Long-term non-surgical contraceptive methods for cats, especially community cats, are of global interest for cost-effective and humane reasons. This study aimed to investigate the effectiveness of a gonadotropin-releasing hormone (GnRH)-based vaccine for immunocontraception and to confirm its safety in intact female cats. Recombinant Salmonella typhimurium flagellin fljB (STF2)-GnRH protein was expressed in Escherichia coli. We divided female cats into vehicle control group (n = 4) and two experimental groups (100 μg injection group [n = 7] and 1000 μg injection group [n=7]), and immunized them twice intramuscularly (0.2 mL/cat at zero week and 4 weeks later into the other leg). Breeding trials started on day 120. All control cats (n = 4/4), 71% of the 100 μg injection group (n = 5/7), and 57% of the 1000 μg injection group (n = 4/7) became pregnant within 203 days after the introduction of male cats. The 1000 μg injection group had significantly a longer median time to conception following treatment (166 days) than the control (17 days, p < 0.05). Average litter size was significantly lower in the 1000 μg GnRH-vaccinated cats (2.8 ± 0.7) than in the control cats (4.5 ± 0.5, p < 0.05). Injection site reactions were not observed in any cat. The E. coli-expressed STF2-GnRH vaccine did not provide contraception in a sufficient proportion of the cats. However, it might be effective to suppress fertility through infertility vaccines before inducing permanent infertility through the trap-neuter-return.

Here, we investigated antioxidant defense mechanism in the spermatheca of A. mellifera queens via RNA-seq analysis of spermathecae in both mated and virgin queens. We identified the genes encoding antioxidant proteins, which were differentially expressed in the spermatheca of mated queens. The concentrations of antioxidant proteins, such as superoxide dismutase 1 (SOD1), catalase, glutathione peroxidase (GTPX), and transferrin (Tf) together with the levels of ROS, H2O2, and iron were higher in the spermathecal fluid of mated queens as opposed to those in the spermathecal fluid of virgin queens; this indicated that increase in antioxidant protein concentration is an antioxidant defense mechanism occurring in the spermathecal fluid of mated queens against ROS; this mechanism involves conversion of ROS using antioxidant enzymes and Tf-mediated inhibition of the Fenton reaction occurring between Fe2+ and H2O2. Our data indicate that an increased expression of antioxidant proteins could facilitate prolonged storage and survival of sperms in the spermatheca of mated queens, suggesting the role of antioxidant proteins in antioxidative defense against ROS.

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.

Bee venom, which serves as a weapon to defend the colony from predator attacks, induces an immediate local inflammatory response that causes acute redness and swelling at the site of the sting. This venom-induced inflammation is a rapid anti-predatory defense strategy of the bee against vertebrate predators. Although acute inflammation by venom from venomous arthropods, including bees, is a typical response, how venom acutely elicits inflammatory responses remains unknown. Here, we identify a novel mechanism underlying acute inflammation and provide a rationale for the presence of superoxide dismutase (SOD3) in bee venom. In mouse models, paradoxically, SOD3 in bee venom (bvSOD3) acts as a reactive oxygen species (ROS)-based harm-inducing system to promote acute inflammation. Exogenous bvSOD3 rapidly induced overproduction of H2O2 through endogenously produced superoxide by venom components, such as melittin and phospholipase A2 (PLA2), which then upregulated the expression of proinflammatory genes and promoted the acute inflammatory response. Furthermore, a more severe noxious effect by bvSOD3 elevated a type 2 immune response, and bvSOD3 immunization protected against bvSOD3-mediated toxicity. Our findings that bvSOD3 promotes an acute inflammatory response and induces a protective immune response against inflammation may offer a new approach in venom therapy/immunotherapy.

This study aims to demonstrate the effectiveness of social media marketing as a tool in communicating a “populist” (Scott, 2015) luxury fashion brand’s good intentions toward ordinary people; it also seeks to identify whether luxury fashion brands frequently perceived as exclusive and “envied” could become approachable and “admired” brands, simply by expressing “warm” intentions on their social media sites. Ultimately, we aim to investigate whether positive relational outcomes can be derived from the brand repositioning process, from envy to admiration. This study builds on the brands as intentional agents framework (Kervyn, Fiske, & Malone, 2012), which categorizes brands in terms of their “intentions” and “ability”: “able/ill-intentioned” luxury brands are categorized as “envied brands,” while “able/well-intentioned” brands elicit the general public’s admiration. Our pre-test results confirmed that consumers can sense a brand’s good intentions and ability via its social media site. We then conducted an online selfreported survey among 488 US women aged 18–49 years who were following or “liking” at least one luxury fashion brand’s official social media site. Using structural equation modeling, we found that intentions have a negative impact on consumer envy, and that they have a positive impact on consumer admiration. Ability was found to have a positive impact on consumer admiration of the brands, while it has a negative impact on consumer envy. Although we confirmed negative directions, consumer envy of the brands had nonsignificant impacts on both emotional brand attachment and brand forgiveness. However, consumer admiration of the brands had a positive impact on both kinds of brand responses. In conclusion, while most luxury fashion brands have stuck to exclusivity, the findings of this study imply that by continually showing good intentions towards ordinary people, luxury fashion brands could reposition themselves as admired brands, which would in turn enhance emotional brand attachment. In this way, these brands could cultivate affectionate and passionate consumer–brand relationships making consumers feel more connected to them. In doing so, luxury fashion brands can acquire through social media powerful consumer allies (Phan, Thomas, & Heine, 2011), who are willing to forgive their failures.

Honeybee (Apis mellifera) egg-yolk protein vitellogenin (Vg) plays roles in immunity, antioxidation, and life span beyond reproduction, but it also acts as an allergen Api m 12 in venom. Here we established antimicrobial and antioxidant roles of honeybee Vg in the body and venom. Using the cDNA encoding Vg identified from Asiatic honeybee (A. cerana) workers, recombinant A. cerana Vg (AcVg) protein of approximately 180 kDa was produced in baculovirus-infected insect cells. In A. cerana worker bees, AcVg was expressed in the fat body and venom gland and was present in the secreted venom. AcVg induced structural damage in microbial cell walls via binding to microbial surfaces and exhibited antimicrobial activity against bacteria and fungi. AcVg protected mammalian and insect cells against oxidative damage through direct shielding of cell membranes. Interestingly, AcVg exhibited DNA protection activity against reactive oxygen species (ROS). Furthermore, the transcript level of AcVg was upregulated in the fat body, but not in the venom gland, of worker bees with antimicrobial peptides and antioxidant enzymes in response to microbial infection and oxidative stress. Our data indicate that AcVg is involved in innate immunity upon infection and in a defense system against ROS, supporting a crucial role of honeybee Vg as an antimicrobial and antioxidant agent in the body and venom.

Bee venom contains a variety of peptide constituents, including low-molecular-weight protease inhibitors. While the putativelow-molecular-weight serine protease inhibitor Api m 6 containing a trypsin inhibitor-like cysteine-rich domain was identifiedfrom honeybee (Apis mellifera) venom, no anti-fibrinolytic or anti-microbial roles for this inhibitor have been elucidated.In this study, we identified an Asiatic honeybee (A. cerana) venom serine protease inhibitor (AcVSPI) that was shownto act as a microbial serine protease inhibitor and plasmin inhibitor. AcVSPI was found to consist of a trypsin inhibitor-likedomain that displays ten cysteine residues. Interestingly, the AcVSPI peptide sequence exhibited high similarity to the putativelow-molecular-weight serine protease inhibitor Api m 6, which suggests that AcVSPI is an allergen Api m 6-like peptide.Recombinant AcVSPI was expressed in baculovirus-infected insect cells, and it demonstrated inhibitory activity against trypsin,but not chymotrypsin. Additionally, AcVSPI has inhibitory effects against plasmin and microbial serine proteases; however,it does not have any detectable inhibitory effects on thrombin or elastase. Consistent with these inhibitory effects, AcVSPIinhibited the plasmin-mediated degradation of fibrin to fibrin degradation products. AcVSPI also bound to bacterial andfungal surfaces and exhibited anti-microbial activity against fungi as well as gram-positive and gram-negative bacteria. Thesefindings demonstrate the anti-fibrinolytic and anti-microbial roles of AcVSPI as a serine protease inhibitor.

Major royal jelly proteins (MRJPs) are important protein components of bee royal jelly (RJ) and exhibit various biologicaland pharmacological activities. The antimicrobial activities of royalisins and the jelleines contained within MRJP 1 andMRJP 2 in RJ have been elucidated. However, the antimicrobial effects of other bee RJ MRJPs remain largely unknown.In this study, we demonstrated that the Asiatic honeybee (Apis cerana) MRJP 4 (AcMRJP4) exhibits antimicrobial activitiesagainst bacteria, fungi, and yeast. Recombinant AcMRJP4 was expressed as a 63-kDa protein in baculovirus-infected insectcells. However, some of the recombinant AcMRJP4 proteins were cleaved into two fragments (i.e., 48-kDa (AcMRJP4-48)and 15-kDa (AcMRJP4-15) proteins) by the proteolytic cleavage of the C-terminus of the recombinant AcMRJP4. Interestingly,AcMRJP4, AcMRJP4-48, and AcMRJP4-15 exhibited antimicrobial activities, with AcMRJP4-15 exhibiting the highestantimicrobial activity, followed by AcMRJP4. AcMRJP4-15, which is a hydrophilic peptide with 88 amino acid residuesthat contains a high content of Asn and positively charged amino acids, induced structural damage in the cell walls ofthe assayed bacteria, fungi, and yeast. Altogether, our data demonstrated that AcMRJP4 functions as an antimicrobial agent.

Bee venom is a complex mixture of toxic components that induces immediate local inflammatory and allergic responses. However, the presence and role of superoxide dismutase (SOD) in bee venom have not been previously investigated. Here, we provide the first demonstration that bee venom contains Cu,Zn SOD (SOD3), a novel extracellular component that promotes local inflammation. Bee venom SOD3 was shown to be an oxidant, rather than an antioxidant, that induces the inflammation-signaling molecule H2O2 in vivo. H2O2 plays a pathological role by triggering an immediate local inflammatory response. Furthermore, bee venom SOD3 significantly induced the activation of proinflammatory mediators (TNF-α and COX-2) and cytokines (IL-1β and IL-6) via the overproduction of H2O2 in mice. Our data demonstrate that bee venom SOD3 induced H2O2, which drives an immediate local inflammatory response, indicating a novel mechanism underlying bee venom-induced local inflammation.

Serine protease inhibitors play a critical role in physiological processes and immune responses by regulating serine protease activities. Here we describe the molecular cloning and antimicrobial activities of a serine protease inhibitor from the mason bee, Osmia cornifrons (OcSPI). OcSPI consists of 405 amino acid residues and contains a potential reactive center loop (RCL) region in its C-terminus. Recombinant OcSPI was produced as a 64-kDa glycoprotein in baculovirus-infected insect cells and exhibited inhibitory activity against chymotrypsin. Additionally, OcSPI demonstrated inhibitory activity against microbial serine proteases, such as subtilisin A and proteinase K, but not against tissue plasminogen activator, thrombin, or plasmin. Recombinant OcSPI bound directly to Escherichia coli, Bacillus subtilis, and Beauveria bassiana and exhibited antimicrobial activity against both bacteria and fungi. Our results demonstrated the antimicrobial functions of OcSPI and suggest a role for OcSPI in the immune response of O. cornifrons.

Bee venom contains a variety of peptide constituents that have various biological, toxicological, and pharmacological actions. However, the biological actions of secapin, a venom peptide in bee venom, remain largely unknown. Here, we provide the first evidence that the Asiatic honeybee (Apis cerana) secapin (AcSecapin-1) exhibits anti-fibrinolytic, anti-elastolytic, and anti-microbial activities. AcSecapin-1 functions as a serine protease inhibitor-like peptide that has inhibitory effects against plasmin, elastases, microbial serine proteases, trypsin, and chymotrypsin. Consistent with these functions, AcSecapin-1 inhibited the plasmin-mediated degradation of fibrin to fibrin degradation products, thus indicating the role of AcSecapin-1 as a clotting factor. AcSecapin-1 also inhibited both human neutrophil and porcine pancreatic elastases. Furthermore, AcSecapin-1 exhibited anti-microbial activity against fungi and Gram-positive and Gram-negative bacteria. Taken together, our data demonstrated that AcSecapin-1 has a multifunctional role as an anti-fibrinolytic agent, an anti-elastolytic agent, and an anti-microbial peptide, and our data suggested novel functions for the biological actions of the bee venom peptide, secapin.

The honeybee inhibitor cysteine knot (ICK) peptide acts as an antifungal peptide and insecticidal venom toxin. However, the ICK peptide from bumblebees has not been characterized. Here, we report the molecular cloning and antifungal activity of a bumblebee (Bombus ignitus) ICK peptide (BiICK). We identified a BiICK that contains an ICK fold. The BiICK was expressed in the epidermis, fat body, and venom gland of B. ignitus worker bees. A 6.7-kDa recombinant BiICK peptide was expressed in baculovirus-infected insect cells. Recombinant BiICK peptides directly bound to Beauveria bassiana, Ascosphaera apis, and Fusarium graminearum, but they did not bind to Escherichia coli, Paenibacillus larvae, or Bacillus thuringiensis. Consistent with this finding, BiICK exhibited antifungal activity against fungi. These results demonstrate that BiICK acts as an antifungal peptide.

Bees of the genus Osmia are cavity-nesting solitary species that play important roles as pollinators. Nest traps are one of the most common methods to study Osmia bees. To elucidate the optimal environmental conditions of nesting sites, we investigated the effects of location, direction, altitude, and sites of nest traps on the rate of trap-nesting Osmia spp. During the collection period, the average rate of trap-nesting Osmia spp. collected within 90 days after the installation of traps was 17.0±20.0%. This percentage was 2.7-fold higher than that of trap-nesting bees in 30 days after the installation of traps. The Jeongseon location exhibited the highest rates of trap-nesting Osmia spp. collected in 30 and 90 days, representing 11.1 ±17.6% and 23.2±22.5%, respectively. The direction of the nest traps did not affect the rate of trap-nesting Osmia spp. The altitude ranges of the traps were 0-199 m, 200-399 m, 400-599 m, 600-799 m and over 800 m. Interestingly, the altitude range of 600-799 m showed the highest rate of trap-nesting bees, which was 40.4±3.9%. Higher altitudes seemed to correspond to higher rates of trap-nesting bees. With regards to the sites where the nests were placed, the rate of trap-nesting bees in a mud wall of an old house was 45.1±25.2%, which was 3-fold higher than that of a nest in an apple orchard. The flowering plants collected at different locations during the trap-nesting activity of Osmia bees belonged to 18 families and 34 species. In conclusion, the rates of trap nests colonized by Osmia spp. were affected by altitude, site, and plant diversity.

Inhibitor cysteine knot (ICK) peptides exhibit ion channel blocking, insecticidal, and antimicrobial activities, but currently, no functional roles for bee-derived ICK peptides have been identified. In this study, a bee (Apis cerana) ICK peptide (AcICK) that acts as an antifungal peptide and as an insecticidal venom toxin was identified. AcICK contains an ICK fold that is expressed in the epidermis, fat body, or venom gland and is present as a 6.6-kDa peptide in bee venom. Recombinant AcICK peptide (expressed in baculovirus-infected insect cells) bound directly to Beauveria bassiana and Fusarium graminearum, but not to Escherichia coli or Bacillus thuringiensis. Consistent with these findings, AcICK showed antifungal activity, indicating that AcICK acts as an antifungal peptide. Furthermore, AcICK expression is induced in the fat body and epidermis after injection with B. bassiana. These results provide insight into the role of AcICK during the innate immune response following fungal infection. Additionally, we show that AcICK has insecticidal activity. Our results demonstrate a functional role for AcICK in bees: AcICK acts as an antifungal peptide in innate immune reactions in the body and as an insecticidal toxin in venom. The finding that the AcICK peptide functions with different mechanisms of action in the body and in venom highlights the two-pronged strategy that is possible with the bee ICK peptide.

Insect cuticular melanization is regulated by the prophenoloxidase (proPO)- activating system, which is also involved in the innate immune reaction. Here, we demonstrate how the differentiation of the proPO-activating system is regulated toward a cuticular melanization or innate immunity function in silkworm (Bombyx mori) pupae. Our results indicate that the differential and spatial regulation of key components, such as the proPO-activating factor, tyrosine hydroxylase, and porPOs, primes the proPO-activating system for either cuticular melanization or innate immunity. This dual strategy for cuticular melanization in development and innate immunity upon infection demonstrates a two-pronged defense mechanism that is mediated by the priming of the proPO system.

Bumblebee venom serine protease inhibitors have been shown to inhibit plasmin activity. In this study, a bumblebee (Bombus ignitus) venom serine protease inhibitor (BiVSPI) that acts as an antimicrobial factor was identified. BiVSPI is a 55-amino acid mature peptide with ten conserved cysteine residues and a P1 methionine residue. BiVSPI was expressed in the venom gland and was present as an 8-kDa peptide in venom. Recombinant BiVSPI expressed in baculovirusinfected insect cells exhibited inhibitory activity against chymotrypsin, but not trypsin. BiVSPI also exhibited inhibitory activity against microbial serine proteases, such as subtilisin A (Ki 6.57 nM) and proteinase K (Ki 7.11 nM), indicating that BiVSPI acts as a microbial serine protease inhibitor. In addition, BiVSPI was also shown to bind directly to Bacillus subtilis, B. thuringiensis, and Beauveria bassiana, but not to Escherichia coli. Consistent with these results, BiVSPI exhibited antimicrobial activity against Gram-positive bacteria and fungi. These findings provide novel evidence for the antimicrobial function of this bumblebee venom serine protease inhibitor.

Insect-derived Kazal-type serine protease inhibitors exhibit thrombin, elastase, plasmin, proteinase K, or subtilisin A inhibition activity, but so far, no functional roles for bee-derived Kazal-type serine protease inhibitors have been identified. In this study, a bee (Apis cerana) venom Kazal-type serine protease inhibitor (AcKTSPI) that acts as a microbial serine protease inhibitor was identified. AcKTSPI contained a single Kazal domain that displayed six conserved cysteine residues and a P1 threonine residue. AcKTSPI was expressed in the venom gland and was present as a 10-kDa peptide in bee venom. Recombinant AcKTSPI Kazal domain (AcKTSPI-Kd) expressed in baculovirus-infected insect cells demonstrated inhibitory activity against subtilisin A (Ki 67.03 nM) and proteinase K (Ki 91.53 nM), but not against α-chymotrypsin or typsin, which implies a role for AcKTSPI as a microbial serine protease inhibitor. However, AcKTSPI-Kd exhibited no detectable inhibitory effects on factor Xa, thrombin, tissue plasminogen activator, or elastase. Additionally, AcKTSPI-Kd bound directly to Bacillus subtilis, B. thuringiensis, Beauveria bassiana, and Fusarium graminearum but not to Escherichia coli. Consistent with these findings, AcKTSPI-Kd showed antibacterial activity against Gram-positive bacteria and antifungal activity against both plant-pathogenic and entomopathogenic fungi. These findings constitute molecular evidence that AcKTSPI acts as an inhibitor of microbial serine proteases. This paper provides a novel view of the antimicrobial functions of a bee venom Kazal-type serine protease inhibitor.

Bee venom contains a variety of peptides and enzymes, including serine proteases. While the presence of serine proteases in bee venom has been demonstrated, the role of these proteins in bee venom has not been elucidated. Furthermore, there is currently no information available regarding the melanization response or the fibrin(ogen)olytic activity of bee venom serine protease, and the molecular mechanism of its action remains unknown. Here we show that bee venom serine protease (Bi-VSP) is a multifunctional enzyme. In insects, Bi-VSP acts as an arthropod prophenoloxidase (proPO)-activating factor (PPAF), thereby triggering the phenoloxidase (PO) cascade. Bi-VSP injected through the stinger induces a lethal melanization response in target insects by modulating the innate immune response. In mammals, Bi-VSP acts similarly to snake venom serine protease, which exhibits fibrin(ogen)olytic activity. Bi-VSP activates prothrombin and directly degrades fibrinogen into fibrin degradation products, defining roles forBi-VSP as a prothrombin activator, a thrombin-like protease, and a plasmin-like protease. These findings provide a novel view of the mechanism of bee venom in which the bee venom serine protease kills target insects via a melanization strategy and exhibits fibrin(ogen)olytic activity.

Glutathione S-transferases (GSTs) are multifunctional enzymes that are mainlyinvolved in the xenobiotic metabolism and protection against oxidative damage. Most studies of GSTs in insects have been focused on their role in detoxifying exogenous compounds in particular insecticides. Here, we show the expression profiles of GSTs of the bumblebee Bombus ignitus in response to oxidative stress. We identified a sigma-class GST from B. ignitus (BiGSTS). The BiGSTSgene consists of 4 exons that encode 201 amino acids. Comparative analysis indicates that the predicted amino acid sequence of BiGSTS shares a high identity with the sigma-class GSTs of hymenopteran insects such as Apis mellifera (70% protein sequence identity) and Solenopsis invicta (59% protein sequence identity). Tissue distribution analyses showed the presence of BiGSTS in all tissues examined, including the fat body, midgut, muscle and epidermis. The oxidative stress responses analyzed by quantitative real-time PCR showed that under H2O2 overload, BiGSTS and BiGSTD (identified in our previous study) were upregulated in all tissues examined, including the fat body and midgut of B. ignitus worker bees. Under uniform conditions of H2O2 overload, the expression profile of GSTs and other antioxidant enzyme genes, such as phospholipid-hydroperoxide glutathione peroxidase (Bi-PHGPx) and peroxiredoxins (BiPrx1 and BiTPx1), showed that other antioxidant enzyme genes are acutely induced at 3 h after H2O2 exposure, whereas BiGSTS and BiGSTD are highly induced at 9 h after H2O2 exposure in the fat body of B. ignitus worker bees. These findings indicate that GSTs and other antioxidant enzyme genes in B. ignitusare differentially expressed in response to oxidative stress. Taken together, our findings indicate that BiGSTS and BiGSTD are oxidative stress-inducible antioxidant enzymes that may play a role in oxidative stress response.