Fasxiator, a novel factor XIa inhibitor from snake venom, and its site-specific mutagenesis to improve potency and selectivity

BACKGROUND

Bleeding remains a major limitation of standard anticoagulant drugs that target the extrinsic and common coagulation pathways. Recently, intrinsic coagulation factors are increasingly being investigated as alternative targets for developing anticoagulant drugs with lower bleeding risk.

OBJECTIVES

Goals were to (i) identify novel anticoagulants selectively targeting intrinsic coagulation pathway and (ii) characterize and further improve the properties of the identified anticoagulants.

METHODS AND RESULTS

We have isolated and sequenced a specific factor XIa (FXIa) inhibitor, henceforth named Fasxiator, from the venom of the banded krait snake, Bungarus fasciatus. It is a Kunitz-type protease inhibitor that prolonged activated partial thromboplastin time without significant effects on prothrombin time. Fasxiator was recombinantly expressed (rFasxiator), purified, and characterized to be a slow-type inhibitor of FXIa that exerts its anticoagulant activities (doubled activated partial thromboplastin time at ~ 3 μmol L(-1) ) by selectively inhibiting human FXIa in in vitro assays. A series of mutants were subsequently generated to improve the potency and selectivity of recombinant rFasxiator. rFasxiatorN17R,L19E showed the best balance between potency (IC50 ~ 1 nmol L(-1) ) and selectivity (> 100 times). rFasxiatorN17R,L19E is a competitive slow-type inhibitor of FXIa (Ki  = 0.86 nmol L(-1) ), possesses anticoagulant activity that is ~ 10 times stronger in human plasma than in murine plasma, and prolonged the occlusion time of mice carotid artery in FeCl3 -induced thrombosis models.

CONCLUSION

We have isolated an exogenous FXIa specific inhibitor, engineered it to improve its potency by ~ 1000 times and demonstrated its in vitro and in vivo efficacy. These proof-of-principle data supported the further development of Fasxiator as a novel anticoagulant candidate.

Molecular cloning of the major lethal toxins from two kraits (Bungarus flaviceps and Bungarus candidus)

The major lethal toxins present in the venoms of the red-headed krait, Bungarus flaviceps, and the Malayan krait, Bungarus candidus, have both been purified. Each consists of two polypeptide chains, A and B, joined by a disulfide bond. In the present study, primary structures of these toxins were determined by Edman degradation and by nucleotide sequencing of the cDNA clones. Amino acid sequencing of the N-terminus and enzymatically digested peptides revealed that the A and B chains were highly homologous to those of beta-bungarotoxins (beta-Bgts) from Bungarus multicinctus, respectively. We isolated cDNA clones encoding the A and B chains from both B. flaviceps and B. candidus venom gland cDNA libraries using probes designed based on the cDNA sequence of beta-Bgt from B. multicinctus. Two isoforms of the A chain and one isoform of the B chain were obtained from B. flaviceps, and one isoform of the A chain and two isoforms of the B chain were obtained from B. candidus. Both of the two A chains from B. flaviceps are made up of 119 amino acids and comprise 15 cysteine residues, while the A chains of beta-Bgt from other Bungarus species including B. candidus comprise 13 cysteine residues. The B chains from both species are composed of 59 amino acid residues and comprise seven cysteines. In conclusion, the lethal toxin from B. flaviceps is considered to be a novel isoform of beta-Bgt, which has a different pattern of cysteine residues from known beta-Bgts.

Lys-64 of the A chain is involved in the enzymatic activity and neurotoxic effect of β-bungarotoxin

Two beta-bungarotoxin isotoxins BM12 and BM13 were isolated from Bungarus multicinctus (Taiwan banded krait) venom by sequential chromatography on ion-exchange and reverse phase columns. The two toxins have the same A chain, but different B chains. Different phospholipase A2 activity and different potencies in inhibiting the spontaneous enhancement of spontaneous synaptic current frequency and muscle contraction were observed for BM12 and BM13. Nevertheless, modification of Lys-64 in the A chain of BM12 and BM13 similarly reduced in their phospholipase A2 activity and toxicity. The modified derivatives retained their affinity with Ca2+ and their conformation as deduced by CD. These results suggest that Lys-64 of the A chain is involved in the phospholipase A2 activity and in the neurotoxic effect of beta-bungarotoxin.

Novel neurotoxins from Taiwan banded krait (Bungarus multicinctus) venom: purification, characterization and gene organization

Two novel neurotoxins BM10-1 and BM10-2 were isolated from Bungarus multicinctus (Taiwan banded krait) venom using the combinations of chromatography on a SP-Sephadex C-25 column and a reverse phase HPLC column. BM10-1 contained 66 amino acid residues including 10 Cys residues, while BM10-2 consisted of 65 amino acid residues with 8 Cys residues. The secondary structure of both BM10-1 and BM10-2 was dominated with beta-sheet, but their gross conformation differed as evidenced by CD spectra and acrylamide quenching studies. BM10-1 inhibited carbachol-induced muscle contraction in a reversible manner and the dose for achieving 50% inhibition was approximately fourfold that of alpha-bungarotoxin. BM10-2 exhibited an irreversible but weak inhibition on carbachol-induced muscle contraction. Sequence alignment of neurotoxins with BM10-1 and BM10-2 suggested that the manner in the manifestation of their activity could be partly elucidated by the residues at toxin second loop. The genomic DNAs encoding BM10-1 and BM10-1-like protein (BM10-1L) were amplified by PCR. The two genes shared virtually identical structural organization and high degree of sequence identity with B. multicinctus neurotoxin genes. Compared to intron sequences of these genes, the protein-coding regions were highly variable. The difference between BM10-1 gene and BM10-1L gene notably arose from the third exon. These results suggest the evolution of B. multicinctus neurotoxins via the path of gene duplication.

Identification of alpha-bungarotoxin (A31) as the major postsynaptic neurotoxin, and complete nucleotide identity of a genomic DNA of Bungarus candidus from Java with exons of the Bungarus multicinctus alpha-bungarotoxin (A31) gene

The Malayan krait (Bungarus candidus) is one of the most medically significant snake species in Southeast Asia. No specific antivenom exists to treat envenoming by this species. Death within 30 min after its bite has been reported from Java, suggesting the presence of highly lethal postsynaptic neurotoxins in the venom of these snakes. We purified and identified the major postsynaptic toxin in the venom of B. candidus from Java. The toxin was indistinguishable from alpha-bungarotoxin (A31), a toxin originally isolated from Bungarus multicinctus, in its mass (7983.75 Da), LD50 (0.23 microg/g in mice i.p.), affinity to nicotinic acetylcholine receptors, and by its 40 N-terminal amino acid residues as determined by Edman degradation. Identity with alpha-bungarotoxin was confirmed by cloning and sequencing a genomic DNA from B. candidus which encodes the 74 amino acid sequence of alpha-bungarotoxin (A31) and part of its signal peptide, revealing complete identity to the alpha-bungarotoxin (A31) gene in exon and 98.9% identity in intron sequences. The entire mitochondrial cytochrome b gene of the krait species B. candidus from Java and B. multicinctus from Taiwan was sequenced for comparison, suggesting that these snakes are phylogenetically closely related. alpha-Bungarotoxin appears to be widely present and conserved in Southeast and East Asian black-and-white kraits across populations and taxa.

Crystallization and preliminary X-ray analysis of candoxin, a novel reversible neurotoxin from the Malayan krait Bungarus candidus

Candoxin, a novel three-finger toxin from Bungarus candidus, is a reversible antagonist of muscle (alphabetagammadelta) but a poorly reversible antagonist of neuronal alpha7 nicotinic acetylcholine receptors. It has a molecular weight of 7344 Da, with 66 amino-acid residues including ten half-cystines. The fifth disulfide bridge is located at the tip of loop I (Cys6-Cys11) instead of in loop II as found in other alpha-neurotoxins. Interestingly, candoxin lacks the segment cyclized by the fifth disulfide bridge at the tip of the middle loop of long-chain neurotoxins, which was reported to be critical for binding to alpha7 receptors. As a first step to determining its three-dimensional structure, candoxin was crystallized by the hanging-drop vapour-diffusion technique in conditions around 1.5 M sodium chloride, 10%(v/v) ethanol. The crystals formed belonged to the hexagonal system, space group P6(2)22, with unit-cell parameters a = 54.88, b = 54.88, c = 75.54 A, alpha = beta = 90, gamma = 120 degrees, and diffract to a resolution of 1.80 A. The crystallographic asymmetric unit contains one molecule of candoxin, with an estimated solvent content of 44.6%. Attempts to solve these structures by molecular-replacement methods have not been successful and a heavy-atom derivative search has been initiated.

A pilot experiment for production of Malayan krait antivenom: immunization of rabbits with Bungarus candidus venom

Immunization with Bungarus candidus venom was performed in four rabbits at high dose (initial dose, 75 microg/kg) and low dose (initial dose, 50 microg/kg). Each dose group consisted of two rabbits; one rabbit received the venom subcutaneously (s.c.) and the other intradermally (i.d.). The venom was injected as emulsified solutions with the same volume of Freund's complete adjuvant until the 4th immunization, thereafter as plain solutions. By stepwise increments of the immunizing dose, the higher dose group received a dose of 200 microg/kg and the lower dose group 150 microg/kg after the 5th immunization, respectively. Thereafter, seven additional immunizations were performed within six months. All rabbits were sacrificed two weeks after the last immunization (12th). Antilethal activity of the immunized antisera thus obtained was determined not only with the homologous venom but also with two heterologous venoms from Bungarus fasciatus and Bungarus flaviceps. Immunodiffusion analysis was also performed with these venoms. The results obtained in this pilot trial provided useful information for production of Malayan krait antivenom at Queen Saovabha Memorial Institute.

Muscarinic toxin-like proteins from Taiwan banded krait (Bungarus multicinctus) venom: purification, characterization and gene organization

Two novel proteins, BM8 and BM14, were isolated from Bungarus multicinctus (Taiwan banded krait) venom using the combination of chromatography on a SP-Sephadex C-25 column and a reverse-phase HPLC column. Both proteins contained 82 amino acid residues including 10 cysteine residues, but there were two amino acid substitutions at positions 37 and 38 (Glu37-Ala38 in BM8; Lys37-Lys38 in BM14). CD spectra and acrylamide quenching studies revealed that the gross conformation of BM8 and BM14 differed. In contrast to BM8, BM14 inhibited the binding of [3H]quinuclidinyl benzilate to the M2 muscarinic acetylcholine (mAchR) receptor subtype. Trinitrophenylation of Lys residues abolished the mAchR-binding activity of BM14, indicating that the Lys substitutions at positions 37 and 38 played a crucial role in the activity of BM14. The genomic DNA encoding the precursor of BM14 was amplified by PCR. The gene shared virtually identical structural organization with alpha-neurotoxin and cardiotoxin genes. The intron sequences of these genes shared a sequence identity up to 84%, but the protein-coding regions were highly variable. These results suggest that BM8, BM14, neurotoxins and cardiotoxins may have originated from a common ancestor, and the evolution of snake venom proteins shows a tendency to diversify their functions.

Characterization and gene organization of Taiwan banded krait (Bungarus multicinctus) gamma-bungarotoxin

gamma-Bungarotoxin was isolated from Bungarus multicinctus (Taiwan banded krait) venom using a combination of chromatography on a SP-Sephadex C-25 column and a reverse-phase high-performance liquid chromatography column. Circular dichroism (CD) measurement revealed that its secondary structure was dominant with beta-sheet structure as is that of snake venom alpha-neurotoxins and cardiotoxins. gamma-Bungarotoxin exhibits activity on inhibiting the binding of [3H]quinuclidinyl benzilate to the M2 muscarinic acetylcholine receptor subtype, and competes weakly with radioiodinated alpha-bungarotoxin for binding to the Torpedo nicotinic acetylcholine receptor. Moreover, the toxin inhibits collagen-induced platelet aggregation, with an IC50 of approximately 200 nM. The genomic DNA encoding the gamma-bungarotoxin precursor is amplified by polymerase chain reaction (PCR). The gene is organized with three exons separated by two introns, and shares virtually identical overall organization with those reported for alpha-neurotoxin and cardiotoxin genes, including similar intron insertions. The intron sequences of these genes share sequence identity up to 85%, but the exon sequences are highly variable. These observations suggest that gamma-bungarotoxin, alpha-neurotoxins, and cardiotoxins originate from a common ancestor, and the evolution of these genes shows a tendency to diversify the functions of snake venom proteins.

Isolation of the major lethal toxin in the venom of Bungarus flaviceps

The major lethal toxin in the venom of Bungarus flaviceps has been isolated by ion-exchange chromatography, absorption chromatography and RP-HPLC with a 14-fold purification and an overall yield of 16.5% of the lethal toxicity contained in crude venom. Its sublethal dose (LD(50)) determined in mice weighing 18-20 g was 0.25 (0.19-0.32) microg per mouse. The lethal toxin was pure according to disc- and SDS-PAGE as well as gel HPLC. Its apparent molecular weight determined by SDS-PAGE was 29 kDa. It is a basic protein consisting of two polypeptide chains having apparent molecular weights of 17 and 8 kDa, respectively. The toxin has PLA activity but is free of ACE activity.

Recombinant expression of alpha-bungarotoxin in Pichia pastoris facilitates identification of mutant toxins engineered to recognize neuronal nicotinic acetylcholine receptors

A snake venom-derived alpha-neurotoxin, alpha-bungarotoxin (alphaBgtx), is the classic competitive antagonist of nicotinic acetylcholine receptors (nAChRs). The very high specificity and essentially irreversible binding of alphaBgtx to various nAChRs make alphaBgtx the prime candidate for studying the molecular determinants of specificity for nAChR-ligand interactions. To facilitate site-directed mutagenesis of alphaBgtx for functional analysis, we have developed a recombinant expression system for alphaBgtx using the methylotropic yeast Pichia pastoris. A synthetic gene coding for alphaBgtx was subcloned into an expression vector that directs secretion of the recombinant alphaBgtx (rBgtx) when stably integrated into the yeast genome. Expression of rBgtx was induced by growth of yeast cultures with methanol as the sole carbon source. The activity of the rBgtx in the cell-free medium was measured by competition with 1251-Bgtx for binding to Torpedo nAChR-enriched membranes. The rBgtx, purified to homogeneity by standard HPLC, has the correct predicted amino terminal sequence and molecular mass. Its circular dichroism spectrum is very similar to that of authentic venom-derived alphaBgtx, and the biological activity of the rBgtx is identical to that of authentic alphaBgtx. We have used the Pichia expression system to study a double point mutation of alphaBgtx, rBgtx-K38P/L42Q, that has a high affinity for alpha3beta2 neuronal nAChRs. This is the first demonstration of engineering an alpha-neurotoxin to recognize non-alpha7 neuronal nicotinic receptors.

Looking back on the discovery of alpha-bungarotoxin

This review is a personal narration by a retiring pharmacologist from Taiwan who looks back at his discovery of alpha-bungarotoxin from the historical perspective of Taiwan during the last 50 years, with accounts of his experiences and his efforts to overcome hardship. How the alpha-toxin was isolated and characterized as an irreversible specific nicotinic acetylcholine (ACh) receptor antagonist, and how it subsequently became a useful experimental probe are presented here. The dilemma of differentiating the actions of tubocurarine and alpha-bungarotoxin is analyzed. The author also outlines findings based on work done in his laboratory using alpha-bungarotoxin as a tool on particular aspects of synaptic transmission. These include presynaptic receptor for positive feedback of transmitter release, explosive release of ACh, up- and downregulation of ACh receptors after chronic drug treatment, autodesensitization of junctional ACh receptors, differences in action between natural transmitter and exogenous agonists and that between junctional and extrajunctional ACh receptors. Some experimental pitfalls, in which biomedical scientists are frequently trapped, are raised. Finally, some anecdotes are appended from which the reader may further understand scientific life in the 20th century, including its joys and regrets.

Isolation, purification, crystallization and preliminary X-ray analysis of beta 1-bungarotoxin from Bungarus caeruleus (Indian common krait)

Beta-Bungarotoxin is a heterodimeric neurotoxin consisting of a phospholipase A2 subunit linked by a disulfide bond to a K+ channel binding subunit, which is a member of of the Kunitz protease-inhibitor subfamily. Purified beta1-bungarotoxin was crystallized using microdialysis techniques. The rectangular-shaped crystals are orthorhombic, space group C2221, with unit-cell dimensions a = 80.7, b = 82.5, c = 56.9 A. The crystals have a calculated Vm of 2.35 A3 Da-1 for one molecule in the asymmetric unit. This corresponds to a solvent content of 48%. X-ray intensity data were collected to 2.6 A resolution. The data set is 97.4% complete.

[Solubilization of beta-bungarotoxin-binding protein from rat diaphragm and inhibition of its binding by some other presynaptic neurotoxins]

The mechanism of the transmitter release-blocking action of beta-bungarotoxin at neuromuscular junctions is probably related to the binding of the toxin to a presynaptic voltage-dependent K+ channel. In this paper we report the solubilization of beta-bungarotoxin-binding protein from rat diaphragm membrane preparations with Triton X-100. The specific binding activities of the detergent extracts are 200-400 fmol/mg of protein, and the yields are about 50%-70%. The binding of 125I-beta-bungarotoxin to the extracts could be completely inhibited by dendrotoxin, with an IC50 of about 8 x 10(-8) mol.L. Another beta-neurotoxin, beta-agkistrodotoxin, however, could not inhibit the 125I-beta-bungarotoxin binding at all. This indicates that the acting sites of beta-agkistrodotoxin on the presynaptic membranes are different from those of beta-bungarotoxin.

Resolution of isotoxins in the beta-bungarotoxin family

Although only five isotoxins of the beta-bungarotoxin family had been claimed, this work indicated the existence of more than sixteen isotoxins. Crude snake (Bungarus multicinctus) venom was divided into four main fractions by gel filtration on a Sephadex G-50 column. beta-Bungarotoxin appeared in a major fraction that contained mainly the M(r) 20,000 protein components. The fraction could be further resolved into eighteen peaks designated P1-P18 by HPLC on a Protein Pak SP 5PW column that was eluted with a linear gradient of 0.1-0.6 M CH3COONa in 20 mM NaH2PO4-Na2HPO4 at pH 7.4 P3-P18 were demonstrated to be isotoxins of the beta-bungarotoxin family. Results of protein sequencing for P8, P9 and P11, the three main isotoxins, confirmed that they shared a common phospholipase A2 subunit, which was very similar to although not completely identical with the A1 chain reported previously.

The non-phospholipase A2 subunit of beta-bungarotoxin plays an important role in the phospholipase A2-independent neurotoxic effect: characterization of three isotoxins with a common phospholipase A2 subunit

Three isotoxins (SP I-III) of the beta-bungarotoxin family were purified to homogeneity via a series of isolation procedures including a final step of h.p.l.c. on an SP column washed with a linear gradient of 0.2-0.6 M sodium acetate at pH 7.4. Their proportions varied greatly with the batch of venom. Each isotoxin was demonstrated by SDS/PAGE to contain a phospholipase A2 subunit and a non-phospholipase A2 subunit. The three proteins were reductively alkylated with 4-vinylpyridine and the alkylated derivatives of the two subunits of each isotoxin were separated. N-Terminal sequence analysis of the alkylated derivatives revealed that the three isotoxins probably share a common phospholipase A2 subunit but differ in their non-phospholipase A2 subunits. The non-phospholipase A2 subunits of SP II and SP III were identical with those of beta 2- and beta 1-toxin respectively, except that there was an additional valine inserted between Thr-18 and Val-19 in beta 2-toxin and Pro-18 and Val-19 in beta 1-toxin. The non-phospholipase A2 subunit of SP I differed greatly from that of SP III but was almost identical with that of SP II, except that Lys-14 and Ala-29 in SP II were replaced by Arg-14 and Glu-29 in SP I. Analysis of the effect of CaCl2 on protein fluorescence showed the existence of a low- and a high-affinity site on the different domains of each isotoxin for Ca2+ binding. The three isotoxins showed no great difference in their ability to bind Ca2+ on both the high- and low-affinity site. They had slightly different phospholipase A2 activities but differed to a great extent with respect to their neurotoxic effects. LD50 values increased in the order SP I > SP II > SP III. In contrast, the ability to inhibit the indirectly evoked contraction of chick biventer cervicis muscle was in the order SP III > SP II > SP I.

Functional expression and site-directed mutagenesis of a synthetic gene for alpha-bungarotoxin

In order to explore the structure-function relationships of the curare mimetic alpha-neurotoxins we have constructed and cloned a synthetic gene for Bungarus multicinctus alpha-bungarotoxin which is expressed in Escherichia coli. The recombinant alpha-bungarotoxin is expressed as a fusion protein with alpha-bungarotoxin linked to the COOH-terminal end of the T7 Gene 9-encoded coat protein. After treatment of the fusion protein with Factor Xa protease, a recombinant alpha-bungarotoxin is released that co-migrates with authentic alpha-bungarotoxin upon reverse-phase high performance liquid chromatography and ion-exchange chromatography. Final yields of active recombinant alpha-bungarotoxin were about 0.4 mg/liter of starting bacterial culture. The recombinant alpha-bungarotoxin contains 10 additional residues linked to the NH2-terminal Ile of the alpha-bungarotoxin sequence due apparently to the inaccessibility of the engineered cleavage site to Factor Xa. Nevertheless, the recombinant alpha-bungarotoxin is capable of binding to the nicotinic acetylcholine receptor with an apparent affinity that is only decreased approximately 1.7-fold from that of authentic alpha-bungarotoxin. Alanine substitution of a residue, Asp30, highly conserved among alpha-neurotoxins and previously suggested to play a key role in receptor recognition, resulted in a recombinant alpha-bungarotoxin whose receptor binding activity is indistinguishable from authentic alpha-bungarotoxin.

Separation and characterization of the A chain and B chain in beta 1-bungarotoxin from Bungarus multicinctus (Taiwan banded krait) venom

The interchain disulfide bond between A chain and B chain of beta 1-bungarotoxin (beta 1-Bgt) was selectively cleaved by dithiothreitol, and the A and B chains were separated by HPLC. The separated A and B chains did not show detectable enzymatic activity and lethal toxicity, but exhibited an immunoreactivity with anti-beta 1-Bgt antibody. Analytical isoelectrofocusing revealed that the A chain is a neutral subunit with pI = 7.4, and the B chain is a basic one with pI = 9.6. The A chain exhibited a Ca(2+)-binding ability as revealed by fluorescence measurement. Moreover, fluorescence studies showed that the intact interchain disulfide bond is essential for maintaining the hydrophobic character of substrate binding site in beta 1-Bgt and stabilizing the architectural environment of Trp-19 in the A chain. However, combination of the A chain and B chain failed to restore the biological activities and physiochemical properties which the intact beta 1-Bgt possessed. These, together with our previous result that the Trp-19 of the A chain is involved in substrate binding, suggest that the integrity of the interchain disulfide bond favors the maintenance of the active conformation of beta 1-Bgt.

Evidence for a fast-exchange conformational process in alpha-bungarotoxin

Anomalous behavior of the post-synaptic protein neurotoxin, alpha-bungarotoxin (alpha-bgt), has been observed during reverse-phase HPLC. Purified samples of this toxin from two distinct sources elute from reverse-phase columns as two separate peaks. The protein species represented by these two peaks are in rapid equilibrium, the relative ratio of which displays a pH dependency with a pKa of approximately 3. This equilibrium does not involve the dimerization or aggregation of the toxin and appears to be relatively unique to alpha-bungarotoxin in that similar behavior is not displayed by several other available alpha-neurotoxins. pH-dependent conformational changes have been documented for several alpha-neurotoxins whose crystal structures have been determined (alpha-bungarotoxin, alpha-cobratoxin, and erabutoxin b). One or more of these may account for the observed behavior of alpha-bungarotoxin on reverse-phase HPLC.

Primary structure of an inactive mutant of phospholipase A2 in the venom of Bungarus fasciatus (banded krait)

From the acidic components of Bungarus fasciatus venom, a very small amount (0.16%) of a novel phospholipase A2 was obtained. Both neurotoxicity and enzyme activity were found to be lacking. Amino acid sequence study showed that it has a normal backbone of group I snake venom phospholipase A2 with 118 amino acid residues. The lack of enzyme activity was attributed to its mutation of the indispensable Asp residue to an Ala residue, i.e., the usual His-Asp47 turned out to be His-Ala47. This is the eighth isoform of phospholipase A2 found from the venom of Bungarus fasciatus. Examination of structural homology with three other isoforms revealed 66% similarity at most.

Purification of an active species of recombinant kappa-bungarotoxin

The expression of kappa-bungarotoxin in Escherichia coli from a synthetic gene results in the production of multiple species of polypeptide. These include not only biologically active kappa-bungarotoxin but also a variety of inactive species, which include inactive monomers as well as disulfide-linked polymeric species. Identification of these species and their separation from the biologically active recombinant toxin is necessary for the use of the toxin in physiological and biochemical studies. This has been accomplished by a combination of ion-exchange and reverse-phase chromatography which results in a homogeneous toxin preparation. The active material produced is sufficient for many types of biological studies and for mutagenesis experiments directed at determining the structure function relationships of toxin interactions with the neuronal nicotinic acetylcholine receptor. In addition, the kappa-bungarotoxin produced in this manner has the distinct advantage over venom-purified kappa-bungarotoxin of not being contaminated with other venom components which could potentially affect experimental observations.

[Effect of toxic components of snake venoms on binding of substance P with rat brain membranes]

Ion-exchange HPLC is used for purification of the snake venom alpha-neurotoxins, chi-bungarotoxin, cytotoxins, and phospholipases A2. Among these purified polypeptides, phospholipases A2 are found to be the most potent in inhibiting the substance P binding to rat brain membranes, Ki approximately 10(-8) M. Other toxins are weak inhibitors (Ki greater than or equal to 10(-4)-10(-5) M), earlier data on the inhibiting activity of alpha-bungarotoxin being caused by the commercial preparations' contamination with phospholipase A2.

Solution structure of neuronal bungarotoxin determined by two-dimensional NMR spectroscopy: sequence-specific assignments, secondary structure, and dimer formation

The solution structure of neuronal bungarotoxin (nBgt) has been studied by using two-dimensional 1H NMR spectroscopy. Sequence-specific assignments for over 95% of the backbone resonances and 85% of the side-chain resonances have been made by using a series of two-dimensional spectra at four temperatures. From these assignments over 75% of the NOESY spectrum has been assigned, which has in turn provided 582 distance constraints. Twenty-seven coupling constants (NH-alpha CH) were determined from the COSY spectra, which have provided dihedral angle constraints. In addition, hydrogen exchange experiments have suggested the probable position of hydrogen bonds. The NOE constraints, dihedral angle constraints, and the rates of amide proton exchange suggest that a triple-stranded antiparallel beta sheet is the major component of secondary structure, which includes 25% of the amino acid residues. A number of NOE peaks were observed that were inconsistent with the antiparallel beta-sheet structure. Because we have confirmed by sedimentation equilibrium that nBgt exists as a dimer, we have reinterpreted these NOE constraints as intermolecular interactions. These constraints suggest that the dimer consists of a six-stranded antiparallel beta sheet (three from each monomer), with residues 55-59 forming the dimer interface.

Selective labeling of alpha-bungarotoxin with fluorescein isothiocyanate and its use for the study of toxin-acetylcholine receptor interactions

The main product of the reaction of fluorescein isothiocyanate (FITC) and bungarotoxin (Bgt) under near stoichiometric conditions is a monofluorescein derivative preferentially labeled at Lys 26, a highly conserved residue known to be involved in the binding (McDaniel, C.S., Manshouri, T., and Atassi, M.Z. (1987) J. Prot. Chem. 6, 455-461; Garcia-Borron, J.C., Bieber, A.L., and Martinez-Carrion, M. (1987) Biochemistry 26, 4295-4303) of postsynaptic neurotoxins specific for the nicotinic acetylcholine receptor (AcChR). The fluorescently labeled toxin retains a high affinity for the AcChR, and an unaltered specificity. Binding of FITC-Bgt to AcChR results in a significant decrease in the fluorescence intensity of the probe. This AcChR-mediated quenching of FITC-Bgt fluorescence allows for a continuous monitoring of the binding process. The quenching of free and bound FITC-Bgt by charged and neutral quenchers shows few fluorophore accessibility changes as induced by the toxin-bound state. The results are consistent with a model in which the positively charged concave surface of the toxin interacts with a negatively charged complementary surface in the receptor molecule.

Kappa 2-bungarotoxin and kappa 3-bungarotoxin: two new neuronal nicotinic receptor antagonists isolated from the venom of Bungarus multicinctus

Neuronal nicotinic acetylcholine receptors are recognized with high affinity by two snake venom kappa-neurotoxins, kappa-bungarotoxin and kappa-flavitoxin. Native and radiolabeled kappa-neurotoxins have been used to localize and quantitate neuronal nicotinic receptors in a variety of species. We now report the identification of two new kappa-neurotoxins. kappa 2-Bungarotoxin and kappa 3-bungarotoxin were purified from the venom of Bungarus multicinctus collected in the province of Guangdong, China. kappa-Bungarotoxin has as yet not been found in this venom, although it is the only kappa-neurotoxin to be isolated thus far from Taiwanese Bungarus multicinctus. The geographical separation of Guangdong and Taiwan might account for this evolutionary divergence within the species. Both of the new kappa-neurotoxins are potent antagonists of nicotinic transmission in the chick ciliary ganglion. kappa 3-Bungarotoxin, the least potent of the kappa-neurotoxins, produces a complete blockage of nicotinic transmission in 60 min at 250 nM. Protection experiments using the short-acting nicotinic antagonists dihydro-beta-erythroidine and (+)-tubocurarine demonstrate that kappa 2-bungarotoxin blocks transmission by binding to the acetylcholine recognition sites of neuronal nicotinic receptors. The isoelectric point of kappa 2-bungarotoxin (pI = 8.9) is similar to that of kappa-bungarotoxin and kappa-flavitoxin, but kappa 3-bungarotoxin is considerably more basic, with pI greater than 11. Partial amino acid sequences are reported for both kappa 2-bungarotoxin and kappa 3-bungarotoxin. These sequences show a high degree of homology (approximately 80%) with other kappa-neurotoxins, and allow the determination of the critical differences between the kappa-neurotoxins and the structurally related alpha-neurotoxins. For example, all 4 kappa-neurotoxins lack a tryptophanyl residue which is invariant and important for function in the alpha-neurotoxins. The kappa-neurotoxins also differ from the alpha-neurotoxins by having an invariant prolinyl residue at a critical sequence position. Heterodimers were detected consisting of one subunit each of kappa 2-bungarotoxin and kappa 3-bungarotoxin. These heterodimers, which form between any combination of two kappa-neurotoxins, appear to be physiologically active and confirm that a further distinction between kappa-neurotoxins and alpha-neurotoxins is the strong tendency of the former to self-associate in solution. The present results help to establish the definition of 'kappa-neurotoxin'. These snake toxins are now being used by a number of laboratories in physiological and biochemical experiments on neuronal nicotinic receptors from a variety of species.(ABSTRACT TRUNCATED AT 400 WORDS)

Beta-bungarotoxin. Preparation and characterization of crystals suitable for structural analysis

Phospholipases in some snake venoms are potent neurotoxins that target their enzymatic action to the synaptic membrane. One of these is the heterodimeric neurotoxin, beta-bungarotoxin, which binds with a protease inhibitor-like subunit to a presynaptic potassium channel and then blocks neurotransmission with a second subunit that has phospholipase A2 activity. We have prepared and characterized well ordered crystals of the most toxic beta-bungarotoxin isoform, beta 1-bungarotoxin. The crystals are monoclinic, space group C2, with unit cell parameters: a = 176.5 A, b = 39.3 A, c = 92.7 A, and beta = 114.8 degrees. Rotation-function analysis of the Patterson function, as calculated from a 2.3-A data set, reveals an asymmetric unit composed of four heterodimers. These heterodimers appear to be associated as two crystallographically distinct (AB)4 tetramers, each having dihedral D2 symmetry. The two are positioned with equivalent molecular 2-fold axes coincident with crystallographic dyads, but rotated by 55 degrees relative to one another. X-ray analysis of these crystals will permit direct visualization of the specific structural motifs and chemical features that underlie phospholipase neurotoxicity.

Primary structure of alpha-bungarotoxin. Six amino acid residues differ from the previously reported sequence

alpha-Bungarotoxin (alpha-BuTx) was isolated from the venom of the Formosan banded krait (Bungarus multicinctus). The amino acid sequence was determined by a combination of conventional methods. In contrast to the sequence of alpha-BuTx reported by Mebs et al. ([1971) Biochem. Biophys. Res. Commun. 44, 711-716], our results revealed the presence of Ser-Pro-Ile, Pro-His and Gln-Arg at positions 9-11, 67-68 and 71-72 from the amino-terminal, respectively, and not Ile-Pro-Ser, His-Pro and Arg-Gln as reported previously.

Differences in pharmacological actions between beta-bungarotoxin and other neurotoxic phospholipases A2 purified from snake venoms

Five highly toxic phospholipases A2 (PLAs) (beta-bungarotoxin, caudoxin, Mojave toxin, notexin and a basic PLA from Naja nigricollis venom) were compared for their pharmacological actions. In the chick biventer cervicis nerve-muscle preparation, all PLA toxins except beta-bungarotoxin (beta-BuTX) inhibited the postsynaptic acetylcholine response and induced contracture of the muscle at a high concentration. Indirect hemolytic activity was found in all PLA toxins and some of the toxins (Naja nigricollis basic PLA and Mojave toxin) even showed a potent direct hemolytic action, while beta-BuTX was devoid of both direct and indirect hemolytic activities on the guinea-pig erythrocytes. All PLA toxins except beta-BuTX caused an increase in muscle tone in the guinea-pig ileum at a concentration as low as 0.05 microgram/ml, and an increase in the contractile force in the guinea-pig atrium at a concentration of 1.0 microgram/ml. In contrast, beta-BuTX had no stimulant effect at concentrations up to 10 micrograms/ml. On the cultured cells, beta-BuTX suppressed the proliferation of neuroblastoma cells, but did not cause lysis of non-neuronal cells of the rat brain. However, beta-BuTX uniquely maintained a high population of viable cells in the neuroblastoma cell cultures. From these results it was concluded that beta-BuTX is the most specific presynaptic neurotoxin among the PLA toxins so far tested.

Isolation of a polypeptide from the venom of Bungarus multicinctus that binds to ganglia and blocks the ganglionic transmission in mammals

A 15,000 dalton polypeptide purified from Bungarus multicinctus venom (which normally copurifies with alpha-bungarotoxin) was characterized biochemically and its biological effects were studied. This polypeptide, P15, had an aminoacid composition and molecular weight different from those of both alpha- and beta-bungarotoxin. It inhibited the ganglionic transmission in the guinea-pig hypogastric nerve-vas deferens preparation and did not block, even at very high concentrations, the neuromuscular transmission in the rat phrenic nerve-diaphragm preparation. In the same preparations alpha-bungarotoxin was unable to block the response at the ganglionic synapse while it was fully active in blocking the neuromuscular transmission. However, a pretreatment of the vas deferens preparation with alpha-bungarotoxin prevented the inhibitory effect of P15. 125I-Labeled P15 showed a specific and saturable binding to rat superior cervical ganglia homogenate and to a Torpedo postsynaptic membrane fraction. The binding of P15 to ganglia was inhibited by curare. The binding was Ca2+ dependent. The density of binding sites was of 300 fmol/mg of protein in the ganglion and 500 fmol/mg of protein in Torpedo membranes. The amount of P15-binding sites in ganglia was not modified by denervation, indicating that P15 binds to postsynaptic receptors. The binding of 125I-labeled P15, both in ganglia and Torpedo membranes, was inhibited by alpha-bungarotoxin. P15 had a Ca2+-dependent phospholipase A2 activity. Lowering Ca2+ concentration in incubation media affected the phospholipase A2 activity more than binding properties and inhibition of phospholipase activity with p-bromophenacyl bromide did not affect the activity of P15 on vas deferens preparation, suggesting that the phospholipase activity is not necessary for the activity of P15 on nicotinic receptors. Our results suggest that P15 toxin may be a specific and valuable probe for studying the ganglionic nicotinic receptor.

kappa-Bungarotoxin. Self-association of a neuronal nicotinic receptor probe

kappa-Bungarotoxin is a postsynaptic neurotoxin purified from the venom of the elapid snake Bungarus multicinctus. The amino acid sequence of this basic polypeptide reveals a single chain containing 66 amino acids having a Mr of 7,313. kappa-Bungarotoxin is a potent antagonist of nicotinic cholinergic transmission in avian and murine autonomic ganglia, a characteristic which distinguishes the toxin from other postsynaptic neurotoxins isolated from snake venoms. The self-association of kappa-bungarotoxin has now been examined using molecular sizing columns, sedimentation velocity, and sedimentation equilibrium. The results demonstrate that, under physiological solvent conditions, kappa-bungarotoxin exists as a dimer (Mr = 14,000 +/- 3,000) of identical subunits. kappa-Bungarotoxin monomers are not observed at toxin concentrations typically used in electrophysiological experiments (0.5-22 micrograms/ml), indicating that the dimer may be physiologically active. Denaturation with sodium dodecyl sulfate or urea dissociates kappa-bungarotoxin dimers into monomers. Significant amounts of monomers are also produced under nondenaturing conditions of high ionic strength and high pH. However, complete reassociation of nondenatured monomers occurs following return to a physiological buffer. The unique pharmacological spectrum of kappa-bungarotoxin may be due in part to its strong tendency to self-associate.

Rapid purification of a phospholipase-free alpha-bungarotoxin: maintenance of cation barriers of acetylcholine receptor membranes upon preincubation with purified toxin

The purification of highly homogeneous, phospholipase-free alpha-bungarotoxin (alpha-Bgt) from the venom of the elapid Bungarus multicinctus or from commercial samples of alpha-Bgt is described. The method combines a conventional procedure for the purification of alpha-Bgt [D. Mebs, K. Narita, S. Iwanaga, Y. Samejima, and C. Y. Lee (1972) Hoppe-Seyler's Z. Physiol. Chem. 353, 243-262] with high-resolution gel-filtration and cation-exchange chromatography steps to remove membrane-damaging, contaminating phospholipase activity. The procedure also removes contaminating radioactive peptides from commercial preparations of 125I-alpha-Bgt. Apparent homogeneity of the purified alpha-Bgt (referred to as fraction D in the text), as well as the absence of contaminating phospholipase A2 activity, is assessed by (i) polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, (ii) gel-filtration and cation-exchange high-performance liquid chromatography, (iii) direct measurements of phospholipase A2 activity under conditions where very low enzymatic levels should be detected, (iv) lack of interference with the passive cation permeability properties of acetylcholine receptor membranes, (v) competitive inhibition of 125I-alpha-Bgt binding to the acetylcholine receptor membranes, and (vi) amino acid analysis and end-group (C- and N-terminus) determination. alpha-Bgt preparations subjected to these criteria do not exert the increase in membrane passive permeability to cations detected with other laboratory or commercial samples of alpha-Bgt. Availability of the new alpha-Bgt preparation allows for an assessment of the inertness of alpha-Bgt on lipid membrane properties while preventing cholinergic ligand binding to nicotinic acetylcholine receptor-rich membranes. These conditions are necessary for experiments requiring maintenance of the physical and phospholipid integrity of membranes.

Characterization of a snake venom neurotoxin which blocks nicotinic transmission in the avian ciliary ganglion

Bungarus multicinctus venom was fractionated by ion exchange chromatography and the various fractions were assayed for their ability to block synaptic transmission through the chick ciliary ganglion. alpha-Bungarotoxin purified from this venom failed to block transmission at 50 micrograms/ml. A second neurotoxin, which we designate Toxin F, blocked transmission at 1-3 micrograms/ml and also blocked ganglionic depolarizations induced by carbachol. Toxin F was clearly distinguishable from alpha-bungarotoxin on the basis of molecular weight (estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and isoelectric point. Binding assays revealed that 125I-labeled toxin F bound to two sites in the ciliary ganglion: one site that was shared by alpha-bungarotoxin and toxin F and another site that was recognized solely by toxin F. Carbachol and d-tubocurarine displaced only that [125I]toxin F bound to the shared site and had no effect on [125I]toxin F bound to the site recognized by toxin F alone. The results suggest that toxin F blocks synaptic transmission in the chick ciliary ganglion by a postsynaptic mechanism. Further study is required to determine whether this effect of toxin F is mediated through a direct interaction with ganglionic nicotinic receptors.

Kappa-bungarotoxin: a probe for the neuronal nicotinic receptor in the avian ciliary ganglion

The interaction of snake alpha-neurotoxins with neuronal membranes has been examined in the chick ciliary ganglion. Some, but not all, alpha-neurotoxins block nicotinic transmission in this ganglion. alpha-Bungarotoxin (ABgT), the major alpha-neurotoxin in the venom of Bungarus multicinctus, does not block transmission at high concentrations (1.2 microM) although it binds (Kd = 1 nM) to a pharmacologically nicotinic site in the ganglion. A toxin (kappa-bungarotoxin, KBgT) has been purified from the venom of Bungarus multicinctus. KBgT has a molecular weight of 6500 daltons and a pI of 9.1. KBgT is a potent inhibitor of nicotinic transmission in the ciliary ganglion, producing a reversible (overal several hours) blockade at 75 nM. Pre-exposure of ganglia to 1.2 microM ABgT does not prevent the effects of KBgT, indicating that the blockade occurs at a site distinct from that recognized by ABgT. Binding of [125I]KBgT to ciliary ganglia reveals two binding sites: one which has previously been characterized by [125I]ABgT and one which is not identified by [125I]ABgT. Both of these [125I]KBgT binding sites are blocked following pre-treatment of ganglia with the irreversible nicotinic affinity agent bromoacetylcholine. A two-site model is proposed to account for these observations. One site (the ABgT binding site) is seen by both ABgT and KBgT, and has as yet no physiological function associated with it. The second site is recognized only by the physiologically active KBgT, and may represent binding of the toxin to the physiologically detected nicotinic receptor.

Analysis of receptor-ligand interactions using nitrocellulose gel transfer: application to Torpedo acetylcholine receptor and alpha-bungarotoxin

A nitrocellulose-gel transfer technique has been adapted to study the interaction of a polypeptide ligand with individual receptor subunits. The acetylcholine receptor isolated from Torpedo californica has been separated into its subunits by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred in a renaturing environment to nitrocellulose sheets. The sheets were incubated with 125I-alpha-bungarotoxin and autoradiographed. A single receptor polypeptide, the alpha subunit (40K) bound the labeled toxin. This binding was demonstrated to be both saturable and specific, although the affinity of 125I-alpha-bungarotoxin (KD, 165 nM) and the potency of d-tubocurarine to displace this binding (IC50, 1 mM) were both reduced by several orders of magnitude when compared to the native receptor.

Ceruleotoxin: identification in the venom of Bungarus fasciatus, molecular properties and importance of phospholipase A2 activity for neurotoxicity

Ceruleotoxin is a potent neurotoxin which was originally purified from a batch of venom labelled Bungarus caeruleus, from the Pasteur Institute. Since NOBLE et al. have shown that this batch differs in its protein composition from that of B. caeruleus provided by Miami Serpentarium, we decided to clarify this point by comparing the composition of venoms from various Bungarus species of several origins. Although individual variations exist between samples of the same species, the venom from B. multicinctus, B. caeruleus and B. fasciatus possess characteristic protein compositions which allowed us to identify the batch used to purify ceruleotoxin as a B. fasciatus venom. We identified and purified ceruleotoxin from each of the five samples of B. fasciatus venoms tested. We failed to find this neurotoxin in either B. multicinctus or B. caeruleus venoms. Purified ceruleotoxin is a slightly basic protein with an isoelectric point of 7.4 which possesses a significant phospholipase A2 activity (200 mumoles lecithin hydrolyzed per min per mg) and a high lethal potency (i.v. LD50 in mice 0.03-0.07 mg/kg). It is composed of two identical subunits of 13,000 mol. wt. which resemble pancreas and snake venom phospholipases in their amino acid composition. Like crotoxin, ceruleotoxin irreversibly blocks the postsynaptic response of Torpedo and Electrophorus electroplaques to cholinergic agonists without preventing the binding of acetylcholine to its receptor. By hydrolyzing critical lipids of the postsynaptic membrane, it stabilizes the acetylcholine receptor - ionophore assembly in a desensitized state.

Preparation of neurotoxic 3H-beta-bungarotoxin: demonstration of saturable binding to brain synapses and its inhibition by toxin I

1. Homogeneous beta-bungarotoxin, isolated from the venom of Bungarus multicinctus was radiolabelled with N-succinimidyl-[2.3-(3) H]propionate. Stable, di-propionylated material was obtained which was tritiated on both subunits and had a specific radioactivity of 102 Ci/mmol. 2. After separation from unlabelled toxin by isoelectric focussing, it was shown to exhibit significant biological activity in both the peripheral and central nervous systems but had negligible phospholipase A2 activity towards lecithin or cerebrocortical synaptosomes. 3. The labeled neurotoxin binds specifically to a single class of non-interacting sites of high affinity (Kd = 0.6 nM) on rat cerebral cortex synaptosomes; the content of sites is about 150 fmol/mg protein. This binding was inhibited by unlabelled beta-bungarotoxin with a potency which indicates that tritiation does not alter the affinity significantly. 4. The association of toxin with its binding component and its dissociation were monophasic; rate constants observed were 7.8 x 10(5) M-1 s-1 and 5.6 x 10(-4) s-1 at 37 C, respectively. 5. beta-Bungarotoxin whose phospholipase activity had been inactivated with p-bromophenacyl bromide inhibited to some extent the binding of tritiated toxin but with low efficacy. Taipoxin and phospholipase A2 from bee venom, but not Naja melanoleuca, inhibited the synaptosomal binding of toxin with low potencies in the presence, but not the absence, of Ca2+. 6. Toxin I, a single-chain protein from Dendroaspis polylepis known to potentiate transmitter release at chick neuromuscular junction, completely inhibited the binding of 3H-beta-bungarotoxin with a Ki of 0.07 nM; this explains its ability to antagonise the neuroparalytic action of beta-bungarotoxin. Other pure presynaptic neurotoxins, alpha-latrotoxin and botulinum neurotoxin failed to antagonise the observed binding; likewise tityustoxin, which is known to affect sodium channels, had no effect on 3H-beta-bungarotoxin binding. 7. Trypsinization of synaptosomes completely destroyed the binding activity, suggesting that the binding component is a protein; the functional role of the latter is discussed in relation to the specificity of toxin binding.

Amino acid sequence of beta 2-bungarotoxin from Bungarus multicinctus venom. The amino acid substitutions in the B chains

beta 2-Bungarotoxin (beta 2-toxin) was isolated from the venom of Bungarus multicinctus by means of CM-Sephadex C-25 column chromatography, Sephadex G-75 gel filtration and CM-Sephadex C-25 column rechromatography. beta 2-Toxin consisted of two dissimilar polypeptides, a (120 amino acid residues) and B (60 amino acid residues) chains, crosslinked by an interchain disulfide bond. The neurotoxicity (LD50) and phospholipase activity of beta 2-toxin were 0.029 micrograms/g of mouse and 48.9 units/mg of toxin, respectively, and both the activities were slightly weaker than those (0.019 micrograms/g and 60.9 units/mg) of beta 1-bungarotoxin (beta 1-toxin). beta 2-Toxin was reduced and carboxymethylated and then its RCM-A and -B chains were separated. Each RCM-chain was maleylated and then digested with TPCK-trypsin. The tryptic peptides were sequences by manual Edman degradation or the dansyl-Edman method, and the total alignment of the tryptic peptides from each RCM-chain was deduced based on the amino acid sequences of the A and B chains of beta 1-toxin. The amino acid sequence of the B chain of beta 2-toxin differed from that of the B chain of beta 1-toxin by 22 amino acid substitutions, while those of their A chains were identical. We concluded that the variation in the amino acid sequence of the B chains did not significantly affect the neurotoxicity of the beta-toxins. The amino acid sequences of the B chains of the two beta-toxins were homologous to those of proteinase inhibitors from snake venoms and mammalian pancreas, but no inhibitory activity of the two beta-toxins on proteinases was observed.

Amino acid sequences of three beta-bungarotoxins (beta 3-, beta 4-, and beta 5- bungarotoxins) from Bungarus multicinctus venom. Amino acid substitutions in the A chains

The two most basic beta-bungarotoxins (beta 3- and beta 4-toxins) and another, less neurotoxic beta-bungarotoxin (beta 5-toxin) were purified from Bungarus multicinctus venom, by a combination of CM-Sephadex C-25 column chromatography and Sephadex G-75 gel filtration. The three toxins consisted of two dissimilar polypeptides (A chain, 120 amino acid residues; B chain, 60 residues). The LD50 values of the beta 3- and beta 4-toxins were 0.066 micrograms and 0.072 micrograms/g of mouse, respectively, and their phospholipase A activities were 43.2 and 36.5 units/mg of toxin, respectively. beta 5-Toxin was weaker in neurotoxicity (LD50, 0.13 micrograms/g of mouse) than the others, and its phospholipase activity was 47.6 units/mg of toxin. Each toxin was separated into RCM-A and RCM-B chains after reduction and S-carboxymethylation. The RCM-polypeptides were maleylated and digested with TPCK-trypsin. The tryptic peptides were sequenced with manual Edman degradation or the dansyl-Edman method. The final alignment of the tryptic peptides from the respective RCM-polypeptides was deduced on the basis of the amino acid sequences of the A and B chains of beta 1-bungarotoxin (beta 1-toxin). The amino acid sequences of the A chains of the beta 3- and beta 4-toxins were identical but differed from those of the A chains of the beta 1- and beta 2-toxins by 4 amino acid substitutions in the COOH-terminal portions (residues 109-120) and substitution at position 87. The amino acid sequences of the B chains of the beta 3- and beta 4-toxins differed from each other, but they were identical with those of the B chains of the beta 1- and beta 2-toxins, respectively. The amino acid sequence of the A chain of beta 5-toxin differed from that of the A chain of beta 1-toxin by consecutive substitutions in residues 55-60 and substitutions at positions 23, 87, and 89. The amino acid sequence of the B chain of beta 5-toxin was identical with those of the B chains of beta 1- and beta 3-toxin. From our results on the effects of the amino acid displacements found in the A chains on the neurotoxicity, it was concluded that the COOH-terminal portion in the A chains was not essential to their neurotoxicity, whereas the region of residues 55-60 in the A chains appeared to participate in the constitution of the neurotoxically active site of the beta-toxins.

Blockade of transmission in rat sympathetic ganglia by a toxin which co-purifies with alpha-bungarotoxin

Bungarus multicinctus venom was fractionated into its toxin components using ion-exchange chromatography on CM-Sephadex. According to previous reports, rechromatography of fraction II on a CM cellulose column yields chemically homogenous alpha-bungarotoxin (II2) of molecular weight 9000. However, in our hands, using the identical purification procedure, two discrete proteins of molecular weight 9000 and 15,000 were obtained as demonstrated by SDS gel electrophoresis. Subsequent fractionation of this alpha-bungarotoxin fraction (II2) was achieved on Sephadex G-50. The 9000 weight component (labelled II-S2) was identical to alpha-bungarotoxin; at a concentration of 1 microgram/ml it blocked transmission at the neuromuscular junction but did not block nicotinic responses in rat sympathetic ganglia. Very different properties were exhibited by II-SI, the 15,000 molecular weight component; it inhibited ganglionic transmission but was ineffective at the neuromuscular junction at the same concentration (1 microgram/ml). BGT II-S1 was equipotent in blocking the ganglionic action potential in the presence or absence of eserine; thus, it is not acting as an acetylcholinesterase by increasing acetylcholine breakdown. In the presence of toxin, [3H]choline incorporation into ganglionic acetylcholine during preganglionic stimulation was not altered, suggesting that the toxin did not block transmission by a presynaptic mechanism. Thus, the site of action of the toxin appears to be postsynaptic although it did not affect depolarization of the ganglia induced by carbachol.

Isolation of "ceruleotoxin" from Bungarus fasciatus venoms

Ceruleotoxin is a potent neurotoxin which irreversibly blocks the neuromuscular transmission at a postsynaptic level, without preventing the binding of acetylcholine to its receptor. We have originally purified this toxin from a batch of venom obtained from the Pasteur Institute, which was thought to be Bungarus caeruleus venom. Recently Noble and co-workers have observed that the protein composition of Bungarus caeruleus provided by Miami Serpentarium significantly differed from that of the Pasteur Institute batch, which they concluded therefore to be of a different origin. In order to clarify this point, the venom composition of various Bungarus species from several origins have been analysed by electrophoresis and by electrofocusing on polyacrylamide gels. Although individual variations exist between samples of the same snake species, the venom from Bungarus caeruleus, Bungarus fasciatus and Bungarus multicinctus possess distinct and characteristic protein compositions. The results of this study allowed us to identify unambiguously the batch used to purify the ceruleotoxin, as a Bungarus fasciatus venom. We identified a neurotoxin similar to ceruleotoxin in each of the five samples of Bungarus fasciatus venoms that we tested. On the contrary we did not detect such a toxin either in Bungarus caeruleus or in Bungarus multicinctus venoms. All purified ceruleotoxins are acidic proteins with a high toxicity (their LD50 by intravenous injection in mice are from 0.04 to 0.06 mg per kg), which irreversibly block the postsynaptic response of Electrophorus electricus electroplaque to cholinergic agonists. They also possess a phospholipase A2 activity (200 nmoles of egg lecithins hydrolysed per min per mg of protein). In this respect, ceruleotoxin is analogous to crotoxin and beta-bungarotoxin.

Molecular forms of the acetylcholine receptor from vertebrate muscles and Torpedo electric organ. Interactions with specific ligands

Multiple forms of the acetylcholine receptor solubilised from cat denervated muscle were separated by velocity sedimentation centrifugation. The kinetic properties of the two main forms (with sedimentation coefficients of 9 S and 4 S) were investigated using a pure preparation of a suitable probe, [3H]propionyl-alpha-bungaro-toxin. The binding of this toxin to each of these forms of the muscle receptor was consistent with a simple bimolecular reaction with a homogeneous class of binding sites. Negligible dissociation of the receptor-toxin complex was observed. This behaviour was also found for the different forms of the acetylcholine receptor of chick embryo muscle and of Torpedo marmorata electric organ. Association rate constants for binding of the 3H-labelled alpha-toxin to receptor from chick embryo muscle and the 9-S and 4-S forms from cat denervated muscle were 0.54 X 10(5), 1.76 X 10(5) and 2.69 X 10(5) M--1 S--1 respectively, at 25 degrees C. The values obtained for the 9-S and 13-S forms of receptor from T. marmorata were 4.51 X 10(5) and 9.93 X 10(5) M--1 S--1 respectively. The reaction of the 3H-labelled alpha-toxin with the receptor was second-order and linear in the presence of an antagonist, as in its absence, for the 4-S and 9-S forms of the cat denervated muscle receptor. This reaction of the receptor was inhibited by cholinergic ligands, with Ki values for two antagonists tested being greater with the 4-S form than with the 9-S form. Apparent negative interaction is observed for antagonists with this receptor, with Hill coefficients of about 0.78 and 0.64 for the 4-S and 9-S forms respectively. A ligand-induced affinity increase, produced by the agonists but not by the antagonists, was observed in this reaction for both forms of the muscle receptor. Two agonists tested showed no difference between these forms in their high-affinity states in either their binding affinities or Hill coefficients.

Purification and properties of the soluble NAD glycohydrolase from Bungarus fasciatus venom

The NAD glycohydrolase (NADase) (EC 3.2.2.5) from Bungarus fasciatus (banded krait) venom was purified (1000-fold) to electrophoretic homogeneity through a 3-step purification procedure, the last step being affinity chromatography on Cibacron blue agarose. The purified NADase is a glycoprotein containing two subunits of Mr = 62,000 each. Nicotinamide and adenosine diphosphoribose were produced in a 1:1 stoichiometry and were the only products formed when the purified NADase was incubated with NAD. These results were confirmed by high performance liquid chromatography. The enzyme exhibited a brod pH profile with optimum pH for hydrolysis at 7.5 with very little change in Km from pH 6.0 to pH 8.5. The NADase is only slightly affected by changes in ionic strength. The enzyme studied titrimetrically at pH 7.5 and 38 degrees C exhibited a Km of 14 microM and a Vmax of 1380 mumol of NAD cleaved/min/mg of protein. The activation energy for the enzyme-catalyzed hydrolysis of NAD was 15.7 kcal/mol. In addition to NAD and NADP, a number of NAD analogs were shown to function as substrates for the enzyme. Product inhibition studies demonstrated nicotinamide to be a noncompetitive inhibitor with a KI of 1.5 mM and adenosine diphosphoribose a competitive inhibitor with a KI of 0.36 mM. Procion blue HB (Cibacron blue F3GA) was shown to be a competitive inhibitor with a KI of 33 nmol. The purified NADase catalyzed the pyridine base exchange reaction between 3-acetylpyridine and the nicotinamide moiety of NAD.

Tritiation of alpha-bungarotoxin with N-succinimidyl [2,3-3H]propionate. A useful reagent for labelling proteins

Mono[3H]propionyl-alpha-bungarotoxin, prepared with N-succinimidyl [2,3-3H]propionate (sp. radioactivity 50 Ci/mmol) and purified to homogeneity by electrofocusing, retains its biological activity and stability. Rate constants for its binding to acetylcholine receptor were 4.4-fold lower than for unlabelled toxin; no dissociation was detectable. Analysis of enzymic digests of toxin showed 3H is located mainly of entirely in epsilon-propionyl-lysine.

On the purification of beta-bungarotoxin

It has recently been claimed that our beta-bungarotoxin preparation contained three contaminants, including a postsynaptic toxin. We have extended our purification procedure and found no evidence of such contaminants.

Complete purification of beta-bungarotoxin. Characterization of its action and that of tityustoxin on synaptosomal accumulation and release of acetylcholine

beta-Bungarotoxin, a snake venom protein (molecular weight 21 000) that irreversibly blocks release of acetylcholine from nerve terminals, was purified to homogeneity by ion-exchange chromatography and isoelectric focussing. Sodium dodecyl sulphate gel electrophoresis under reducing conditions resolved two subunits of molecular weight 11 400 and 9000. In the presence of deoxycholate, it showed phospholipase activity which was activated by Ca2+ but not Sr2+.beta-Bungarotoxin and tityustoxin, a polypeptide that prolongs the opening of sodium channels, inhibited choline accumulation by synaptosomes purified from rat cortex. Both toxins also induced release of acetylcholine which was maximal in the presence of Ca2+ and showed ED50 values of 5 . 10(8) and 10(6) M, respectively. Unlike tityustoxin, beta-bungarotoxin also induced release of choline and cytoplasmic lactate dehydrogenase from synaptosomes, with similar potency, suggesting that it causes some membrane disruption, following its binding to the membrane. The effects of tityustoxin on both accumulation and release were antagonised by tetrodotoxin, which specifically blocks Na+ channels, indicating that it mediates these effects by depolarization. Thus, these toxins may prove to be useful probes for characterisation of nerve membrane components involved in triggering transmitter release.