Toxins from Mamba Venoms that Facilitate Neuroiluscular Transmission

Nanoporous gold electrode for ultrasensitive detection of neurotoxin fasciculin

Acetylcholinesterase (AChE), an efficient biocatalyst known to hydrolyze the neurotransmitter acetylcholine, could be inactivated in the presence of insecticides, nerve agents or other drug inhibitors to thus result in disrupted neurotransmission. Improvement in the peripheral cholinergic function, as well as overall cognition and neuronal functions of an exposed system could be achieved if the mechanisms of inhibitions are deactivated in a controlled fashion and with rapid response time. Herein, we proposed to develop a simple AChE biosensor capable to realize the rapid detection of neurotoxins. Our approach uses a nanoporous gold film (NPGF) and reduced graphene oxide-tin dioxide nanoparticle (RGO-SnO₂) nanocomposite to define the highly active electrode interface where the electrochemical monitoring of the interaction between AChE and its target molecule, fasciculin, could take place. Our results demonstrate that the established biosensor had the ability to monitor fasciculin concentrations at the ultra-low limit of detection of 8 pM, an inhibition rate of 8% and within only 30min of electrochemical exposure. Our study provides a convenient technology for the rapid and ultrasensitive detection of neurotoxins and has the potential for large applicability to other drugs or toxins screening.

Toxins and drug discovery

Components from venoms have stimulated many drug discovery projects, with some notable successes. These are briefly reviewed, from captopril to ziconotide. However, there have been many more disappointments on the road from toxin discovery to approval of a new medicine. Drug discovery and development is an inherently risky business, and the main causes of failure during development programmes are outlined in order to highlight steps that might be taken to increase the chances of success with toxin-based drug discovery. These include having a clear focus on unmet therapeutic needs, concentrating on targets that are well-validated in terms of their relevance to the disease in question, making use of phenotypic screening rather than molecular-based assays, and working with development partners with the resources required for the long and expensive development process.

Twenty years of dendrotoxins

Dendrotoxins are small proteins that were isolated 20 years ago from mamba (Dendroaspis) snake venoms (Harvey, A.L., Karlsson, E., 1980. Dendrotoxin from the venom of the green mamba, Dendroaspis angusticeps: a neurotoxin that enhances acetylcholine release at neuromuscular junctions. Naunyn-Schmiedebergs Arch. Pharmacol. 312, 1-6.). Subsequently, a family of related proteins was found in mamba venoms and shown to be homologous to Kunitz-type serine protease inhibitors, such as aprotinin. The dendrotoxins contain 57-60 amino acid residues cross-linked by three disulphide bridges. The dendrotoxins have little or no anti-protease activity, but they were demonstrated to block particular subtypes of voltage-dependent potassium channels in neurons. Studies with cloned K(+) channels indicate that alpha-dendrotoxin from green mamba Dendroaspis angusticeps blocks Kv1.1, Kv1.2 and Kv1.6 channels in the nanomolar range, whereas toxin K from the black mamba Dendroaspis polylepis preferentially blocks Kv1.1 channels. Structural analogues of dendrotoxins have helped to define the molecular recognition properties of different types of K(+) channels, and radiolabelled dendrotoxins have also been useful in helping to discover toxins from other sources that bind to K(+) channels. Because dendrotoxins are useful markers of subtypes of K(+) channels in vivo, dendrotoxins have become widely used as probes for studying the function of K(+) channels in physiology and pathophysiology.

m1-toxin isotoxins from the green mamba (Dendroaspis angusticeps) that selectively block m1 muscarinic receptors

The venom of the green mamba, Dendroaspis angusticeps, was found to have at least six trace m1-specific toxins that block the binding of 3H-N-methylscopolamine to cloned m1 muscarinic receptors. Four were isolated by gel filtration, cation exchange HPLC and reversed-phase HPLC and named m1-toxins1-4. Recovery was 180, 90, 20 and 10 microg/g dry venom, respectively. m1-Toxin1 (the original m1-toxin) was found to have the sequence, L T C V K S N S I W F P T S E D C P D G Q N LC F K R W Q Y I S P R M Y D F T R G C A A T C P K A E Y R D V I N C C G T D K C N K, calculated mass = 7473 Da and calculated pI = 8.2. This sequence had been predicted previously from a cDNA cloned from the venom glands of this snake. The binding of m1-toxin1 was irreversible, so its Kd could not be determined. m1-Toxin2 differed only in proline-19, mass = 7455 and pI = 8.5. Partial sequence data for m1-toxin3 showed aspartate-7 and m1-toxin4 showed isoleucine-12, asparagine-16 and alanine-19. m1-Toxins1-4 have seven conserved amino acids not found in homologous mamba toxins that bind to other muscarinic receptors (MT1, MT2, m4-toxin = MT3, MT4, MT5, MTalpha and MTbeta). Some of these residues may be essential for m1-specificity. Since m1-toxin1 binds irreversibly in artificial cerebrospinal fluid at 37 degrees C, it is a particularly attractive antagonist for studies in vivo.

m2-toxin: A selective ligand for M2 muscarinic receptors

Selective ligands are needed for distinguishing the functional roles of M2 receptors in tissues containing several muscarinic receptor subtypes. Because the venom of the green mamba Dendroaspis angusticeps contains the most specific antagonists known for M1 and M4 receptors (m1-toxin and m4-toxin), it was screened for toxins that inhibit the binding of [(3)H]N-methylscopolamine ([(3)H]NMS) to cloned M2 receptors. Desalted venom had as much anti-M2 as anti-M4 activity. The most active anti-M2 toxin in the venom was isolated by gel filtration, cation-exchange chromatography, and reversed-phase HPLC, and called m2-toxin. Spectrometry yielded a mass of 7095 Da, and N-terminal sequencing of 53 amino acids showed RICHSQMSSQPPTTTFCRVNSCYRRTLRDPHDPRGT-IIVRGCGCPRMKPGTKL. This sequence is more homologous to antinicotinic than antimuscarinic toxins, but it lacks three almost invariant residues of antinicotinic toxins required for their activity. m2-Toxin fully blocked the binding of [(3)H]NMS and [(3)H]oxotremorine-M to M2 receptors with Hill coefficients near 1, and blocked 77% of the binding sites for 0.1 nM [(3)H]NMS in the rat brainstem (K(i) = 11 nM). Concentrations that fully blocked cloned M2 receptors had no effect on M4 receptors, but slightly increased [(3)H]NMS binding to M1 receptors, an allosteric effect. In accord with these results, light microscopic autoradiography of the rat brain showed that m2-toxin decreased [(3)H]NMS binding in regions rich in M2 receptors and increased binding in regions rich in M1 receptors. Thus m2-toxin is a novel M2-selective, short-chain neurotoxin that may prove useful for binding and functional studies.

Structure-activity relationships of calcicludine and dendrotoxin-I, homologous peptides acting on different targets, calcium and potassium channels

Calcicludine (CaC) and dendrotoxin-I (DTX-I) possess high homology of their primary structures despite their different biological activities acting on calcium and potassium channels, respectively. In order to elucidate the channel specificity displayed by these toxins, their three-dimensional structures were compared by NMR. These analyses revealed that their overall conformations are similar except for the structure at the N-terminus. To demonstrate the significance of this N-terminal, chimeric peptides, CaC(1-30)/DTX-I(31-60) and DTX-I(1-30)/CaC(31-60), were synthesized. The CD spectra and receptor-binding measurements of chimeric peptides indicated that the contribution to the overall conformation and to the affinity of the N-terminal part of molecule seem to be more important than that of the C-terminal one. These results suggest that the N-terminal part may participate in distinguishing between calcium and potassium channels.

Site-directed mutagenesis of dendrotoxin K reveals amino acids critical for its interaction with neuronal K+ channels

Dendrotoxin K (DTXK) is a 57-residue protein from mamba venom that blocks certain non-inactivating, voltage-activated K+ currents in neurones. In order to pinpoint the residues responsible for its specificity, structure-activity relations of DTX(K) were investigated by mutagenesis. A previously cloned gene encoding this toxin [Smith et al. (1993) Biochemistry 32, 5692-5697] was used to make single mutations; after expression in Escherichia coli as fusion proteins and enzymatic cleavage of the conjugates isolated from the periplasmic space, nine toxins were purified. Structural analysis of the native DTXK and representative mutants by circular dichroism showed that no significant differences were detectable in their folded structures. The biological activity of the mutants, which contained alterations of positively charged and other amino acids, was determined from their abilities to compete for the binding of 125I-labeled DTX(K) to K+ channels in synaptic plasma membranes from rat cerebral cortex. Mutants with residues substituted in the alpha-helix near the C-terminus (R52A or R53A) yielded binding parameters similar to those of wild-type and native DTX(K). In the case of the beta-turn (residues 24-28), however, altering single amino acids reduced binding to the high-affinity site of K+ channels, with the rank order of decreases being K26A >> W25A > K24A = K28A. Also, substitutions made in the 3(10)-helix (residues 3-7), a region located close to the beta-turn, produced equivalent effects (K3A > K6A). Thus, it is deduced that residues in the distorted beta-turn and neighboring 3(10)-helix of DTX(K) are critical for its interaction with neuronal K+ channels.

Characterization of a new family of toxin-like peptides from the venom of the scorpion Leiurus quinquestriatus hebraeus. 1H-NMR structure of leiuropeptide II

To extend our knowledge about the structural features of short scorpion toxins, the ion-exchange fractions obtained from Leiurus quinquestriatus hebraeus venom were investigated by plasma desorption mass spectrometry in order to select low molecular mass polypeptides. Three toxin-like peptides with molecular mass close to 3 kDa, named leiuropeptides I, II and III, were purified and found devoid of any significant toxicity against mammals and insects. Their amino acid sequences revealed a cysteine pattern analogous to that of short-chain scorpion toxins. The solution structure of leiuropeptide II was determined by 2D 1H-NMR spectroscopy and indicated the presence of a helix accommodating a proline, connected to a two-standard beta-sheet by three disulfide bonds. The overall fold of leiuropeptide II is found to be similar to that of leiurotoxin I, a 31-residue toxin present in the same scorpion venom which acts on K+ channels. In order to rationalize the absence of toxicity, the electrostatic potential of leiuropeptide II was compared to that of leiurotoxin I. The peptide is characterized by a large negative zone around Glu4, Asp5 and Asp8 residues, beginning in the neighbourhood of the beta-turn and extending along the helix. In the same area, leiurotoxin I exhibits a positive surface, around Arg6 and Arg13 basic residues, which are essential for its receptor affinity.

Anti-muscarinic toxins from Dendroaspis angusticeps

Toxins from the venom of the African green mamba, Dendroaspis angusticeps, fulfill a major need for selective ligands for some of the five genetically defined subtypes of muscarinic acetylcholine receptors (m1-m5). Two toxins have been found that are highly selective antagonists for m1 and m4 receptors (m1-toxin and m4-toxin, respectively). Two other toxins (MT1 and MT2) bind with high affinity to both m1 and m4 receptors, and are agonists. Components of the venom also modify the binding of radiolabeled antagonists to m2 receptors, but an m2-selective toxin has not yet been isolated, m1-Toxin can bind to m1 receptors at the same time as typical competitive antagonists, suggesting that this toxin binds to the N-terminal and outer loops of m1 receptor molecules, rather than within the receptor pocket where typical agonists and antagonists bind. The binding of toxins to the outer parts of receptor molecules probably accounts for their much higher specificity for individual receptor subtypes than is seen with smaller ligands. Toxins are useful for identifying, counting, localizing, activating and blocking m1 and m4 receptors with high specificity.

Molecular structure, conformational analysis, and structure-activity studies of Dendrotoxin and its homologues using molecular mechanics and molecular dynamics techniques

Three-dimensional structures of Dendrotoxin (DtX), Toxin-I (DpI), and Toxin-K (DpK) were determined using molecular mechanics and molecular dynamics techniques. The overall molecular conformation and protein folding of the three dendrotoxins are very similar to the published crystal structures of bovine pancreatic trypsin inhibitor (BPTI) and alpha-DtX. Major secondary structural regions of the dendrotoxins are stable without much fluctuation during the dynamics simulation; the regions corresponding to the turns and bends (rich in lysines and arginines) exhibit more fluctuations. The conformational angles and the C alpha...C alpha' distances of the three disulfides (in each of the dendrotoxins) are different from each other. Comparative model building studies, involving the dendrotoxins and the proteinases, reveal that the key interactions (observed in BPTI-trypsin complex) needed for anti-protease activity are absent due to structural differences between the dendrotoxins and BPTI at the anti-protease loop; this explains the inability of the dendrotoxins to inhibit proteinases. The model also suggests that the solvent-exposed beta-turn region, rich in lysines (residues 26-28), might bind directly to the extracellular anionic sites of the receptors (K+ channels) by ionic interactions. The strikingly homologous cysteine distribution (Cys-x-x-x-Cys) in DtX, DpI, and DpK, at the C-terminus, induces the occurrence of a characteristic conformational motif, consisting of an alpha-helix (in an amphiphilic environment) stabilized by two disulfides, one involving a cysteine at the beta-strand, and the other at the N-terminus. This amphiphilic secondary structural element seems to provide the rigid frame work needed for exposing the proposed active site region of the dendrotoxins to the anionic sites of the K+ channel receptors.

Muscarinic toxins from the black mamba Dendroaspis polylepis

Three new toxins acting on muscarinic receptors were isolated from the venom of the black mamba Dendroaspis polylepis. They were called muscarinic toxins alpha, beta, and gamma (MT alpha, MT beta, and MT gamma). All of the toxins have four disulphide bonds and 65 or 66 amino acids. The sequences of MT alpha and MT beta were determined. The muscarinic toxins, of which about 12 have been isolated from venoms of green and black mambas, have 60-98% sequence identity with each other, and are similar to many (about 180) other snake venom components, such as alpha-neurotoxins, cardiotoxins, and fasciculins. In contrast to the alpha-neurotoxins, muscarinic toxins do not bind to nicotinic acetylcholine receptors. The binding constants of MT alpha and MT beta were determined for human muscarinic receptors of subtypes m1-m5 stably expressed in Chinese hamster ovary cells. The toxins are less selective than the earlier discovered muscarinic toxins from the green mamba Dendroaspis angusticeps. MT alpha and the muscarinic toxin MT4 from D. angusticeps differ only in a region of three amino acids (residues 31-33), which are Leu-Asn-His in MT alpha and Ile-Val-Pro in MT4. This difference causes a pronounced shift in subtype selectivity. MT alpha has high affinity to all subtypes, with Ki (inhibition constant) values of 23 nM (m1; pKi = 7.64 +/- 0.10), 44 nM (m2; pKi = 7.36 +/- 0.06), 3 nM (m3; pKi = 8.46 +/- 0.14), 5 nM (m4; pKi = 8.32 +/- 0.07), and 8 nM (m5; pKi = 8.09 +/- 0.07). MT4 has high affinity only to m1 (Ki = 62 nM) and m4 (87 nM) receptors, and low (Ki > 1 microM) affinity to m2, m3, and m5. The region at positions 31-33 evidently plays an important role in the toxin-receptor interaction. MT beta has low affinity for m1 and m2 receptors (Ki > 1 microM) and intermediate affinity for m3 (140 nM; pKi = 6.85 +/- 0.03), m4 (120 nM; pKi = 6.90 +/- 0.06), and m5 (350 nM; pKi = 6.46 +/- 0.01). The low affinity of MT beta may reflect a tendency for spontaneous inactivation.

Cloning and expression of mamba toxins

Mamba venoms contain pharmacologically active proteins that interfere with neuromuscular transmission by binding to and altering the normal functioning of neuronal proteins involved, directly or indirectly, with regulating nerve transmission. Of the mamba toxins studied to date, many act on voltage-sensitive K+ channels, nicotinic or muscarinic acetylcholine receptors, or acetylcholinesterase. In an attempt to clone, characterize, and express the genes encoding these toxins, as well as other genes specifying activities not completely elucidated as yet, a cDNA library was constructed from mRNA isolated from the glands of the black mamba. Clones from the library harboring sequences encoding 14 different mamba toxins were isolated and characterized by nucleotide sequence analysis. Genes coding for three proteins, dendrotoxins (DTX) K, I, and E, were expressed as maltose-binding (MBP) fusion proteins in the periplasmic space of Escherichia coli. The DTXK-MBP fusion protein was affinity purified, cleaved from its chaperon, and the recombinant DTXK purified from MBP. Recombinant DTXK was shown to be identical to native DTXK in its N-terminal sequence, chromatographic behavior, convulsion-inducing activity, and binding to voltage-activated K+ channels in bovine synaptic membranes. Computer modeling was employed to create three-dimensional structures of DTXK and DTX1 from the X-ray crystal structure of alpha-DTX utilizing both structural and sequence homologies. Comparisons were made between the three toxins, providing a framework for site-directed mutagenesis.

On the site by which alpha-dendrotoxin binds to voltage-dependent potassium channels: site-directed mutagenesis reveals that the lysine triplet 28-30 is not essential for binding

We constructed a synthetic gene encoding the published amino acid sequence of DTx from Dendroaspis angusticeps, a ligand of voltage-dependent postassium channels that facilitates neurotransmitter release. We expressed it in Escherichia coli as a fusion protein secreted in the culture medium. The recombinant DTx was generated in vitro by chemical treatment and recovered as two isoforms. One of them (rDTx), like the venom toxin, has an N-terminal pyroglutamate whereas the other (rQDTx) has a free N-terminal glutamine. Chromatographic differences between rDTx and natural DTx led us to re-examine the amino acid sequence of natural DTx. In contrast to what was previously published, position 12 was an Asp and not Asn. Despite this difference, rDTx and DTx had similar toxicity in mice and binding affinity to synaptosomes, suggesting that residue 12 is not important for DTx function. Nor is the N-terminal residue implicated in DTx function since rDTx and rQDTx also had similar biological activities. We also synthesized and expressed a mutant of the DTx gene in which the lysine triplet 28-30 was changed into Ala-Ala-Gly. The two resulting recombinant isoforms exhibited only small decreases in biological activity, excluding the possibility that the positively charged lysine triplet 28-30 of DTx is directly involved in the toxin functional site.

Toxins from mamba venoms: small proteins with selectivities for different subtypes of muscarinic acetylcholine receptors

Muscarinic acetylcholine receptors exist as five subtypes that are widely distributed throughout the body. Conventional pharmacological agents are not highly selective for particular subtypes, making investigations on the functional significance of the subtypes difficult. Recent findings indicate that mamba snake venoms contain several small proteins ('muscarinic toxins') that are highly specific for muscarinic receptors, and are discussed in this review by Diana Jerusalinsky and Alan Harvey. Some of these toxins act selectively and irreversibly on individual subtypes of receptor, and some are antagonists, while others activate muscarinic receptors. The toxins should be useful tools in studies of the functions of individual receptor subtypes, and comparisons of their three-dimensional structures should give clues about how selective binding to muscarinic receptor subtypes can be obtained.

Protease inhibitor homologues of dendrotoxin do not bind to dendrotoxin acceptors on synaptosomal membranes or facilitate neuromuscular transmission

The dendrotoxins are a homologous group of potassium channel-blocking polypeptides found in mamba snake venom. They are similar in sequence and structure to Kunitz-type serine protease inhibitors. Modified and native protease inhibitors were assayed for dendrotoxin-like activity using radioligand-binding and twitch tension-recording methods. Despite the large number and high concentration of compounds tested, no protease inhibitor displayed dendrotoxin-like activity. The results indicate that the protease-inhibiting and potassium channel-blocking activities of these two groups of polypeptides are not linked.

Amino acid sequence of a muscarinic toxin deduced from the cDNA nucleotide sequence

We prepared a cDNA library from venom glands of the green mamba Dendroaspis angusticeps. A cDNA clone was isolated using an appropriate nucleotide probe. The nucleotide sequence codes for a 21 residue signal peptide followed by a 65 residue protein having the amino acid sequence of muscarinic toxin 2, as confirmed in the accompanying paper (Karlsson, E., Risinger, C., Jolkkonen, M., Wernstedt, C. and Adem, A.). The cDNA encoding the muscarinic toxin has been compared with those encoding other snake toxins. There are close similarities with short-chain curaremimetic neurotoxins.

Preliminary X-ray analysis of crystals of fasciculin 1, a potent acetylcholinesterase inhibitor from green mamba venom

Fasciculin 1 from Dendroaspis angusticeps has been crystallized by vapour diffusion, in sodium acetate using sodium thiocyanate as precipitant. Tetragonal crystals (space group P4(1)2(1)2 or P4(3)2(1)2) diffract to 1.8 A resolution. The unit cell parameters are a = 40.4 A and c = 81.1 A. We estimated the presence of one molecule in the asymmetric unit.

Cardiotoxicity of Kenyan green mamba (Dendroaspis angusticeps) venom and its fractionated components in primary cultures of rat myocardial cells

The cardiotoxic actions of Kenyan green mamba (Dendroaspis angusticeps) venom have been investigated using primary myocardial cell cultures isolated from neonatal rat hearts. The cardiotoxic actions of the whole venom and its fractionated components were evaluated on the basis of leakage of lactate dehydrogenase (LDH), changes in morphology, cell membrane lysis, decreases in viability and inhibition of spontaneous beating activity. The whole venom caused time- and concentration-dependent arrest of myocardial contraction, leakage of LDH, extensive disruption of cell monolayer, and decreases in viability. The venom was separated into 6 (DaI to DaVI) fractions by gel permeation chromatography on Sephadex G-50. Spontaneous beating activity was abolished by DaI to DaVI at high concentrations, while at lower doses they induced progressive depression of beating frequency after a 3-h treatment period. DaI to DaIV caused significant leakage of LDH, morphological damage, and decreases in viability after a 6-h incubation period. The most cardiotoxic fraction (DaIV), which also contains about 54% of the total protein of the whole venom, was fractionated into 18 polypeptides (Da1 to Da18) by ion exchange chromatography on Bio-Rex 70. On the basis of their ability to abolish myocardial contractility, release LDH, alter cellular structure, lyse cell membranes and reduce viability, the 18 fractions have been divided into 4 arbitrary subgroups of cytotoxins: cardiotoxins, Da1 to Da3; cardiotoxin-like polypeptides, Da4 to Da12, Da14; less active membrane lytic polypeptides, Da13, Da15 to Da17; and membrane lytic polypeptide, Da18. Marked synergistic cell membrane lysis occurred in myocardial cell cultures treated simultaneously with 2 cardiotoxin-like polypeptides, Da7 and Da11. It is suggested that the additive and synergistic cardiotoxic effects of high molecular weight cytotoxic proteins (DaI to DaIII), very low molecular weight cholinomimetic substances (DaV to DaVI) and the 4 subgroups of cardiotoxins may directly contribute to the pronounced cardiovascular problems observed in victims of green mamba bites.

Cardiotoxicity of Jamesoni's mamba (Dendroaspis jamesoni) venom and its fractionated components in primary cultures of rat myocardial cells

Primary cultures of spontaneously beating myocardial cells isolated from neonatal rat hearts were used to screen the cardiotoxic effects of Jamesoni's mamba (Dendroaspis jamesoni) venom and components isolated from the venom by gel filtration and ion exchange chromatography. Cardiotoxicity was evaluated on the basis of leakage of lactate dehydrogenase (LDH), changes in morphology, cell membrane lysis, cellular viability, and alterations in spontaneous beating activity. The whole venom caused dose- and time-dependent leakage of LDH, disruption of the cell monolayer, decreases in viability, and inhibition of beating activity. Gel filtration of the venom yielded eight fractions (DjI to DjVIII). DjI (30 micrograms/ml), DjII (20 micrograms/ml), and DjV (20 micrograms/ml) caused significant (P less than 0.001) leakage of LDH, extensive morphologic damage, and decreases in viability. At lower concentrations DjI to DjVIII caused progressive inhibition of spontaneous beating activity. The main fraction (DjV), which was the most toxic, was further separated into 14 polypeptides (Dj1 to Dj14) by ion-exchange chromatography using Bio-Rex 70. Based on the ability to induce LDH leakage, produce morphologic damage, lyse cell membranes, and arrest beating activity, four categories of polypeptides were identified: cardiotoxins, Dj1 and Dj2; cardiotoxinlike polypeptides, Dj3 to Dj8; less active membrane lytic polypeptides, Dj9 to Dj13; and membrane lytic polypeptide, Dj14.

Toxins from the venom of the green mamba Dendroaspis angusticeps that inhibit the binding of quinuclidinyl benzilate to muscarinic acetylcholine receptors

Two protein toxins that displace the muscarinic antagonist quinuclidinyl benzilate from rat cortex synaptosomal membranes have been isolated from the green mamba (Dendroaspis angusticeps) venom by gel filtration on sephadex G-50, chromatography on the ion-exchangers Bio-Rex 70 and Sulphopropyl-Sephadex C-25 and reversed-phase HPLC. Toxin 1 has 64 amino acids and four disulfides and a formula weight of 7200 and the corresponding values for toxin 2 are 63, 4 and 6840, respectively. Ultracentrifugation gave a molecular weight of 6900 for toxin 1 and 6700 for toxin 2, Quinuclidinyl benzilate that binds to all types of muscarinic cholinergic receptor was displaced to about 50% by both toxins. This partial displacement indicates that the toxins might be specific for one subtype of receptor.

Effects of the potassium channel blocking dendrotoxins on acetylcholine release and motor nerve terminal activity

1. The effects of the K+ channel blocking toxins, the dendrotoxins, on neuromuscular transmission and motor nerve terminal activity were assessed on frog cutaneous pectoris, mouse diaphragm and mouse triangularis sterni nerve-muscle preparations. Endplate potentials (e.p.ps) and miniature e.p.ps were recorded with intracellular microelectrodes, and nerve terminal spikes were recorded with extracellular electrodes placed in the perineural sheaths of motor nerves. 2. Dendrotoxin from green mamba (Dendroaspis angusticeps) venom and toxin I from black mamba (D. polylepis) venom increased the amplitude of e.p.ps by increasing quantal content, and also induced repetitive e.p.ps. 3. Perineural recordings revealed that dendrotoxins could decrease the component of the waveform associated with K+ currents at the nerve terminals, and induce repetitive activation of nerve terminals. 4. In frog motor nerves, dendrotoxins are known to block the fast f1 component of the K+ current at nodes of Ranvier. Blockade of a similar component of the K+ current at motor nerve terminals may be responsible for the effects of these toxins on neuromuscular transmission. 5. Similar conclusions can be drawn from the results obtained from mouse neuromuscular junctions.

Genetic code redundancy and its differential influence on the evolution of protein interiors versus exteriors

The distinctive amino acid compositions of protein exteriors and interiors were compared to the composition bias imposed by genetic code redundancy. It transpired that the synonym allocation is biased more in favour of those residues which are preferred in interiors, and this leads to an average interior residue being more probable and less mutable compared to an exterior residue. The general implications for protein evolution are discussed in association with the known evolutionary behavior of particular protein families. It is suggested that some proteins may have their structural history "fossilised" in their interiors and that the "amino acid" code is in reality a "protein" code.

Structure-function relationships of phospholipases. I: Prediction of presynaptic neurotoxicity

The hydropathic indexes of 24 phospholipases have been calculated from their amino acid sequences. The presynaptic neurotoxic potential of venom phospholipases can be predicted by the use of hydropathy profiles. The presynaptically acting phospholipases have a distinct hydrophobic region around the residues 80-110 which is probably involved in the interaction with the presynaptic membranes. This region is present as a separate helix in the tertiary structure of phospholipases. Such a hydrophobic region is absent in non-neurotoxic phospholipases.

The effects of protease inhibitor homologues from mamba snake venoms on autonomic neurotransmission

Five protease inhibitor homologues isolated from mamba venoms were tested for facilitatory actions on autonomic neurotransmission using isolated smooth muscle preparations. Dendrotoxin from the eastern green mamba (Dendroaspis angusticeps) was the most consistent in augmenting the responses to sympathetic stimulation in vas deferens preparations and to parasympathetic stimulation in chick oesophagus preparations. Toxin I from the black mamba (D. polylepis) venom augmented the neurally evoked responses in vas deferens preparations, and toxin K from the same venom augmented neurally evoked responses in chick oesophagus preparations. Proteins B and E from D. polylepis venom, as well as bovine pancreas trypsin inhibitor, had no significant facilitatory action on either smooth muscle preparation. The mechanism of the augmentation of neurally evoked responses produced by toxin I on vas deferens preparations, and dendrotoxin on chick oesophagus preparations, was investigated using a variety of drugs which interfere with cholinergic and adrenergic transmission. It is concluded that dendrotoxin and toxin I increase evoked transmitter release in the autonomic nervous system by a direct action on nerves.