Design of a modern liposome and bee venom formulation for the traditional VIT-venom immunotherapy

Traditional venom immunotherapy uses injections of whole bee venom in buffer or adsorbed in Al (OH)(3) in an expensive, time-consuming way. New strategies to improve the safety and efficacy of this treatment with a reduction of injections would, therefore, be of general interest. It would improve patient compliance and provide socio-economic benefits. Liposomes have a long tradition in drug delivery because they increase the therapeutic index and avoid drug degradation and secondary effects. However, bee venom melittin (Mel) and phospholipase (PLA(2)) destroy the phospholipid membranes. Our central idea was to inhibit the PLA(2) and Mel activities through histidine alkylation and or tryptophan oxidation (with pbb, para-bromo-phenacyl bromide, and/or NBS- N-bromosuccinimide, respectively) to make their encapsulations possible within stabilized liposomes. We strongly believe that this formulation will be nontoxic but immunogenic. In this paper, we present the whole bee venom conformation characterization during and after chemical modification and after interaction with liposome by ultraviolet, circular dichroism, and fluorescence spectroscopies. The PLA(2) and Mel activities were measured indirectly by changes in turbidity at 400(n m), rhodamine leak-out, and hemolysis. The native whole bee venom (BV) presented 78.06% of alpha-helical content. The alkylation (A-BV) and succynilation (S-BV) of BV increased 0.44 and 0.20% of its alpha-helical content. The double-modified venom (S-A-BV) had a 0.74% increase of alpha-helical content. The BV chemical modification induced another change on protein conformations observed by Trp that became buried with respect to the native whole BV. It was demonstrated that the liposomal membranes must contain pbb (SPC:Cho:pbb, 26:7:1) as a component to protect them from aggregation and/or fusion. The membranes containing pbb maintained the same turbidity (100%) after incubation with modified venom, in contrast with pbb-free membranes that showed a 15% size decrease. This size decrease was interpreted as membrane degradation and was corroborated by a 50% rhodamine leak-out. Another fact that confirmed our interpretation was the observed 100% inhibition of the hemolytic activity after venom modification with pbb and NBS (S-A-BV). When S-A-BV interacted with liposomes, other protein conformational changes were observed and characterized by the increase of 1.93% on S-A-BV alpha-helical content and the presence of tryptophan residues in a more hydrophobic environment. In other words, the S-A-BV interacted with liposomal membranes, but this interaction was not effective to cause aggregation, leak-out, or fusion. A stable formulation composed by S-A-BV encapsulated within liposomes composed by SPC:Cho:pbb, at a ratio of 26:7:1, was devised. Large unilamellar vesicles of 202.5 nm with a negative surface charge (-24.29 mV) encapsulated 95% of S-A-BV. This formulation can, now, be assayed on VIT.     

Design of a Modern Liposome and Bee Venom Formulation for the Traditional VIT-Venom Immunotherapy

Traditional venom immunotherapy uses injections of whole bee venom in buffer or adsorbed in Al (OH)₃ in an expensive, time-consuming way. New strategies to improve the safety and efficacy of this treatment with a reduction of injections would, therefore, be of general interest. It would improve patient compliance and provide socio-economic benefits. Liposomes have a long tradition in drug delivery because they increase the therapeutic index and avoid drug degradation and secondary effects. However, bee venom melittin (Mel) and phospholipase (PLA₂) destroy the phospholipid membranes. Our central idea was to inhibit the PLA₂ and Mel activities through histidine alkylation and or tryptophan oxidation (with pbb, para-bromo-phenacyl bromide, and/or NBS- N-bromosuccinimide, respectively) to make their encapsulations possible within stabilized liposomes. We strongly believe that this formulation will be nontoxic but immunogenic. In this paper, we present the whole bee venom conformation characterization during and after chemical modification and after interaction with liposome by ultraviolet, circular dichroism, and fluorescence spectroscopies. The PLA₂ and Mel activities were measured indirectly by changes in turbidity at 400_{n m}, rhodamine leak-out, and hemolysis. The native whole bee venom (BV) presented 78.06%?of α-helical content. The alkylation (A-BV) and succynilation (S-BV) of BV increased 0.44 and 0.20%?of its α-helical content. The double-modified venom (S-A-BV) had a 0.74%?increase of α-helical content. The BV chemical modification induced another change on protein conformations observed by Trp that became buried with respect to the native whole BV. It was demonstrated that the liposomal membranes must contain pbb (SPC:Cho:pbb, 26:7:1) as a component to protect them from aggregation and/or fusion. The membranes containing pbb maintained the same turbidity (100%) after incubation with modified venom, in contrast with pbb-free membranes that showed a 15%?size decrease. This size decrease was interpreted as membrane degradation and was corroborated by a 50%?rhodamine leak-out. Another fact that confirmed our interpretation was the observed 100%?inhibition of the hemolytic activity after venom modification with pbb and NBS (S-A-BV). When S-A-BV interacted with liposomes, other protein conformational changes were observed and characterized by the increase of 1.93%?on S-A-BV α-helical content and the presence of tryptophan residues in a more hydrophobic environment. In other words, the S-A-BV interacted with liposomal membranes, but this interaction was not effective to cause aggregation, leak-out, or fusion. A stable formulation composed by S-A-BV encapsulated within liposomes composed by SPC:Cho:pbb, at a ratio of 26:7:1, was devised. Large unilamellar vesicles of 202.5 nm with a negative surface charge (–24.29 mV) encapsulated 95%?of S-A-BV. This formulation can, now, be assayed on VIT.     

Apoptotic Effect of Melittin Purified from Iranian Honey Bee Venom on Human Cervical Cancer HeLa Cell Line

Melittin, an amphipathic 26-residue peptide, is the main component of honey bee venom. Studies have been demonstrated that melittin has an inhibitory effect on proliferation of cancer cells. However, the precise mechanism of action is not completely understood. In the present study we have shown that purified melittin from Iranian honey bee venom shows anti-cancer effects on human cervical cancer cell line through induction of apoptosis. The venom was collected from Iranian honey bee (Apis mellifera meda) and melittin isolated using reversed phase HPLC. Biological activity of melittin was analyzed by hemolytic test on human red blood cells. In order to investigate whether melittin inhibits proliferation of cervical cancer cells, the viability of the melittin treated HeLa cell line was measured via MTT assay. Finally, cell death analysis was performed using Propidum iodide and Annexin V-FITC dual staining. The results showed that the half hemolytic concentration (HD50) induced by mellitin was 0.5 µg/ml in free FBS solution. IC50 obtained after 12 h at 1.8 µg/ml by MTT assay. According to flow cytometric analysis, melittin induced apoptosis at concentrations more than 1 µg/ml. These results suggest that melittin induces apoptotic cell death in cervical cancerous cells as observed by flow cytometric assay. It is concluded that melittin could be regarded as a potential candidate in future studies to discovery of new anticancer agents.     

Characterization of some membrane-active components of Vespa orientalis venom

The molecular weight distribution of the components of giant hornet (Vespa orientalis) venom was studied, using gel-filtration on a column with Sephadex G-50. The effects of the venom and its constituent fractions on the permeability and stability of artificial bilayer phospholipid membranes, potassium ions release from the erythrocytes and mitochondrial oxidative phosphorylation parameters, as well as on the activity and stability of polyenzymic systems of the mitochondrial respiratroy chain, were studied. The data obtained suggest that the high molecular weight fractions contain phospholipases, whose activities are much higher than those of presently known venoms. Despite the fact that the hemolytic effect is typical for two low molecular weight fractions, no fractions possessing high activity of bee venom of the melitin type were found.     

Biological activities of C-terminal 15-residue synthetic fragment of melittin: design of an analog with improved antibacterial activity

Melittin, the 26-residue predominant toxic peptide from bee venom, exhibits potent antibacterial activity in addition to its hemolytic activity. The synthetic peptide of 15 residues corresponding to its C-terminal end (MCF), which encompasses its most amphiphilic segment, is now being shown to possess antibacterial activity about 5-7 times less compared to that of melittin. MCF, however, is 300 times less hemolytic. An analog of MCF, MCFA, in which two cationic residues have been transpositioned to the N-terminal region from the C-terminal region, exhibits antibacterial activity comparable to that of melittin, but is only marginally more hemolytic than MCF. The biophysical properties of the peptides, like folding and aggregation, correlate well with their biological properties.     

Functional interaction between Cerebratulus lacteus cytolysin A-III and phospholipase A2. Implications for the mechanism of cytolysis

A study on the interaction between bee venom phospholipase A2 and Cerebratulus lacteus cytolysin A-III, a major hemolysin secreted by this organism has been carried out. The hemolytic activity of A-III in phosphate-buffered saline is increased 5-fold in the presence of phospholipase A2 from bee venom. Dansylphosphatidylethanolamine (DPE) labeled, phosphatidylcholine-containing liposomes and human erythrocyte membranes were employed to study the interaction between these two proteins. In DPE-liposomes, A-III alone had no effect on DPE fluorescence nor did it enhance either the phospholipase A2-dependent fluorescence increase or blue shift in emission maximum, indicating that the cytolysin is not a major phospholipase A2-activator. However, when DPE was incorporated into erythrocyte membranes, A-III alone induced a 40% fluorescence increase and a 5 nm blue shift, implying a transient activation of an endogenous phospholipase A2. Further studies using synthetic lysophosphatidylcholine and free fatty acids demonstrated that the hemolytic activity of A-III is potentiated by free fatty acids, a product of phospholipid degradation catalyzed by phospholipase A2. Together, sublytic concentrations of A-III and nonlytic concentrations of oleic acid cause extensive cell lysis. Subsequent analysis of this phenomenon by gel filtration chromatography, analytical ultracentrifugation, chemical cross-linking, and measurement of [14C]oleic acid binding by the cytolysin demonstrated that binding of oleic acid to A-III causes aggregation of the toxin molecules to a tetrameric form which has a higher alpha-helix content and a greater activity than the monomer.     

Membrane structure and function. Mechanism of hemolysis induced by nematocyst venom: roles of phospholipase A and direct lytic factor.

Pure venom from the acontial nematocysts of the sea anemone Aiptasia pallida exhibited phospholipase A (phosphatide acyl-hydrolase; EC 3.1.1.4) activity on a mixture of free phospholipids. Diethyl aminoethyl cellulose fractionation of the venom gave four distinct protein peaks with the phospholipase A activity being restricted to fractions III and IV. These two fractions tested separately also were able to lyse red blood cells weakly. Fractions I and II enhanced the hemolytic activity of fractions III and IV, with fractions I and III giving as much as ninefold enhancement over that of III alone. Fraction I appears analogous to the direct lytic factor of some snake and bee venoms. Fraction III, which could not appreciably hydrolyze the phospholipids of the intact red cell membrane, was able to do so in the presence of fraction I. The sequential interactions of these two nematocyst venom proteins with the red blood cell membrane to produce hemolysis is discussed.     

Sulfated sialic acid-polymers inhibit the cytotoxic action of bee and snake venom

Colominic acid is an 2,8-linked sialic acid polymer produced by Escherichia coli. We found that synthetic sulfated-colominic acids (SC) remarkably inhibited the cytotoxicity of bee and snake venom toward mouse fibroblast cells, but colominic acids showed no inhibition themselves, indicating the important role of sulfate groups in the inhibitory activity of SC. Other sulfated carbohydrates such as chondroitin sulfates, heparin and heparan sulfate showed no inhibition. SC also exhibited potent inhibition of melittin, a highly basic peptide, which is a major cytotoxic component of bee venom. SC did not inhibit phospholipase A₂ activity in bee venom. This suggests that the inhibition of bee and snake venom by SC is due to inhibition of melittin and cardiotoxin, which is a cytolytic peptide in snake venom, respectively. SC with a higher sulfur content and a larger molecular mass showed more potent activity. The interaction between SC and melittin basically seems an ionic one, however, the conformation of SC is also likely important. For the binding of SC to melittin leading loss of its cytotoxic activity, the sulfate groups of SC must be properly arranged to interact with lysine and arginine residues of melittin molecules, which play an important role in the cytolytic activity. A higher molecular mass of SC substituted with more sulfate groups is required for more obvious inhibition of the cytotoxic activity.     

Contribution of proline-14 to the structure and actions of melittin

The structure and dynamic properties of bee venom melittin and a synthetic analogue, [Ala14]-melittin (melittin P14A), are compared, using high resolution 1H nuclear magnetic resonance (NMR) spectroscopy and amide exchange measurements in methanol. P14A is shown to adopt a regular, stable alpha-helical conformation in solution without the flexibility around the Pro-14 residue found in melittin. P14A has twice the hemolytic activity of melittin but is less able to induce voltage-dependent ion conductance in planar bilayers. The results indicate that helix flexibility afforded by the Pro-14 residue promotes the ability of melittin to adopt the transbilayer associates thought to underlie ion translocation.     

Red blood cell lysis induced by the venom of the brown recluse spider: the role of sphingomyelinase D.

Red blood cell lysis induced by the venom of Loxosceles reclusa, the brown recluse spider, may be related to the hemolytic anemia observed in several cases of spider envenomation. These investigations demonstrate that the venom of the brown recluse spider contains a calcium-dependent, heat-labile hemolysin of molecular weight approximately 19,000. The pH optimum for the hemolytic reaction was 7.1, and the optimum calcium concentration for venom-induced lysis was observed within the range of 6 to 10 mm. Sheep red blood cells were more susceptible to the spider hemolysin than human red blood cells, although both types exhibited appreciable lysis. Digestion of sheep red blood cell membranes with partially purified venom lysin resulted in degradation of the sphingomyelin component. However, reaction of the membranes with the venom lysin produced no release of water-soluble phosphate, and no free fatty acids were generated. These results indicate that the sphingomyelin-degrading activity of the venom is not a phospholipase C- or a phospholipase A₂-type activity. Sphingomyelin was employed as substrate for the venom hemolysin, and the organic and aqueous fractions of the reaction mixtures were analyzed by thin-layer chromatography. Analysis of the organic fraction revealed a phosphate-containing product with the solubility and chromatographic characteristics of N-acylsphingosine phosphate (ceramide phosphate), and analysis of the aqueous fraction demonstrated the presence of choline. The isolation and identification of these products indicate that the sphingomyelin of the red cell membrane is hydrolyzed by a sphingomyelinase D-type activity expressed by the partially purified venom hemolysin. A close correspondence between the hemolytic and sphingomyelinase D activities was observed when the partially purified hemolysin was further characterized in polyacrylamide gel electrophoresis at pH 8.3 and pH 4.9. The hemolytic and sphingomyelinase activities were coincident within the electrophoretic pattern at both pHs. The results presented demonstrate conclusively a direct lytic action of brown recluse venom upon red blood cells and report for the first time the presence of sphingomyelinase D in spider venom.     

Conformation and activity of delta-lysin and its analogs

Delta-Lysin is a 26-residue hemolytic peptide secreted by Staphylococcus aureus. Unlike the bee venom peptide melittin, delta-lysin does not exhibit antibacterial activity. We have synthesized delta-lysin and several analogs wherein the N-terminal residues of the toxin were sequentially deleted. The toxin has three aspartic acids, four lysines and no prolines. Analogs were also generated in which all the aspartic acids were replaced with lysines. A proline residue was introduced in the native sequences as well as in the analogs where aspartic acids were replaced with lysines. We observed that 20- and 22-residue peptides corresponding to residues 7-26 and 5-26 of delta-lysin, respectively, had greater hemolytic activity than the parent peptide. These shorter peptides, unlike delta-lysin, did not self-associate to adopt alpha-helical conformation in water, at lytic concentrations. Introduction of proline or substitution of aspartic acids by lysines resulted in loss in propensity to adopt helical conformation in water. When proline was introduced in the peptides corresponding to the native toxin sequence, loss of hemolytic activity was observed. Substitution of all the aspartic acids with lysines resulted in enhanced hemolytic activity in all the analogs. However, when both proline and aspartic acid to lysine changes were made, only antibacterial activity was observed in the shorter peptides. Our investigations on delta-lysin and its analogs provide insights into the positioning of anionic, cationic residues and proline in determining hemolytic and antibacterial activities.     

中华眼镜蛇蛇毒因子(CVF)对补体系统的作用及与人补作C_3和其他蛇毒抗原性关系

中华眼镜蛇蛇毒经DEAE-Sepharose CL-6B。HPLC等多次柱层析分离出有抗补体及溶血活性的眼镜蛇蛇毒因子(Cobra venom factor,CVF),纯化后的CVF在聚丙烯酰胺凝胶电泳图谱上呈单一区带,分子量为225000—230000,等电点为6.20。用二硫苏糖醇还原经SDS-聚丙烯酰胺凝胶电泳得三类亚基,其分子量总和为237,000。 体外抗补体及溶血试验表明,CVF的作用是通过补体旁路途经使总补体活力下降。双向免疫电泳鉴定,发现CVF与人血清作用后,其中补体成分C_3分子的抗原性发生改变,则表明CVF的作用是通过激活补体成分C_3而发挥的。给豚鼠腹腔注射CVF(0.15ug/g体重)后,其血清总补体水平下降到正常值的3％以下,7天后回升,13天后恢复到正常水平。 单相免疫电泳表明,CVF与人补体C_3抗血清间无任何交叉免疫反应,但人血清与CVF抗血清间有微弱的免疫沉淀反应。另外,CVF的氨基酸组成与人补体C_3也较为相似。鉴定还表明眼镜蛇科中四种蛇毒与CVF抗血清有强烈的免疫沉淀反应,蝰蛇毒及海蛇毒也有免疫沉淀反应,但只有眼镜蛇毒具有抗补体活性。     

The role of tryptophan residues in the hemolytic activity of stonustoxin,a lethal factor from stonefish (Synanceja horrida) venom

Stonustoxin (SNTX) is a pore-forming cytolytic lethal factor, isolated from the venom of the stonefish Synanceja horrida, that has potent hemolytic activity. The role of tryptophan residues in the hemolytic activity of SNTX was investigated. Oxidation of tryptophan residues of SNTX with N-bromosuccinimide (NBS) resulted in loss of hemolytic activity. Binding of 8-anilino-1-naphthalenesulphonate (ANS) to SNTX resulted in occlusion of tryptophan residues that resulted in loss of hemolytic activity. Circular dichroism and fluorescence studies indicated that ANS binding resulted in a conformational change of SNTX, in particular, a relocation of surface tryptophan residues to the hydrophobic interior. NBS-modification resulted in oxidised surface tryptophan residues that did not relocate to the hydrophobic interior. These results suggest that native surface tryptophan residues play a pivotal role in the hemolytic activity of STNX, possibly by being an essential component of a hydrophobic surface necessary for pore-formation. This study is the first report on the essentiality of tryptophan residues in the activity of a lytic and lethal factor from a fish venom.     

Novel antimicrobial peptides from the venom of the eusocial bee Halictus sexcinctus (Hymenoptera: Halictidae) and their analogs

Two novel antimicrobial peptides, named halictines, were isolated from the venom of the eusocial bee Halictus sexcinctus. Their primary sequences were established by ESI-QTOF mass spectrometry, Edman degradation and enzymatic digestion as Gly-Met-Trp-Ser-Lys-Ile-Leu-Gly-His-Leu-Ile-Arg-NH₂ (HAL-1), and Gly-Lys-Trp-Met-Ser-Leu-Leu-Lys–His-Ile-Leu-Lys-NH₂ (HAL-2). Both peptides exhibited potent antimicrobial activity against Gram-positive and Gram-negative bacteria but also noticeable hemolytic activity. The CD spectra of HAL-1 and HAL-2 measured in the presence of trifluoroethanol or SDS showed ability to form an amphipathic α-helical secondary structure in an anisotropic environment such as bacterial cell membrane. NMR spectra of HAL-1 and HAL-2 measured in trifluoroethanol/water confirmed formation of helical conformation in both peptides with a slightly higher helical propensity in HAL-1. Altogether, we prepared 51 of HAL-1 and HAL-2 analogs to study the effect of such structural parameters as cationicity, hydrophobicity, α-helicity, amphipathicity, and truncation on antimicrobial and hemolytic activities. The potentially most promising analogs in both series are those with increased net positive charge, in which the suitable amino acid residues were replaced by Lys. This improvement basically relates to the increase of antimicrobial activity against pathogenic Pseudomonas aeruginosa and to the mitigation of hemolytic activity.     

Lasiocepsin, a novel cyclic antimicrobial peptide from the venom of eusocial bee Lasioglossum laticeps (Hymenoptera: Halictidae)

In the venom of eusocial bee Lasioglossum laticeps, we identified a novel unique antimicrobial peptide named lasiocepsin consisting of 27 amino acid residues and two disulfide bridges. After identifying its primary structure, we synthesized lasiocepsin by solid-phase peptide synthesis using two different approaches for oxidative folding. The oxidative folding of fully deprotected linear peptide resulted in a mixture of three products differing in the pattern of disulfide bridges. Regioselective disulfide bond formation significantly improved the yield of desired product. The synthetic lasiocepsin possessed antimicrobial activity against both Gram-positive and -negative bacteria, antifungal activity against Candida albicans, and no hemolytic activity against human erythrocytes. We synthesized two lasiocepsin analogs cyclized through one native disulfide bridge in different positions and having the remaining two cysteines substituted by alanines. The analog cyclized through a Cys8-Cys25 disulfide bridge showed reduced antimicrobial activity compared to the native peptide while the second one (Cys17-Cys27) was almost inactive. Linear lasiocepsin having all four cysteine residues substituted by alanines or alkylated was also inactive. That was in contrast to the linear lasiocepsin with all four cysteine residues non-paired, which exhibited remarkable antimicrobial activity. The shortening of lasiocepsin by several amino acid residues either from the N- or C-terminal resulted in significant loss of antimicrobial activity. Study of Bacillus subtilis cells treated by lasiocepsin using transmission electron microscopy showed leakage of bacterial content mainly from the holes localized at the ends of the bacterial cells.     

Bee Venom Induces the Interaction between Phosphorylated Histone Variant,H2AX,and the Intracellular Site of beta-Actin in Liver and Breast Cancer Cells

Bee venom is a natural mixture and candidate anti-cancer agent with selective cytotoxic effect on some cancer cells. However, the cellular mechanisms of how bee venom selectively targets cancer cells remain elusive. The aim of this study was to reveal the genotoxic effect of bee venom in concordance with the location of β-actin protein throughout the nucleus or/and cytoplasm. For this aim, the level of H2AX phosphorylation (γH2AX) and intracellular location of β-actin were assessed by immunofluorescence in liver (HEPG2) and metastatic breast (MDA-MB-231) cancer cell lines compared to normal fibroblasts (NIH3T3) after bee venom treatment. Colocalisation profiles of γH2AX and β-actin in each cell line were also analysed. The results showed that the levels of γH2AX staining decreased in normal cells but increased in cancer cells. The majority of β-actin was localised within the cytoplasm of normal cells after bee venom treatment, but it was mostly accumulated within the nucleus in cancer cells. Colocalisation of β-actin and γH2AX both in nucleus and cytoplasm was induced in each cancer cell by different patterns. The results showed that normal and cancerous cells had different responses against bee venom, and suggested that bee venom induced a cellular response by the interaction between γH2AX and β-actin.     

Phaiodactylipin, a glycosylated heterodimeric phospholipase A from the venom of the scorpion Anuroctonus phaiodactylus.

Phaiodactylipin was purified from the venom of the scorpion Anuroctonus phaiodactylus. It is the first protein to be purified from a scorpion of the family Iuridae and has a molecular mass of 19 172 atomic mass units. The mature protein is composed of two subunits, the large one consisting of 108 amino acid residues, whereas the small subunit has only 18 residues, and the structure is stabilized by five disulfide bridges. The heterodimer is expressed from a single message containing 769 base pairs and a signal peptide with 16 and/or 25 amino acid residues. During maturation an internal hexapeptide is excised. There are three putative sites of N-glycosylation, one of which is situated in the small subunit region. The carbohydrate composition of this site was determined by mass spectrometry analysis and was found to contain three hexoses, two N-acetyl-hexoses and two deoxyhexoses. The protein has a calcium dependent phospholipase A(2) type of activity. It is lethal to arthropods (insects and isopods), but not toxic to mammals, using doses up to 20 microg per 20 g mouse body weight. For crickets, a dose of 5 microg per animal is lethal; however, when injected into mice it is capable of causing only muscular inflammation, without rupture of the basal membrane of cells. It has a direct hemolytic effect in human erythrocytes and retards the coagulation time of blood. It is an unusual phospholipase A(2), with only 36% and 50% amino acid sequence identities to the closest known phospholipases, imperatoxin I and phospholipin, respectively. Identities with bee and Heloderma venom phospholipase are only in the order of 28%.     

Isolation and partial characterization of a hemolytic and toxic protein from the nematocyst venom of the Portuguese Man-of-War, Physalia physalis

Nematocysts isolated from the stinging tentacles of the Atlantic Portuguese Man-of-War (Physalia physalis) possess a potent venom composed of several proteins. A hemolytic protein lethal to mice has been isolated from this nematocyst venom. This protein, physalitoxin, appears to be responsible for both the venom's hemolytic and lethal activities. The hemolysin has a molecular weight of approx. 240 000, a sedimentation coefficient of 7.8 S, and is rod-like in shape with a calculated axial ratio of about 1 : 10. It appears to be composed of three subunits of unequal size, each of which is glycosylated. Two of these subunits seem to have pKi values near 8.2 and the third near 5.5. Physalitoxin comprises about 28% of the total nematocyst venom protein. It is 10.6% carbohydrate by weight and represents the major glycoprotein of the venom. Physalitoxin is inactivated by concanavalin A and this inactivation can be blocked with alpha-methyl-mannoside. The inactivation by concanavalin A is temperature-dependent about 12 degrees C and the hemolytic activity of untreated venom is temperature-dependent below 12 degrees C. Physalitoxin is the first hemolytic toxin from a cnidarian to be purified directly from isolated nematocysts.     

Inhibition of [3H]nitrendipine binding by phospholipase A2

Phospholipase A2 from several sources inhibited [3H]nitrendipine binding to membranes from brain, heart and ileal longitudinal muscle. The enzymes from bee venom and Russell's viper venom were most potent, having IC50 values of approximately 5 and 14 ng/ml, respectively, in all three membrane preparations. Inhibition of binding by bee venom phospholipase A2 was time- and dose-dependent. Mastoparan, a known facilitator of phospholipase A2 enzymatic activity, shifted the bee venom phospholipase A2 dose-response curve to the left. Pretreatment of brain membranes with bee venom phospholipase A2 (10 ng/ml) for 15 min caused a 2-fold increase in the Kd without changing the Bmax compared with untreated membranes. Extension of the preincubation period to 30 min caused no further increase in the Kd but significantly decreased the Bmax to 71% the value for untreated membranes. [3H]Nitrendipine, preincubated with bee venom phospholipase A2, was recovered and found to be fully active, indicating that the phospholipase A2 did not modify the ligand. It is concluded that phospholipase A2 acts on the membrane at or near the [3H]nitrendipine binding site and that phospholipids play a key role in the interactions of 1,4 dihydropyridine calcium channel antagonists with the dihydropyridine binding site.     

Molecular characterization of a venom acid phosphatase Acph-1-like protein from the Asiatic honeybee Apis cerana

Bee venom contains a variety of peptides and enzymes, including acid phosphatases. An acid phosphatase has been identified from European honeybee (Apis mellifera) venom. However, although the amino acid sequence is known, no functional information is currently available for bee venom acid phosphatase Acph-1-like proteins. In this study, an Asiatic honeybee (Apis cerana) venom acid phosphatase Acph-1-like protein (AcAcph-1) was identified. The analysis of the predicted AcAcph-1 amino acid sequence revealed high levels of identity with other bee venom acid phosphatase Acph-1-like proteins. Recombinant AcAcph-1 was expressed as a 64-kDa protein in baculovirus-infected insect cells. The enzymatic properties of recombinant AcAcph-1, determined using p-nitrophenyl phosphate (p-NPP) as a substrate, showed the highest activity at 45 °C and pH 4.8. Northern and western blot analyses showed that AcAcph-1 was expressed in the venom gland and was present as a 64-kDa protein in bee venom. In addition, N-glycosylation of AcAcph-1 was revealed by tunicamycin treatment of recombinant virus-infected insect Sf9 cells and by glycoprotein staining of purified recombinant AcAcph-1. Our findings show that AcAcph-1 functions as a venom acid phosphatase. This paper provides the first evidence of the role of a bee venom acid phosphatase Acph-1-like protein.