Our data provide a comprehensive catalog of several important PTMs in RJ and add valuable information towards assessing both the biological roles of these PTMs and deciphering the mechanisms underlying the beneficial effects of RJ for human health.     

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.     

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.     

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.     

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.     

Molecular and biochemical characterization of the major royal jelly protein in bumblebees suggest a non-nutritive function

Honeybee queens are generated on purpose by extensive feeding with a glandular secretion termed royal jelly. Major royal jelly proteins (MRJPs) are the dominant proteinaceous component of royal jelly. One of them, MRJP1, was found to play a central role in honeybee queen development. Genes encoding MRJPs were reported to originate from a single originator, and several of them have evolved nutritive function. Phylogenetic analysis provides evidence that the same originator has multiplied independently in Nasonia and ant lineages. Here we show that bumblebees represent a transition species preserving a single-copy pre-multiplication stage of MRJP evolution. By exploring the single-copy BtRJPL gene, we found striking similarities with MRJPs of the honeybee such as gene structure and expression regulation. At the same time it turned out that BtRJPL does not fulfill criteria for functioning as a nutritive protein. Instead we found evidence that BtRJPL is involved in food digestion or modification, which appears to be the original MRJP function, at least in this lineage. Thus, the evolutionary pattern of MRJPs in hymenopterans constitutes an excellent example of a functional diversification combined with the origin of new properties followed by intensive gene duplication events.     

The MRJP/YELLOW protein family of Apis mellifera: identification of new members in the EST library

Major royal jelly proteins (named MRJP1-5) of honeybee (Apis mellifera), yellow proteins of Drosophila, together with putative proteins found in several bacteria, form a protein family termed the MRJP/yellow family. Members of the family exert diverse physiological functions and amongst eukaryotes appear to be restricted to the order Insecta. MRJPs constitute about 90% of total protein of royal jelly, which is secreted by nurse bees to feed the queen and growing larvae. We looked for mrjp and yellow homologues in a honeybee brain expressed sequence tags (EST) library. In addition to the five mrjp cDNAs previously characterized, we found three additional cDNAs encoding novel MRJPs and importantly, two cDNAs coding for orthologues of Drosophila yellow proteins. One yellow cDNA and all three cDNAs coding for the novel MRJPs were assembled completely, the sequence of the other yellow homologue was partially assembled. The data we present here supports the view that repeated duplications and functional divergence occurred during the evolution of MRJPs in honeybees, with even closely related MRJPs appearing to perform diverse physiological functions. Conversely, yellow protein orthologues appear to be conserved and thus candidates for maintaining the former function(s) of yellow proteins.     

蜂王浆主蛋白研究进展

作为社会性昆虫,蜜蜂是研究社会行为和学习记忆的理想模式生物。王浆主蛋白（Major royal jelly protein, MRJP）是蜂王浆中蛋白质的主要成分,该家族一共有9个成员,MRJP1~MRJP9。所有mrjps均以串联排列的形式位于蜜蜂11号染色体上一个大约60 kb的DNA片段上。mrjp的同源体也存在于其他的膜翅目昆虫,均是通过yellow进化而来的。随着不断地进化,MRJPs家族进化出许多重要功能,其中最主要的就是营养功能。本文从MRJPs家族的基因及蛋白质结构、mRNA表达情况、进化和功能等方面进行综述,为今后开展相关研究提供理论支持。     

Towards functional proteomics of minority component of honeybee royal jelly: The effect of post‐translational modifications on the antimicrobial activity of apalbumin2

This study illustrates multifunctionality of proteins of honeybee royal jelly (RJ) and how their neofunctionalization result from various PTMs of maternal proteins. Major proteins of RJ, designated as apalbumins belong to a protein family consisting of nine members with M_r of 49–87 kDa and they are accompanied by high number of minority homologs derived from maternal apalbumins. In spite of many data on diversity of apalbumins, the molecular study of their individual minority homologous is still missing. This work is a contribution to functional proteomics of second most abundant protein of RJ apalbumin2 (M_r 52.7 kDa). We have purified a minority protein from RJ; named as apalbumin2a, differ from apalbumin2 in M_r (48.6 kDa), in N‐terminal amino acids sequences – ENSPRN and in N‐linked glycans. Characterization of apalbumin2a by LC‐MALDI TOF/TOF MS revealed that it is a minority homolog of the major basic royal jelly protein, apalbumin2, carrying two fully occupied N‐glycosylation sites, one with high‐mannose structure, HexNAc2Hex9, and another carrying complex type antennary structures, HexNAc4Hex3 and HexNAc5Hex4. We have found that apalbumin2a inhibit growth of Paenibacillus larvae. The obtained data call attention to functional plasticity of RJ proteins with potential impact on functional proteomics in medicine.     

Selection and Methionine Accumulation in the Fat Body Protein 2 Gene (FBP2), a Duplicate of the Drosophila Alcohol Dehydrogenase (ADH) Gene

The Drosophila fat body protein 2 gene (Fbp2) is an ancient duplication of the alcohol dehydrogenase gene (Adh) which encodes a protein that differs substantially from ADH in its methionine content. In D. melanogaster, there is one methionine in ADH, while there are 51 (20% of all amino acids) in FBP2. Methionine is involved in 46% of amino acid replacements when Fbp2 DNA sequences are compared between D. melanogaster and D. pseudoobscura. Methionine accumulation does not affect conserved residues of the ADH-ADH^r-FBP2 multigene family. The multigene family has evolved by replacement of mildly hydrophobic amino acids by methionine with no apparent reversion. Its short-term evolution was compared between two Drosophila species, while its long-term evolution was compared between two genera belonging respectively to acalyptrate and calyptrate Diptera, Drosophila and Sarcophaga. The pattern of nucleotide substitution was consistent with an independent accumulation of methionines at the Fbp2 locus in each lineage. Under a steady-state model, the rate of methionine accumulation was constant in the lineage leading to Drosophila, and was twice as fast as that in the calyptrate lineage. Substitution rates were consistent with a slight positive selective advantage for each methionine change in about one-half of amino acid sites in Drosophila. This shows that selection can potentially account for a large proportion of amino acid replacements in the molecular evolution of proteins. Received: 12 December 1994 / Accepted: 15 April 1996     

Major royal jelly protein 2 acts as an antimicrobial agent and antioxidant in royal jelly

Royal jelly (RJ) is a well-known functional and medicinal food for human health promotion. Major royal jelly proteins (MRJPs), which are the major protein components in RJ, exhibit antimicrobial activities. However, the identities of the MRJPs of RJ responsible for its antioxidant effects have remained unclear. Here, we report that honeybee (Apis cerana) MRJP 2 (AcMRJP2) acts as an antimicrobial and antioxidant agent in RJ. Using recombinant AcMRJP2, which was produced in baculovirus-infected insect cells, we established the antimicrobial and antioxidant roles of MRJP 2. AcMRJP2 bound to the surfaces of bacteria, fungi, and yeast, which then induced structural damage in the microbial cell walls and led to a broad spectrum of antimicrobial activities. AcMRJP2 protected mammalian and insect cells via the direct shielding of the cell against oxidative stress, which led to reduced levels of caspase-3 activity and oxidative stress-induced cell apoptosis, followed by increased cell viability. Moreover, AcMRJP2 exhibited DNA protection activity against reactive oxygen species (ROS). Our data indicate that AcMRJP2 could play a crucial role as an antimicrobial agent and antioxidant in RJ, suggesting that MRJP 2 is a component responsible for the antimicrobial and antioxidant activities of RJ.     

Cloning and Molecular Characterization of the First Innexin of the Phylum Annelida—Expression of the Gene During Development

A novel member of the innexin family (cv-inx) has been isolated from the annelid polychaete worm Chaetopterus variopedatus using a PCR approach on genomic DNA and sequence analysis on genomic DNA clones. The gene is present in a HindIII-HindIII segment of 2250 bp containing an uninterrupted open reading frame of 1196 bp encoding a protein of 399 amino acids. The predicted protein shows the typical structural features of innexins and consensus sites for phosphorylation. Analyses on genomic DNA demonstrate that cv-inx is a single copy gene with no introns in the coding region, exactly corresponding to the cDNA sequence. The gene expression is regulated during development as shown by Northern blots analyses of the RNA and by immunoreaction with antibodies against the protein at several embryonic stages. The finding of an innexin in the phylum Annelida, outside of the Ecdysozoa clade, and its peculiar gene structure suggest the necessity to reconsider the current hypothesis on the origin and evolution of gap junctional proteins. Received: 15 December 2000 / Accepted: 27 August 2001     

Antimicrobial activity of the C-terminal of the major royal jelly protein 4 in a honeybee (Apis cerana)

The protein component of honeybee royal jelly (RJ) is constituted by major royal jelly proteins (MRJPs). The Asiatic honeybee (Apis cerana) MRJP-4 (AcMRJP4) exhibits antimicrobial activities. In this study, we identified the antimicrobial activity of AcMRJP4-15, which is a hydrophilic peptide with 88 amino acid residues in the C-terminal of AcMRJP4 that contains a high content of Asn and positively charged amino acids. Recombinant AcMRJP4-15, which is expressed as a 15-kDa peptide in baculovirus-infected insect cells, induced structural damage to the cell walls of bacteria, fungi, and yeast. Interestingly, the antimicrobial activity of AcMRJP4-15 was greater than that of AcMRJP4, demonstrating that the antimicrobial activity of AcMRJP4 was due in large part to the C-terminal. Our data suggest that AcMRJP4-15 can function as an effective antimicrobial agent.     

The Antigen Receptor (NCCRP-1) on Catfish and Zebrafish Nonspecific Cytotoxic Cells Belongs to a New Gene Family Characterized by an F-Box-Associated Domain

The catfish nonspecific cytotoxic cell receptor protein (NCCRP-1) provides an important function in target cell recognition and activation of cytotoxicity. This report identifies and characterizes a zebrafish orthologue of the catfish NCCRP-1. The zebrafish NCCRP-1 cDNA contains an open reading frame that encodes a predicted protein of 237 amino acids with a MW of 27 kDa and a pI of 5.5. Sequence similarities comparisons show that the NCCRP-1 receptors from these two phylogenetically distant species share a high degree of identity. These results suggested that NCCRP-1 performs a crucial function in innate immunity in teleosts. Further, a zebrafish 17-mer peptide corresponding to the catfish NCCRP-1 antigen-binding domain inhibited (catfish) cytotoxicity toward conventional tumor target cells (HL-60). These data appeared to indicate that the zebrafish NCCRP-1 protein may function as an antigen recognition molecule and, as such, may participate in innate immunity in teleosts. A homology search of the zebrafish NCCRP-1 protein revealed that it shares a significant level of identity with another group of proteins belonging to an F-box subfamily. These proteins share an F-box domain in the N terminus (not present in NCCRP-1) and an extremely conserved C-terminal region that has been termed the F-box-associated domain (FBA). The FBA is currently of unknown function. A new gene family is proposed in this work, based on similarities in the FBA sequences with the catfish and zebrafish NCCRP-1 peptides. This new gene family includes several F-box domain-containing proteins and a predicted C. elegans protein. Received: 20 June 2001 / Accepted: 31 August 2001     

Proteome comparison of hypopharyngeal gland development between Italian and royal jelly producing worker honeybees (Apis mellifera L.)

The hypopharyngeal gland (HG) of the honeybee (Apis mellifera L.) produces royal jelly (RJ) that is essential to feed and raise broods and queens. A strain of bees (high royal jelly producing bee, RJb) has been selected for its high RJ production, but the mechanisms of its higher yield are not understood. In this study, we compared HG acini size, RJ production, and protein differential expressions between the RJb and nonselected honeybee (Italian bee, ITb) using proteomics in combination with an electron microscopy, Western blot, and quantitative real-time PCR (qRT-PCR). Generally, the HG of both bees showed age-dependent changes in acini sizes and protein expression as worker behaviors changed from brood nursing to nectar ripening, foraging, and storage activities. The electron microscopic analysis revealed that the HG acini diameter of the RJb strain was large and produced 5 times more RJ than the ITb, demonstrating a positive correlation between the yield and HG acini size. In addition, the proteomic analysis showed that RJb significantly upregulated a large group of proteins involved in carbohydrate metabolism and energy production, those involved in protein biosynthesis, development, amino acid metabolism, nucleotide and fatty acid, transporter, protein folding, cytoskeleton, and antioxidation, which coincides with the fact that the HGs of the RJb strain produce more RJ than the ITb strain that is owing to selection pressure. We also observed age-dependent major royal jelly proteins (MRJPs) changing both in form and expressional intensity concurrent with task-switching. In addition to MRJPs, the RJb overexpressed proteins such as enolase and transitional endoplasmic reticulum ATPase, protein biosynthesis, and development proteins compared to the ITb strain to support its large HG growth and RJ secretion. Because of selection pressure, RJb pursued a different strategy of increased RJ production by involving additional proteins compared to its original counterpart ITb. To our knowledge, this morphological and proteomic comparison study on the HG of the two strains of worker honeybees associated with their age-dependent division of labor is the first of its kind. The study provided not only the quantity and quality differences in the HG from the RJb and the ITb, but also addressed the cellular and behavioral biology development question of how the RJb strain can produce RJ more efficiently than its wild type strain (ITb).     

Honeybee (Apis cerana) major royal jelly protein 4 exhibits antimicrobial activity

Major royal jelly proteins (MRJPs) are important protein components of bee royal jelly (RJ) and exhibit various biological and pharmacological activities. The antimicrobial activities of the royalisin and the jelleines contained within MRJP 1 and MRJP 2 in RJ have been elucidated. However, the antimicrobial effects of other MRJPs remain largely unknown. In this study, we demonstrated the antimicrobial activity of the Asiatic honeybee (Apis cerana) MRJP 4 (AcMRJP4). Recombinant AcMRJP4 was expressed as a 63-kDa protein in baculovirus-infected insect cells. We examined the antimicrobial activity of recombinant AcMRJP4 against bacteria, fungi, and yeast. The mechanisms underlying the antimicrobial activity of AcMRJP4 were assessed using western blot analysis, immunofluorescence staining, and scanning electron microscopy. Recombinant AcMRJP4 bound to the cell walls of bacteria, fungi, and yeast and induced structural damage in the microbial cell walls. AcMRJP4 has an antimicrobial role and exhibits a broad spectrum of antimicrobial activities against bacteria, fungi, and yeast. We demonstrated that AcMRJP4 functions as an antimicrobial agent with activity against bacteria, fungi, and yeast. Together, our data identified a novel function of MRJP 4 as an antimicrobial agent.     

Molecular Evolution of Calmodulin and Calmodulin-Like Genes in the Cephalochordate Branchiostoma

Calmodulin is a calcium-binding EF-hand protein that is an activator of many enzymes as well as ion pumps and channels. Due to its multiple targets and its central role in the cell, understanding the evolutionary history of calmodulin genes should provide insights into the origin of genetic complexity in eukaryotes. We have previously isolated and characterized a calmodulin gene from the early-diverging chordate Branchiostoma lanceolatum (CaM1). In this paper, we report the existence of a second calmodulin gene (CaM2) as well as two CaM-like genomic fragments (CaML-2, CaML-3) in B. lanceolatum and a CaM2 and three CaM-like genes (CaML-1, CaML-2, CaML-3) in B. floridae. The CaM-like genes were isolated using low-stringency PCR. Surprisingly, the nucleotide sequences of the B. lanceolatum CaM1 and CaM2 cDNAs differ by 19.3%. Moreover, the CaM2 protein differs at two positions from the amino acid sequence of CaM1; the latter is identical to calmodulins in Drosophila melanogaster, the mollusc Aplysia californica, and the tunicate Halocynthia roretzi. The two B. lanceolatum CaM-like genes are more closely related to the CaM2 than to the CaM1 gene. This relationship is supported by the phylogenetic analyses and the identical exon/intron organization of these three genes, a relationship unique among animal CaM sequences. These data demonstrate the existence of a CaM multigene family in the cephalochordate Branchiostoma, which may have evolved independently from the multigene family in vertebrates. Received: 2 November 1999 / Accepted: 25 April 2000