Snake venom toxins The purification and properties of five non-neurotoxic polypeptides from Naja mossambica mossambica venom

The monolayer technique: a potent tool for studying the interfacial properties of antimicrobial and membrane-lytic peptides and their interactions with lipid membranes

Erudites of the antiquity already knew the calming effect of oil films on the sea waves. But one had to wait until 1774 to read the first scientific report on oil films from B. Franklin and again 1878 to learn the thermodynamic analysis on adsorption developed by J. Gibbs. Then, in 1891, Agnes Pockels described a technique to manipulate oil films by using barriers. Finally, in 1917, I. Langmuir introduced the experimental and theoretical modern concepts on insoluble monolayers. Since that time, and because it has been found to provide invaluable information at the molecular scale, the monolayer technique has been more and more extensively used, and, during the past decade, an explosive increase in the number of publications has occurred. Over the same period, considerable and ever-increasing interest in the antimicrobial peptides of various plants, bacteria, insects, amphibians and mammals has grown. Because many of these antimicrobial peptides act at the cell membrane level, the monolayer technique is entirely suitable for studying their physicochemical and biological properties. This review describes monolayer experiments performed with some of these antimicrobial peptides, especially gramicidin A, melittin, cardiotoxins and defensin A. After giving a few basic notions of surface chemistry, the surface-active properties of these peptides and their behavior when they are arranged in monomolecular films are reported and discussed in relation to their tridimensional structure and their amphipathic character. The penetration of these antimicrobial peptides into phospholipid monolayer model membranes, as well as their interactions with lipids in mixed films, are also emphasized.

Membrane structure and dynamics as viewed by solid-state NMR spectroscopy

The purpose of the present study is the investigation of the structure and dynamics of biological membranes using solid-state nuclear magnetic resonance (NMR) spectroscopy. Two approaches are used in our laboratory. The first involves the measurement of high-resolution 13C and 1H spectra obtained by the magic angle spinning (MAS) technique while the second approach involves the measurement of 31P and 2H powder spectra in static samples. This paper will present some recent results obtained by high-resolution solid-state 1H NMR on the conformation of gramicidin A incorporated in a phosphatidylcholine bilayers. More specifically, we were able to observe changes in the gramicidin spectra as a function of the cosolubilization solvent initially used to prepare the samples. The interaction between lipid bilayers and an anticancer drug derived from chloroethylurea was also investigated using proton NMR spectroscopy. Finally, we have studied the interaction between cardiotoxin, a toxic protein extracted from snake venom, and negatively charged lipid bilayers using 31P solid-state NMR spectroscopy.

Do cardiotoxins possess a functional site? Structural and chemical modification studies reveal the functional site of the cardiotoxin from Naja nigricollis

Examination of the literature has revealed that regarding the amino acid sequences, cardiotoxins constitute a family of homogeneous compounds. In contrast, cardiotoxins appear heterogeneous as far as their biological and spectroscopic properties are concerned. As a result, comparison between these molecules with a view to establishing structure-activity correlations is complicated. We have therefore reviewed recent works aiming at identifying the functional site of a defined cardiotoxin, ie toxin gamma from the venom of the spitting cobra Naja nigricollis. The biological and structural properties of toxin gamma are first described. In particular, a model depicting the 3-dimensional structure of the toxin studied by NMR spectroscopy is proposed. The toxin polypeptide chain is folded into 3 adjacent loops rich in beta-sheet structure connected to a small globular core containing the 4 disulfide bonds. A number of derivatives chemically modified at a single aromatic or amino group have been prepared. The structure of each derivative was probed by emission fluorescence, circular dichroism and NMR spectroscopy. Also tested was the ability of the derivatives to kill mice, depolarize excitable cell membranes and lyse epithelial cells. Modification of some residues in the first loop, in particular Lys-12 and at the base of the second loop substantially affected biological properties, with no sign of concomitant structural modifications other than local changes. Modifications in other regions much less affected the biological properties of the toxin. A plausible functional site for toxin gamma involving loop I and the base of loop II is presented. It is stressed that the functional site of other cardiotoxins may be different.

Differing stabilities of snake venom cardiotoxins in acidic aqueous acetonitrile

1. Although snake venom cardiotoxins constitute a homologous family of proteins, subclasses with different structural and biological properties exist. 2. By using circular dichroism spectroscopy of twelve cardiotoxins belonging to two structural classes and one non-classified group, this investigation indicated that cardiotoxins differ in their stabilities towards denaturation in acidic aqueous acetonitrile, as used in some reversed-phase high performance liquid chromatography separations. 3. It was also shown that cardiotoxins of the structural class II are in general less stable towards this denaturation than class I and non-classified cardiotoxins.

Correlation between the surface hydrophobicities and elution orders of elapid neurotoxins and cardiotoxins on hydrophobic-interaction high-performance liquid chromatography

Hydrophilic and hydrophobic regions were predicted for Elapid neuro- and cardiotoxins. The contribution of these regions to the retention times of neuro- and cardiotoxins on hydrophobic-interaction HPLC was assessed from the known surface accessibilities of amino acid side-chains within these regions. Differences in retention times between neuro- and cardiotoxins on hydrophobic-interaction HPLC could be attributed to differences in hydrophobicity of regions 6-12 and 22-26 between these two types of toxins. Smaller differences in retention times between cardiotoxins were due to the variable hydrophobicities of regions 1-4 and 26-36.

Snake venom toxins--II. The primary structures of cytotoxin homologues S3C2 and S4C8 from Aspidelaps scutatus (shield or shield-nose snake) venom

1. Cytotoxin homologues S3C2 and S4C8 from Aspidelaps scutatus were purified by gel filtration and ion exchange chromatography. 2. They consist of 63 amino acids including eight half-cystines. The toxicities of S3C2 and S4C8 were determined and LD50 values of 6.6 and 9.4 micrograms/g mouse were, respectively, found. 3. The complete primary structures of toxins S3C2 and S4C8 have been determined. The two toxins resemble the cytotoxin type toxins and in the cytotoxin homologues the ten structurally invariant amino acids of the neurotoxins and the cytotoxins are conserved.

Purification and some properties of low-molecular-weight proteins of Aspidelaps scutatus (shield or shield-nose snake) venom

1. Fourteen low-molecular-weight proteins from Aspidelaps scutatus venom were purified by gel filtration and ion exchange chromatography. 2. The proteins (toxins) have i.v. LD50 values ranging from 0.12 to 54 micrograms/g mouse. 3. The amino-terminal sequences of the proteins show that 12 of the 14 proteins were pure. 4. The proteins were preliminarily assigned as phospholipases A2, long neurotoxins and cytotoxin homologues.

Reversed-phase and hydrophobic-interaction high-performance liquid chromatography of elapid cardiotoxins

The separation of proteins by hydrophobic-interaction HPLC and reversed-phase HPLC depends upon differences in the hydrophobicity of accessible surface groups. The elution order of a group of snake venom cardiotoxins was found to vary between these two HPLC methods. Circular dichroism spectroscopy showed that the eluant acetonitrile-trifluoroacetic acid used for reversed-phase HPLC altered the conformation of the toxins, whereas the salt-buffer eluting medium used for hydrophobic-interaction HPLC did not affect toxin conformation. The retention times of cardiotoxins on reversed-phase HPLC are therefore influenced by their conformational instability in the eluting medium which causes partial or complete unfolding. Hydrophobic interaction is clearly the preferred method with which to correlate the "surface hydrophobicity" of cardiotoxins and their biological effects.

Characterization of elapidae snake venom components using optimized reverse-phase high-performance liquid chromatographic conditions and screening assays for alpha-neurotoxin and phospholipase A2 activities

The vast majority of Elapidae snake venoms, genus Naja, includes three classes of toxic polypeptides: alpha-neurotoxins, phospholipases A2, and cardiotoxins. A new experimental approach using reverse-phase high-performance liquid chromatography in particular has been developed, allowing their respective resolution, identification, and quantitation from milligram quantities of venom. First, definition of optimal chromatographic conditions for Naja mossambica mossambica toxins has been ascertained. Different column packing and solvent systems were compared for their efficiency, with particular attention to the ionic strength of the aqueous solvent. A medium-chain alkyl support (octyl) in conjunction with a volatile ammonium formate (0.15 M, pH 2.70)/acetonitrile solvent system was found to be particularly effective. All the components known until now from this venom could be resolved in a single step, and the elution order was alpha-neurotoxins, phospholipases A2, and cardiotoxins with a total recovery of absorbance and toxicity. Then, with these suitable conditions, we describe a new major cardiotoxin molecule in this venom by hydrophobic and not ionic-charge discrimination. Second, specific assays were designed to detect alpha-neurotoxin and phospholipase A2 activities in chromatographic fractions: alpha-neurotoxin activity was determined by competition for the binding of a radiolabeled alpha-neurotoxin to the acetylcholine receptor of the ray electric organ, and phospholipase A2 activity was defined by the enzymatic activity of these toxins with a fluorescent phospholipid as substrate. Finally, the applicability of these new methods to study other Naja snake venoms was demonstrated.

Preparation and characterization of monoclonal antibody specific for Naja nivea cardiotoxin VII1

Monoclonal antibodies against Naja nivea cardiotoxin VII1 were produced using the hybridoma technique. The antibodies of two clones were found to be identical by an avidity test, isoelectric focusing and immunodiffusion typing assay. The monoclonal antibody was focused at a pH range of 7.4-8.1 and belonged to the mouse sub-class IgG1. A dissociation constant of 0.26 nM demonstrated its high affinity to cardiotoxin. The monoclonal antibody had no effect on cardiotoxin lethality or lysis of red blood cells by the toxin and could therefore be assumed to bind to an antigenic site separate from the active centre.

Lethal potency in mice of toxins from scorpion, sea anemone, snake and bee venoms following intraperitoneal and intracisternal injection

The lethal potency of 29 toxins from scorpion, sea anemone, snake and bee venoms was studied. Lethality following intracisternal injection of these toxins is considerably higher than following i.p. injection (except for the snake neurotoxins). This is of practical interest in the determination of the concentration of active toxins in a solution when only small amounts are available, as in the case of radiolabelled toxins.

Isolation of rhodopsin by the combined action of cardiotoxin and phospholipase A2 on rod outer segment membranes

Freeze-fracture electron microscopy was used to follow morphological changes induced by Naja mossambica mossambica venom VII4 cardiotoxin in rod outer segment membrane preparations. The extent of the morphological changes depend on the purity of the cardiotoxin. Pure cardiotoxin had no detectable effect upon the preparation, but, when contaminated with venom phospholipase A2, led to a rapid disintegration of the membrane vesicles. With trace amounts (up to about 0.5% of the cardiotoxin) of phospholipase A2, the membrane vesicles disintegrated into smooth lamellae and particles in solution. These two components were separated by centrifugation. The pellet, which showed the presence of smooth lamellae and aggregated particles, was composed of unbleached rhodopsin, initial membrane lipids, lysolipids and cardiotoxin. The supernatant, which showed only the presence of dispersed particles, was composed of unbleached rhodopsin, lysolipids and cardiotoxin. With cardiotoxin contained larger amounts of phospholipase A2 (more than 0.5% of the cardiotoxin), membrane vesicles were disintegrated into large aggregates of amorphous material, composed of bleached rhodopsin, initial membrane lipids, lysolipids and cardiotoxin. These results confirm our previous observation on the release of integral membrane proteins from membrane vesicles by the action of cardiotoxin containing traces of phospholipase A2 (Gulik-Krzywicki, T., Balerna, M., Vincent, J.P. and Lazdunski, M. (1981) Biochim. Biophys. Acta 643, 101-114) and suggest it possible use for isolation and purification of integral membrane proteins.

Freeze-fracture study of cardiotoxin action on axonal membrane and axonal membrane lipid vesicles

Freeze-fracture electron microscopy was used to follow morphological changes induced by Naja mossambica mossambica venom cardiotoxins on crab axonal membranes and thier lipids. It was shown that the extent of morphological changes depended drastically on the purity of cardiotoxin preparations and on their nature. Highly purified cardiotoxin induced mainly fusion of membrane or lipid vesicles. The extent of fusion and other morphological changes depended on the nature of cardiotoxin used: VII4 cardiotoxin induced only fusion while VII1 led to further modifications of membranes and liposomes. The most spectacular morphological changes were observed with axonal membranes treated with cardiotoxin containing traces of venom phospholipase A2. At low cardiotoxin concentration (10(-7)-10(-5) M) important intramembrane particle aggregation was observed and at higher concentrations (more than 10(-4) M) intramembrane particles disappeared from the membrane and were found in solution. The membrane vesicles, devoid of intramembrane particles, were observed to fuse rapidly into liposome-like aggregates. These morphological changes are interpreted as being due to the removal of intrinsic membrane proteins from the membrane by the combined action of cardiotoxin and phospholipase A2.

Penetrability of orally toxic protein from cobra venom through the gut of a blowfly

The oral toxicity of a radioiodinated toxic polypeptide isolated from a cobra snake venom as assayed by Sarcophaga falculata blowflies coupled with assays on competitive displacement have indicated that: (a) During 3--4 h 8% of the orally active toxin is able to pass through the digestive system of the fly; (b) the orally active toxin after passing the gut binds to body tissues. The strong affinity of the toxin to tissue membranes explains its absence in the insect's hemolymph following oral applications as well as injection. The removal of traces of phospholipase A, which is extremely toxic, by injection of the orally active toxin has significantly lowered its injection toxicity without affecting its oral toxicity, thus indicating the absence of any interaction with phospholipases in oral toxicity. This conclusion was supported by additional experimentation.

Naja haje haje (Egyptian cobra) venom. Some properties and the complete primary structure of three toxins (CM-2, CM-11 and CM-12)

Three toxins (CM-2, CM-11 and CM-12) were purified from Naja haje haje (Egyptian cobra) venom. Whereas toxin CM-11 contains 65 amino acid residues and five intrachain disulphide bridges, toxin CM-2 and CM-12 comprise, respectively, 61 and 62 residues but both contain four disulphide bridges. The complete primary structures of the three toxins have been established. The sequence and the invarient amino acid residues of CM-2 resemble those of part of a long neurotoxin, a short neurotoxin and a cytotoxin. The sequence of CM-11 reveals that it is a homologue of the neurotoxins and to some extent also a cytotoxin. The immunochemical properties and the sequences of CM-12 suggest that it is related to the cytotoxin group. Further, the sequences of CM-11 and CM-12 from Naja haje haje venom show a high degree of homology with those of the corresponding toxins isolated from NaJA annulifera or NaJA melanoleuca venoms.

Conformation of snake toxic polypeptides studied by a method of prediction and circular dichroism

Short and long neurotoxins as well as cardiotoxins belong to three distinct families of homologous toxic polypeptides extracted from cobra venoms. A study of their conformation was undertaken by using the method of Chou and Fasman for prediction of secondary structures of proteins. To improve the reliability of this method, an averaging scheme was developed. The data obtained showed that all toxins have a predominant trend for beta-sheet nucleation. Moreover, predicted beta-sheet strands fitted well those actually observed from X-ray data. Thus, it seems that all toxins share similarities in their secondary structure. This proposition was supported by a comparative study of the CD spectra of a set of toxins. Nevertheless, the present data suggest also that each type of toxins possesses localized structural individualities which might be responsible for the biological and/or immunological specificities.

Naja mossambica mossambica venom. Purification, some properties and the amino acid sequences of three phospholipases A (CM-I, CM-II and CM-III)

Three phospholipases A, CM-I, CM-II and CM-III, were purified from Naja mossambica mossambica venom by gel filtration on Sephadex G-50 followed by ion-exchange chromatography on CM-cellulose. They comprise each 118 amino acid residues and are close-linked by seven intrachain disulphide bridges. The complete primary structure of the three phospholipases A have been elucidated. The sequences and the invariant amino acid residues of CM-I, CM-II and CM-III resemble those of phospholipases A from other snake venoms and also from porcine pancreas. However, the letality (LD50 values) of the three phospholipases A from Naja mossambica mossambica venom, differ among themselves, and are also much higher than the LD100 value encountered for notexin from Notechis scutatus scutatus venom.

The importance of protein structure and conformation in the preparation of phospholipase-free cardiotoxin from snake venom

Hydrophobic interactions of cobra venom phospholipase A2 (Mr 13 400) in saline with Sephadex gels and its stability towards denaturation in 6 M guanidine-hydrochloride precluded the use of these solvents to remove traces (approx. 0.2%, w/w) of phospholipase A2 from cardiotoxin (Mr 6800) by gel chromatography. Phospholipase-free (less than 0.001%, w/w) cardiotoxin could, however, be obtained by gel chromatography in 8 M urea or 80 mM phenylalanine. Stokes radius and circular dichroism measurements showed that the hydrophobic retardation of phospholipase A2 was abolished but that the hydrodynamic size and conformation of neither protein was affected, thereby facilitating separation.

Snake venom toxins. Purification and properties of low-molecular-weight polypeptides of Dendroaspis polylepis polylepis (black mamba) venom

Twelve low-molecular-weight proteins, of which eleven have subcutaneous LD50 values of less than 40 mug/g mouse, were purified from Dendroaspis polylepis polylepis venom. Ion-exchange chromatography on Amberlite CG-50 and ion-exchange chromatography on carboxymethyl-cellulose and/or phosphocellulose was used for the purification. The amino-terminal sequences of these proteins were determined and used to indicate that five groups of low-molecular-weight polypeptides are to be found in black mamba venom. Proteins from two of these groups which have low toxicity individually, when used together show synergism, in that their toxicity in combination is greater than the sum of their individual toxicities.

Molecular mechanism of cardiotoxin action on axonal membranes

Cardiotoxin isolated from Naja mossambica mossambica selectively deactivates the sodium-potassium activated adenosine triphosphatase of axonal membranes. Tetrodotoxin binding and acetylcholinesterase activities are unaffected by cardiotoxin treatment. The details of association of cardiotoxin with the axonal membrane were studied by following the deactivation of the sodium-potassium activated adenosine triphosphatase and by direct binding measurements with a tritiated derivative of the native cardiotoxin. The maximal binding capacity of the membrane is 42-50 nmol of cardiotoxin/mg of membrane protein. The high amount of binding suggests association of the toxin with the lipid phase of the membrane. It has been shown that cardiotoxin first associates rapidly and reversibly to membrane lipids, then, in a second step, it induces a rearrangement of the membrane structure which produces and irreversible deactivation of the sodium-potassium activated adenosine triphosphatase. Solubilization of the membrane-bound ATPase with Lubrol WX gives an active enzyme species that is resistant to cardiotoxin-induced deactivation. Cardiotoxin binding to the membrane is prevented by high concentrations of Ca 2+ and dibucaine. Although cardiotoxins and neurotoxins of cobra venom have large sequence homologies, their mode of action on membranes is very different. The cardiotoxin seems to bind to the lipid phase of the axonal membrane and inhibits the sodium-potassium activated adenosine triphosphatase, whereas the neurotoxin associates with a protein receptor in the post-synaptic membrane and blocks acetylcholine transmission.

The primary structure of a major polypeptide component from the venom of Naja melanoleuca

The venom of the forest cobra, Naja melanoleuca, contains a number of homologous polypeptides containing between 60 and 71 amino acid resides. The primary structure of a major component (approx. 10% by weight of the crude venom) has been determined unambiguously. The molecule contians 61 amino acid residues and four disulphide bridges. It has not effect on neuromuscular transmission or the excitatory or inhibitory responses to acetylcholine of molluscan neurons. The molecule is similar to, but not identical with, the so-called cytotoxins VII2 and VII3 isolated, by others, from the same venom but reported to be minor components.