Sequence homology between phospholipase and its inhibitor in snake venom. The primary structure of phospholipase A2 of vipoxin from the venom of the Bulgarian viper (Vipera ammodytes ammodytes, Serpentes)

The amino-acid sequence of phospholipase A2 from the neurotoxin vipoxin of the Bulgarian Viper (Vipera ammodytes ammodytes, Serpentes) is presented. The enzyme consists of 122 amino-acid residues including 7 disulfide bonds and thus belongs to phospholipases A2 group IIA. The sequence was determined by automatic Edman degradation of the intact chain and of the peptides obtained after tryptic hydrolysis of the oxidized chain. The short cleavage time of 30 min and another limited tryptic digestion of the oxidized and citraconylated chain provided overlapping peptides. Sequencing was done with liquid- and gas-phase sequenators. The complete alignment of all peptides was facilitated by the high degree of homology with known viperid venom phospholipases A2. In common with mammalian phospholipases, the tryptophan residue in position 30 (essential for enzymatic activity) as well as the histidine in position 47 in the active site are present. Vipoxin phospholipase A2 shows 53.3% homology with another phospholipase A2 from Vipera ammodytes ammodytes venom (Ammodytoxin B), whereas 62% homology was found between both subunits of vipoxin phospholipase A2 and its inhibitor. This high degree of identity can be accounted for in terms of a common origin by gene duplication.     

The first phospholipase inhibitor from the serum of Vipera ammodytes ammodytes

Ammodytoxins are neurotoxic secretory phospholipase A(2) molecules, some of the most toxic components of the long-nosed viper (Vipera ammodytes ammodytes) venom. Envenomation by this and by closely related vipers is quite frequent in southern parts of Europe and serotherapy is used in the most severe cases. Because of occasional complications, alternative medical treatment of envenomation is needed. In the present study, ammodytoxin inhibitor was purified from the serum of V. a. ammodytes using two affinity procedures and a gel exclusion chromatography step. The ammodytoxin inhibitor from V. a. ammodytes serum consists of 23- and 25-kDa glycoproteins that form an oligomer, probably a tetramer, of about 100 kDa. N-terminal sequencing and immunological analysis revealed that both types of subunit are very similar to gamma-type secretory phospholipase A(2) inhibitors. The ammodytoxin inhibitor from V. a. ammodytes serum is a potent inhibitor of phospholipase activity and hence probably also the neurotoxicity of ammodytoxins. Discovery of the novel natural inhibitor of these potent secretory phospholipase A(2) toxins opens up prospects for the development of new types of small peptide inhibitors for use in regulating the physiological and pathological activities of secretory phospholipases A(2).     

Sequence homology between phospholipase and its inhibitor in snake venom. The primary structure of the inhibitor of vipoxin from the venom of the Bulgarian viper (Vipera ammodytes ammodytes, Serpentes)

We are presenting the first primary structure of a snake venom inhibitor. It was isolated from the neurotoxin vipoxin of the Bulgarian Viper (Vipera ammodytes ammodytes, Serpentes) which represents a complex of a strong toxic basic protein with phospholipase A2 activity (2 isoenzymes) and the nontoxic acidic component functioning as its inhibitor. The sequence was established by automatic degradation in a liquid phase sequenator on the S-carboxymethylated chain and on the peptides obtained by tryptic hydrolysis of the oxidized chain. A limited tryptic digestion of the oxidized chain provided the necessary overlapping peptides. The inhibitor consists of 122 amino-acid residues including 14 cysteine and 10 tyrosine residues and is thus similar to the phospholipases from snake venoms. A comparison of the inhibitor sequence with the primary structure of the phospholipase A2 (CM-II) from the Horned Adder (Bitis nasicornis) venom shows a surprising homology of 52%. The identical amino acids include the cysteine and tyrosine residues and are generally accumulated in the surroundings of cysteine residues. The histidine (pos. 47) in the active center of the phospholipase A2 is substituted by glutamine in the inhibitor, but the tryptophan (pos. 30) which is essential for the enzymatic activity is present. The significant homology between enzyme and inhibitor in the vipoxin complex is believed to originate from a gene duplication. The relatively late development of the reptiles and the snake venom complex explains the highly preserved structure compared to other enzyme-inhibitor systems.     

Amino acid and cDNA sequences of a neutral phospholipase A2 from the long-nosed viper (Vipera ammodytes ammodytes) venom.

The amino acid sequence of a non-toxic phospholipase A2, ammodytin I2, from the venom of the long-nosed viper (Vipera ammodytes ammodytes) and its cDNA sequence have been determined. The protein sequence was elucidated by sequencing the peptides generated by CNBr cleavage, mild acid hydrolysis and tryptic digestion of maleylated and non-maleylated protein. Sequencing of the cDNA showed that the protein is synthesized as an 137-amino-acid-residue precursor molecule consisting of a 16-residue signal peptide, followed by a 121-residue mature enzyme. Ammodytin I2 cDNA shows 73% nucleotide and 59% amino acid identities in the mature protein region in comparison to that of ammodytoxin A, the most presynaptically neurotoxic phospholipase A2 from the long-nosed viper. Identities in the signal-peptide region are considerably higher, 96% and 100%, respectively.     

Comparative analysis of the venom proteomes of Vipera ammodytes ammodytes and Vipera ammodytes meridionalis

The venom proteomics of Vipera ammodytes ammodytes and Vipera ammodytes meridionalis, snakes of public health significance and the most poisonous reptiles in Europe, were analyzed by FPLC, 2-D electrophoresis, sequence analysis, and MS/MS. FPLC analysis showed the presence of l-amino acid oxidase, monomeric and heterodimeric phospholipases A2, C-type lectin protein, and proteinases in the venom of V. a. ammodytes. Representatives of the same protein families were found in the venom of the other subspecies, V. a. meridionalis. N-terminally identical PLA2 neurotoxins were identified in both venoms. Difference in the PLA2 compositions of the venoms was also observed: a monomeric protein with phospholipase A2 activity, identical in the first 20 amino acid residues to the catalitically inactive acidic component of the heterodimeric PLA2 present in both venoms, was found only in that of V. a. meridionalis. Probably, this protein represents an intermediate form of the two components of the heterodimer. 2-D electrophoresis and MS/MS analysis showed that the two venoms shared a number of protein families: monomeric and heterodimeric Group II PLA2s, serine proteinases, Group I, II, and III metalloproteinases, l-amino acid oxidases (LAAOs), cysteine-rich secretory proteins, disintegrins, and growth factors. Totally, 38 venom components of the V. a. ammodytes, belonging to 9 protein families, and 67 components of the V. a. meridionalis venom belonging to 8 protein families were identified. The venom proteome of V. a. ammodytes shows larger diversity of proteins (139) in comparison to that of V. a. meridionalis (104 proteins). Most of the proteins are homologues of known representatives of the respective protein families. The protein compositions explain clinical effects of the V. ammodytes snakebites, such as difficulties in the breathing, paralysis, apoptosis, cloting disorders, hemorrhage, and tissue necrosis. The lists of secreted proteins by the two vipers can be used for further study of structure-function relationships in the toxins and for prediction and treatment of snakebite consequences.     

Amino-acid sequence of ammodytoxin B partially reveals the location of the site of toxicity of ammodytoxins

The complete amino-acid sequence of ammodytoxin B, a presynaptically toxic phospholipase A2 isolated from Vipera ammodytes ammodytes venom, was determined by manual and automated protein sequencing. Ammodytoxin B (i.v. LD50 = 0.58 mg/kg for white mice) is 30-fold less toxic than ammodytoxin A, the most toxic phospholipase isolated from the same venom. The two proteins (each 122 residues long) differ in only 3 residues located in positions 115, 118 and 119 (numbering according to R. Renetseder et al. (1985) J. Biol. Chem. 260, 11627-11634) suggesting that an exposed hydrophobic residue in position 115 and a basic residue in position 118 may be responsible for the increased toxicity of ammodytoxin A and should form at least one part of the site of toxicity in ammodytoxins.     

Enzymatic activity and inhibition of the neurotoxic complex vipoxin from the venom of Vipera ammodytes meridionalis

Vipoxin from the venom of Vipera ammodytes meridionalis is an unique neurotoxic complex between a toxic phospholipase A2 and a highly homologous non-toxic protein inhibitor. It is an example of evolution of a catalytic and toxic function into inhibitory and non-toxic one. The activity of the V. ammodytes meridionalis toxin is 1.7 times higher than that of the closely related (92% sequence identity) neurotoxic complex RV4/RV7 from the venom of Vipera russelli formosensis The enhanced enzymatic activity of vipoxin is attributed to limited structural changes, in particular to the substitutions G54R and Q78K in the PLA2 subunit of the complex and to the T54R substitution in the inhibitor. Oleyloxyethylphosphocholine, aristolochic acid and vitamin E suppressed the enzymatic activity of vipoxin and its isolated PLA2 subunit. These compounds influence inflammatory processes in which PLA2 is implicated. The peptide Lys-Ala-Ile-Tyr-Ser, which is an integral part of the PLA2 components of the two neurotoxic complexes from V. ammodytes meridionalis and V. russelli formosensis (sequence 70-74) activated vipoxin increasing its PLA2 activity by 23%. This is in contrast to the inhibitory effect of the respective pentapeptides with 70-74 sequences on other group II PLA2s. Surprisingly, the same peptide inhibited 46% of the V. russelli formosensis PLA2 activity. The limited changes in the structure of the two highly homologous neurotoxins lead to considerable differences in their interaction with native peptides.     

Properties of phospholipase A2 from the venom of the large hornet Vespa orientalis

Some properties (catalytic and hemolytic activity, pH and temperature optima, stability, substrate specificity, effects of detergents and metal ions, N-terminal sequence, chemical modification of histidine in the enzyme active center, etc.) of phospholipase A2 from hornet (Vespa orientalis) venom were studied. It was shown that phospholipase A2 from hornet venom differs essentially from other enzymes of this species in terms of stability, catalytic properties and structural features. The active center of the enzyme contains an essential histidine residue, similar to other phospholipases A2 from various sources. Unlike other known forms of phospholipase A2, the enzyme under study exerts a pronounced hemolytic action. The hemolysis is inhibited by Ca2+ at concentrations capable of inducing the activation of the hydrolytic activity of the enzyme.     

The variability of Vipera ammodytes ammodytes venoms from Croatia--biochemical properties and biological activity

Vipera ammodytes ammodytes venom has been used for many years in Croatia for immunization of horses and production of specific therapeutic anti-venoms. The neutralizing effectiveness of anti-venoms is directly dependent on the properties of the snake venom used for immunization. Therefore, appropriate characterization of the whole venom is necessary prior to use in the immunization procedure. In the course of such analyses, the variability in biochemical properties and biological activity was observed in venoms collected from snakes originating from different parts of Croatia. The venom pools also differed with respect to time of snake collection (1992-2003). Analyses of three samples of whole venom pools were carried out revealing differences in lethal activity (LD50), minimum haemorrhagic dose (MHD), minimum necrotizing dose (MND), phospholipase A2 activity and in anticomplementary activity. SDS-PAGE electrophoretic patterns were similar, but not identical, for all tested venom pools with respect to the number of protein bands detected, but intensity of particular components differed. Preliminary immunogenicity testing in terms of determination of specific antibodies revealed similar immunogenicity and high cross-reactivity for three samples tested.     

The role of antibodies specific for toxic sPLA2s and haemorrhagins in neutralizing potential of antisera raised against Vipera ammodytes ammodytes venom

The contribution of antibodies directed against the two main toxic groups of proteins in the Vipera ammodytes ammodytes venom, haemorrhagic metalloproteinases (H) and neurotoxic sPLA2s (Atxs), to the overall protective efficacy of the whole venom antisera was investigated. Using ELISA assays we established a high correlation between the protective efficacy of the whole venom antisera in mice and their anti-Atxs antibody content. As the haemorrhage is the prevailing toxic effect of the venom in human, the lack of correlation also with anti-H IgG content exposed that the mouse model might not be optimal to evaluate the neutralizing potential of the venom-specific antisera for human therapy. We further revealed that Atxs and structurally very similar but non-toxic AtnI2 from the venom are not immuno cross-reactive.     

Intraspecies variability in Vipera ammodytes ammodytes venom related to its toxicity and immunogenic potential

Vipera ammodytes is the most venomous European snake, whose venom has been used as antigen for immunization of antivenom-producing animals. Same as venom of any other snake, it is a complex mixture of proteins, peptides and other compounds which biochemical and pharmacological variability has been demonstrated at interspecies and intraspecies level. In this work we demonstrated intraspecific variability between 8 venom production batches using both the conventional and the new methodology. Moreover, in contrast to the literature on different venoms' variability, for the first time we were able to select those biochemical differences that are related to and give information on the venom's toxicity and immunogenicity. We have shown that methods quantifying ammodytoxin (the most toxic compound identified so far in the Vipera ammodytes ammodytes venom) content of the venom clearly distinguish between high and low immunogenic venoms.     

Group IB phospholipase A2 from Pseudonaja textilis

Pseudonaja textilis, an Australian Elapid, is known to produce a highly toxic venom. Both protein profiling and N-terminal sequence analysis showed the presence of four new phospholipases A(2) in this venom. Besides being non-lethal, the phospholipase A(2) proteins were found to be moderately active enzymes and they showed procoagulant property. cDNA cloning and characterization indicated the presence of two isoforms of PLA(2) proteins in a single snake, each containing the "pancreatic loop," characteristic of group IB phospholipase A(2). The genomic cloning also confirmed the presence of two genes each containing four exons that are interrupted by three introns. Phylogenetic analysis showed that the venom group IB PLA(2) gene is primitive and could have evolved from the same ancestor as the mammalian and venom group IA PLA(2) genes. In the present study, we report that the Pt-PLA2 gene could be responsible for the production of PL1, 2, and 3 possibly via RNA editing process.     

Crystallization and preliminary X-ray diffraction studies of a toxic phospholipase A2 from the venom of Vipera ammodytes meridionalis complexed to a synthetic inhibitor

A toxic phospholipase A(2) (PLA(2)) is isolated from the neurotoxic complex Vipoxin, the major lethal component of the venom of Vipera ammodytes meridionalis. The enzyme is complexed to the synthetic inhibitor elaidoylamide and crystallized. The crystals belong to the space group P2(1)2(1)2(1), with unit cell dimensions a=46.57 A, b=82.68 A, c=119.47 A and beta=90 degrees. Initial diffraction data to 3.3 A resolution are collected.     

The X-ray structure of a snake venom Gln48 phospholipase A2 at 1.9A resolution reveals anion-binding sites

Phospholipase A2 is an "interfacial" enzyme and its binding to negatively charged surfaces is an important step during catalysis. The Gln48 phospholipase A2 from the venom of Vipera ammodytes meridionalis plays the role of chaperone and directs a toxic His48 PLA2 onto its acceptor. In the venom the two phospholipases A2 exist as a postsynaptic neurotoxic complex, Vipoxin. The X-ray structure of Gln48 PLA2, complexed to sulphate ions, which mimic the negatively charged groups of anionic membranes, has been determined by the molecular replacement method and refined to 1.9A resolution. The protein forms a homodimer stabilized by ionic, hydrophobic, and hydrogen-bond interactions. The structure reveals two anion-binding sites per subunit. These sites are probably involved in interactions with the negatively charged membrane surface and, in this way, in the "targeting" of the toxic component to the receptors of the postsynaptic membranes. In the absence of the chaperone subunit the toxin changes the target of the physiological attack. A comparison of the homodimeric Gln48 PLA2 structure with that of the heterodimeric Vipoxin reveals differences in regions involved in the pharmacological activity of the toxin. This fact, except the active site histidine substitution, can explain the absence of toxicity in the Gln48 protein in comparison to the His48 phospholipase A2.     

A high affinity acceptor for phospholipase A2 with neurotoxic activity is a calmodulin

One of the high affinity binding proteins for ammodytoxin C, a snake venom presynaptically neurotoxic phospholipase A(2), has been purified from porcine cerebral cortex and characterized. After extraction from the membranes, the toxin-binding protein was isolated in a homogenous form using wheat germ lectin-Sepharose, Q-Sepharose, and ammodytoxin-CH-Sepharose chromatography. The specific binding of (125)I-ammodytoxin C to the isolated acceptor was inhibited to different extents by some neurotoxic phospholipases A(2), ammodytoxins, bee venom phospholipase A(2), agkistrodotoxin, and crotoxin; but not by nontoxic phospholipases A(2), ammodytin I(2), porcine pancreatic phospholipase A(2), and human type IIA phospholipase A(2); suggesting the significance of the acceptor in the mechanism of phospholipase A(2) neurotoxicity. The isolated acceptor was identified as calmodulin by tandem mass spectrometry. Since calmodulin is generally considered as an intracellular protein, the identity of this acceptor supports the view that secretory phospholipase A(2) neurotoxins have to be internalized to exert their toxic effect. Moreover, since ammodytoxin is known to block synaptic transmission, its interaction with calmodulin as an acceptor may constitute a valuable probe for further investigation of the role of the latter in this Ca(2+)-regulated process.     

Isolation and preliminary characterisation of two toxic phospholipases A2 from the venom of the Malayan cobra (Naja naja sputatrix)

Two toxic phospholipases A have been isolated from the venom of the Malayan cobra (Naja naja sputatrix). The phospholipases A were purified by successive ion-change chromatography on SP-Sephadex C-25, Sephadex G-75 gel filtration chromatography and successive Bio-Rex 70 ion-exchange chromatography. The purified toxic phospholipases A were homogeneous electrophoretically. They were designated as sputatrix phospholipase A-I and sputatrix phospholipase A-II. Positional specificity studies showed that they belong to the A₂-type phospholipase A. The medium lethal dose 50% (LD₅₀) values of the two phospholipases A are 0.27 and 0.28 μg/g, respectively, by intravenous injection and 1.05 and 1.00 μg./g, respectively, by intraperitoneal injection. The molecular weights of the two enzymes are 14 000 as determined by gel-filtration chromatography and SDS-polyacrylamide gel electrophoresis. Amino acid composition of sputatrix phospholipase A-I differs from sputatrix phospholipase A-II only by having one extra amino acid: a glutamic acid. Amino acid compositions of the two enzymes are also similar to those of other cobra venom phospholipases A.     

The amino acid region 115-119 of ammodytoxins plays an important role in neurotoxicity

Quadruple (Y115K/I116K/R118M/N119L) and double (Y115K/I116K) mutants of ammodytoxin A, a presynaptically toxic phospholipase A(2) from Vipera ammodytes ammodytes venom, were prepared and characterized. The enzymatic activity of the quadruple mutant on phosphatidylcholine micelles was threefold higher than that of AtxA, presumably due to higher phospholipid-binding affinity, whereas the activity of the double mutant was twofold lower. The substantial decrease by more than two orders of magnitude in the lethal potency of both mutants, together with their decreased binding affinity for neuronal receptors, indicates involvement of the amino acid region 115-119 in neurotoxicity. The similar decrease of toxicity for the two mutants points to the importance of the residues Y115 and I116.     

The primary structure of ammodytin L, a myotoxic phospholipase A2 homologue from Vipera ammodytes venom.

A new myotoxic phospholipase A2 homologue, having a serine residue in position 49 instead of highly conserved aspartic acid, was found in the venom of Vipera ammodytes. The primary structure revealed additional mutations in the positions important for enzymatic activity. Tyr28 is exchanged for a histidine and Gly33 for asparagine. These changes render earlier-reported weak enzymatic activity unlikely. The role of this rather abundant venom fraction is apparently in myotoxicity, which was confirmed in the muscle-cell culture from neonatal rats. The muscle-cell culture proved to be a good tool to investigate the effects of various myotoxins on muscle cells.     

The relationship between high-affinity noncatalytic binding of snake venom phospholipases A2 to brain synaptic plasma membranes and their central lethal potencies

The basic phospholipase A2 from Naja nigricollis (African spitting cobra) snake venom is enzymatically less active but more toxic than the acidic phospholipase A2 from Naja naja atra (Taiwan cobra) snake venom, following injection into the right lateral ventricle of the brain of rats. When radiolabeled with 125I, these phospholipases A2 retained enzymatic activities and lethal potencies. Both enzymes bound with high affinity and specificity to brain synaptic plasma membrane preparations in vitro even in the absence of calcium, suggesting a non-catalytic binding. The acidic enzyme, in a calcium-free medium, had two binding components with Kd values of 1 X 10(-10) and 2.75 X 10(-8) M and Bmax values of 6 X 10(-13) and 3.4 X 10(-11) mol/mg, respectively. Multiple specific and nonspecific binding components were observed for each phospholipase A2; saturability for all of the binding sites was conclusively demonstrated only for the N. naja atra phospholipase A2 in a calcium-free medium (Bmax = 3.4 X 10(-11) mol/mg). The levels of specific and total binding were 150 pmol/mg and 450 pmol/mg, respectively, for the comparatively toxic enzyme and 15 pmol/mg and 35 pmol/mg, respectively, for the comparatively nontoxic enzyme at a concentration of 2.5 X 10(-8) M. These levels of binding (both total and specific) were directly correlated with the intraventricular lethal potencies of the phospholipases A2 (0.5 and 5.0 micrograms/rat for the N. nigricollis and N. naja atra phospholipases A2, respectively), suggesting a possible relationship between binding and lethal potency. Carbamylation of lysines reduced the levels of binding and the lethal potencies of both enzymes to a greater extent than their enzymatic activities. Pretreatment with high temperature, proteinases, phospholipases A2 or C suggested that radiolabeled phospholipase A2 binds to phospholipids rather than proteins. However, only the N. naja atra phospholipase A2 manifested a strict dependence on a divalent cation (Ca2+ or Sr2+) for most of its binding. The N. nigricollis enzyme demonstrated a much lower rate of dissociation from synaptic plasma membranes than did N. naja atra phospholipase A2, suggesting that hydrophobic interactions are more important in the binding of the more toxic enzyme as compared to the less toxic enzyme. It is proposed that differences in the extent of high-affinity noncatalytic binding to membrane phospholipids may be at least partly responsible for the marked difference in central toxicities of these two phospholipases A2.