Isolation and amino acid compositions of geographutoxin I and II from the marine snail Conus geographus

Historical Perspective of the Characterization of Conotoxins Targeting Voltage-Gated Sodium Channels

Marine toxins have potent actions on diverse sodium ion channels regulated by transmembrane voltage (voltage-gated ion channels) or by neurotransmitters (nicotinic acetylcholine receptor channels). Studies of these toxins have focused on varied aspects of venom peptides ranging from evolutionary relationships of predator and prey, biological actions on excitable tissues, potential application as pharmacological intervention in disease therapy, and as part of multiple experimental approaches towards an understanding of the atomistic characterization of ion channel structure. This review examines the historical perspective of the study of conotoxin peptides active on sodium channels gated by transmembrane voltage, which has led to recent advances in ion channel research made possible with the exploitation of the diversity of these marine toxins.

Polygenic prediction of educational attainment within and between families from genome-wide association analyses in 3 million individuals

We conduct a genome-wide association study (GWAS) of educational attainment (EA) in a sample of ~3 million individuals and identify 3,952 approximately uncorrelated genome-wide-significant single-nucleotide polymorphisms (SNPs). A genome-wide polygenic predictor, or polygenic index (PGI), explains 12-16% of EA variance and contributes to risk prediction for ten diseases. Direct effects (i.e., controlling for parental PGIs) explain roughly half the PGI's magnitude of association with EA and other phenotypes. The correlation between mate-pair PGIs is far too large to be consistent with phenotypic assortment alone, implying additional assortment on PGI-associated factors. In an additional GWAS of dominance deviations from the additive model, we identify no genome-wide-significant SNPs, and a separate X-chromosome additive GWAS identifies 57.

Search for New Bioactive Marine Natural Products and Application to Drug Development

Natural products are well recognized as an important source of lead compounds in drug development. During the past >30 years, we have discovered >1000 novel bioactive natural products from Okinawan marine organisms (sponges, tunicates, cone shells, etc.) and microorganisms (fungi, bacteria, dinoflagellates, etc.). Some of them are used as bioprobes useful for basic studies of life sciences, while others are expected to be candidates of drug leads.

A tyrosine-containing analog of mu-conotoxin GIIIA as ligand in the receptor binding assay for paralytic shellfish poisons

Development of novel analytical tools to detect marine biotoxins has been warranted in view of the apparent global pervasiveness of algal-derived shellfish poisoning, and the limitations of existing methods. Here, we describe the initial phase in the development and evaluation of a tyrosine-containing analog of μ-conotoxin (μ-CTX) GIIIA as an alternative to saxitoxin (STX) in a receptor binding assay (RBA) for paralytic shellfish poisons. The peptide analog was synthesized and characterized for structure and bioactivity. The major product of oxidation elicited paralytic symptoms in mice at a minimum dose of 1.31 mg kg(-1) (i.p.). Mass spectrometry analysis of the bioactive peptide gave a molecular mass of 2637.52 Da that was close to the predicted value. Iodination via chloramine-T produced non-, mono- and di-iodinated peptides (respectively, NIP, MIP and DIP). Competition assays against (3)H-STX revealed higher Ki and EC50 (P < 0.0001, ANOVA) indicating reduced affinity for the receptor, and limited displacement of receptor-bound STX. However, subsequent use of MIP may extend the application of RBA to detect small changes in toxin levels owing to its likely enhanced displacement by STX. This may be useful in analyzing samples with toxicities near the regulatory limit, or in establishing baseline values in high risk environments.

Roles of basic amino acid residues in the activity of μ-conotoxin GIIIA and GIIIB, peptide blockers of muscle sodium channels

To study in detail the roles of basic amino acid residues in the activity of μ-conotoxin GIIIA (μ-GIIIA) and GIIIB (μ-GIIIB), specific blockers of muscle sodium channels, seven analogs of μ-GIIIA, and two analogs of μ-GIIIB were synthesized. μ-GIIIA analogs were synthesized by replacing systematically the three Arg residues (Arg1, Arg13, and Arg19) with one, two, and three Lys residues. μ-GIIIB analogs were synthesized by replacing simultaneously all four Lys residues (Lys9, Lys11, Lys16, and Lys19) with Arg residues and further replacement of acidic Asp residues with neutral Ala residues. Circular dichroism spectra of the synthesized analogs suggested that the replacement did not affect the three dimensional structure. The inhibitory effects on the twitch contractions of the rat diaphragm showed that the side chain guanidino group of Arg13 of μ-GIIIA was important for the activity, whereas that of Arg19 had little role for biological activity. Although [Arg9,11,16,19]μ-GIIIB showed higher activity than native μ-GIIIB, highly basic [Ala2,12, Arg9,11,16,19]μ-GIIIB showed lower activity, suggesting that there was an appropriate molecular basicity for the maximum activity.

Biochemistry of envenomation

Venoms and toxins are of significant interest due to their ability to cause a wide range of pathophysiological conditions that can potentially result in death. Despite their wide distribution among plants and animals, the biochemical pathways associated with these pathogenic agents remain largely unexplored. Impoverished and underdeveloped regions appear especially susceptible to increased incidence and severity due to poor socioeconomic conditions and lack of appropriate medical treatment infrastructure. To facilitate better management and treatment of envenomation victims, it is essential that the biochemical mechanisms of their action be elucidated. This review aims to characterize downstream envenomation mechanisms by addressing the major neuro-, cardio-, and hemotoxins as well as ion-channel toxins. Because of their use in folk and traditional medicine, the biochemistry behind venom therapy and possible implications on conventional medicine will also be addressed.

Novel interactions identified between micro -Conotoxin and the Na+ channel domain I P-loop: implications for toxin-pore binding geometry

micro -Conotoxins ( micro -CTX) are peptides that inhibit Na(+) flux by blocking the Na(+) channel pore. Toxin residue arginine 13 is critical for both high affinity binding and for complete block of the single channel current, prompting the simple conventional view that residue 13 (R13) leads toxin docking by entering the channel along the pore axis. To date, the strongest interactions identified are between micro -CTX and domain II (DII) or DIII pore residues of the rat skeletal muscle (Na(v)1.4) Na(+) channels, but little data is available for the role of the DI P-loop in micro -CTX binding due to the lack of critical determinants identified in this domain. Despite being an essential determinant of isoform-specific tetrodotoxin sensitivity, the DI-Y401C variant had little effect on micro -CTX block. Here we report that the charge-changing substitution Y401K dramatically reduced the micro -CTX affinity ( approximately 300-fold). Using mutant cycle analysis, we demonstrate that K401 couples strongly to R13 (DeltaDeltaG > 3.0 kcal/mol) but not R1, K11, or R14 (<<1 kcal/mol). Unlike K401, however, a significant coupling was detected between toxin residue 14 and DI-E403K (DeltaDeltaG = 1.4 kcal/mol for the E403K-Q14D pair). This appears to underlie the ability of DI-E403K channels to discriminate between the GIIIA and GIIIB isoforms of micro -CTX (p < 0.05), whereas Y401K, DII-E758Q, and DIII-D1241K do not. We also identify five additional, novel toxin-channel interactions (>0.75 kcal/mol) in DII (E758-K16, D762-R13, D762-K16, E765-R13, E765-K16). Considered together, these new interactions suggest that the R13 side chain and the bulk of the bound toxin micro -CTX molecule may be significantly tilted with respect to pore axis.

Dependence of mu-conotoxin block of sodium channels on ionic strength but not on the permeating [Na+]: implications for the distinctive mechanistic interactions between Na+ and K+ channel pore-blocking toxins and their molecular targets

Mu-conotoxins (mu-CTXs) are Na+ channel-blocking, 22-amino acid peptides produced by the sea snail Conus geographus. Although K+ channel pore-blocking toxins show specific interactions with permeant ions and strong dependence on the ionic strength (mu), no such dependence has been reported for mu-CTX and Na+ channels. Such properties would offer insight into the binding and blocking mechanism of mu-CTX as well as functional and structural properties of the Na+ channel pore. Here we studied the effects of mu and permeant ion concentration ([Na+]) on mu-CTX block of rat skeletal muscle (mu1, Nav1.4) Na+ channels. Mu-CTX sensitivity of wild-type and E758Q channels increased significantly (by approximately 20-fold) when mu was lowered by substituting external Na+ with equimolar sucrose (from 140 to 35 mm Na+); however, toxin block was unaltered (p > 0.05) when mu was maintained by replacement of [Na+] with N-methyl-d-glucamine (NMG+), suggesting that the enhanced sensitivity at low mu was not due to reduction in [Na+]. Single-channel recordings identified the association rate constant, k(on), as the primary determinant of the changes in affinity (k(on) increased 40- and 333-fold for mu-CTX D2N/R13Q and D12N/R13Q, respectively, when symmetric 200 mm Na+ was reduced to 50 mm). In contrast, dissociation rates changed <2-fold for the same derivatives under the same conditions. Experiments with additional mu-CTX derivatives identified toxin residues Arg-1, Arg-13, and Lys-16 as important contributors to the sensitivity to external mu. Taken together, our findings indicate that mu-CTX block of Na+ channels depends critically on mu but not specifically on [Na+], contrasting with the known behavior of pore-blocking K+ channel toxins. These findings suggest that different degrees of ion interaction, underlying the fundamental conduction mechanisms of Na+ and K+ channels, are mirrored in ion interactions with pore-blocking toxins.

Molecular basis of isoform-specific micro-conotoxin block of cardiac, skeletal muscle, and brain Na+ channels

mu-Conotoxins (mu-CTXs) block skeletal muscle Na(+) channels with an affinity 1-2 orders of magnitude higher than cardiac and brain Na(+) channels. Although a number of conserved pore residues are recognized as critical determinants of mu-CTX block, the molecular basis of isoform-specific toxin sensitivity remains unresolved. Sequence comparison of the domain II (DII) S5-S6 loops of rat skeletal muscle (mu1, Na(v)1.4), human heart (hh1, Na(v)1.5), and rat brain (rb1, Na(v)1.1) Na(+) channels reveals substantial divergence in their N-terminal S5-P linkers even though the P-S6 and C-terminal P segments are almost identical. We used Na(v)1.4 as the backbone and systematically converted these DII S5-P isoform variants to the corresponding residues in Na(v)1.1 and Na(v)1.5. The Na(v)1.4-->Na(v)1.5 variant substitutions V724R, C725S, A728S, D730S, and C731S (Na(v)1.4 numbering) reduced block of Na(v)1.4 by 4-, 86-, 12-, 185-, and 55-fold respectively, rendering the skeletal muscle isoform more "cardiac-like." Conversely, an Na(v)1.5--> Na(v)1.4 chimeric construct in which the Na(v)1.4 DII S5-P linker replaces the analogous segment in Na(v)1.5 showed enhanced mu-CTX block. However, these variant determinants are conserved between Na(v)1.1 and Na(v)1.4 and thus cannot explain their different sensitivities to mu-CTX. Comparison of their sequences reveals two variants at Na(v)1.4 positions 729 and 732: Ser and Asn in Na(v)1.4 compared with Thr and Lys in Na(v)1.1, respectively. The double mutation S729T/N732K rendered Na(v)1.4 more "brain-like" (30-fold downward arrow in block), and the converse mutation T925S/K928N in Na(v)1.1 reproduced the high affinity blocking phenotype of Na(v)1.4. We conclude that the DII S5-P linker, although lying outside the conventional ion-conducting pore, plays a prominent role in mu-CTX binding, thus shaping isoform-specific toxin sensitivity.

A novel conus peptide ligand for K+ channels

Voltage-gated ion channels determine the membrane excitability of cells. Although many Conus peptides that interact with voltage-gated Na(+) and Ca(2+) channels have been characterized, relatively few have been identified that interact with K(+) channels. We describe a novel Conus peptide that interacts with the Shaker K(+) channel, kappaM-conotoxin RIIIK from Conus radiatus. The peptide was chemically synthesized. Although kappaM-conotoxin RIIIK is structurally similar to the mu-conotoxins that are sodium channel blockers, it does not affect any of the sodium channels tested, but blocks Shaker K(+) channels. Studies using Shaker K(+) channel mutants with single residue substitutions reveal that the peptide interacts with the pore region of the channel. Introduction of a negative charge at residue 427 (K427D) greatly increases the affinity of the toxin, whereas the substitutions at two other residues, Phe(425) and Thr(449), drastically reduced toxin affinity. Based on the Shaker results, a teleost homolog of the Shaker K(+) channel, TSha1 was identified as a kappaM-conotoxin RIIIK target. Binding of kappaM-conotoxin RIIIK is state-dependent, with an IC(50) of 20 nm for the closed state and 60 nm at 0 mV for the open state of TSha1 channels.

Charge conversion enables quantification of the proximity between a normally-neutral mu-conotoxin (GIIIA) site and the Na+ channel pore

mu-Conotoxin (mu-CTX) inhibits Na+ flux by obstructing the Na+ channel pore. Previous studies of mu-CTX have focused only on charged toxin residues, ignoring the neutral sites. Here we investigated the proximity between the C-terminal neutral alanine (A22) of mu-CTX and the Na+ channel pore by replacing it with the negatively charged glutamate. The analog A22E and wild-type (WT) mu-CTX exhibited identical nuclear magnetic resonance spectra except at the site of replacement, verifying that they have identical backbone structures. A22E significantly reduced mu-CTX affinity for WT mu1 Na+ channels (90-fold), as if the inserted glutamate repels the anionic pore receptor. We then looked for the interacting partner(s) of residue 22 by determining the potency of block of Y401K, Y401A, E758Q, D762K, D762A, E765K, E765A and D1241K channels by WT mu-CTX and A22E, followed by mutant cycle analysis to assess their individual couplings. Our results show that A22E interacts strongly with E765K from domain II (DII) (deltadeltaG=2.2 +/- 0.1 vs. <1 kcal/mol for others). We conclude that mu-CTX residue 22 closely associates with the DII pore in the toxin-bound channel complex. The approach taken may be further exploited to study the proximity of other neutral toxin residues with the Na+ channel pore.

Generation of polyclonal antibody against mu-conotoxin GIIIA using an immunogen of [Cys(5)]mu-conotoxin GIIIA site-specifically conjugated with bovine serum albumin

mu-Conotoxin GIIIA, one of the strong peptide toxins in the cone shell, preferentially blocks the skeletal muscle-type sodium channels in vertebrates. The toxicity of mu-conotoxin GIIIA is nearly equal to that of tetrodotoxin. The generation of an antibody for the native toxins is analytically useful, but practically difficult due to its high toxicity to animals. In this study, we generated the polyclonal antibody for mu-conotoxin GIIIA using a specific conjugation method in which the immunogen was detoxified while retaining the active-site structure for the sodium channels. ELISA analysis showed that the generated antibody recognized the native toxin folded with three disulfide bridges, but not the linear one. Furthermore, the physiologically active mutants of GIIIA were recognized while the inactive mutants were not, suggesting that the newly generated antibody can selectively recognize the physiologically active toxins. These methods for generating an antibody against peptide toxins will be applicable to other peptide toxins.

Modification of Arg-13 of mu-conotoxin GIIIA with piperidinyl-Arg analogs and their relation to the inhibition of sodium channels

mu-Conotoxin GIIIA, a peptide toxin isolated from the marine snail Conus geographus, preferentially blocks skeletal muscle sodium channels in vertebrates. In this study, analogs of mu-conotoxin GIIIA in which essential Arg-13 was replaced with arginine analogs consisting of a piperidyl framework to regulate length and direction of the side chain were synthesized. Synthesized analogs exhibited similar CD and NMR spectra to that of GIIIA, suggesting a three-dimensional structure identical to that of the native toxin. The biological activities of piperidyl analogs were decreased or lost despite the small change in the side chain of Arg-13. The investigated structure-activity relationships in inhibiting electrically stimulated muscle contraction suggest that the guanidinium group at amino acid position 13 interacts best when spaced with three to four carbons and placed in a vertical direction from the peptide loop. Thus, the position of the guanidinium group at Arg-13 of GIIIA must be located in a certain range for its strong interaction with the channel protein.

Clockwise domain arrangement of the sodium channel revealed by (mu)-conotoxin (GIIIA) docking orientation

mu-Conotoxins (mu-CTXs) specifically inhibit Na(+) flux by occluding the pore of voltage-gated Na(+) channels. Although the three-dimensional structures of mu-CTXs are well defined, the molecular configuration of the channel receptor is much less certain; even the fundamental question of whether the four homologous Na(+) channel domains are arranged in a clockwise or counter-clockwise configuration remains unanswered. Residues Asp(762) and Glu(765) from domain II and Asp(1241) from domain III of rat skeletal muscle Na(+) channels are known to be critical for mu-CTX binding. We probed toxin-channel interactions by determining the potency of block of wild-type, D762K, E765K, and D1241C channels by wild-type and point-mutated mu-CTXs (R1A, Q14D, K11A, K16A, and R19A). Individual interaction energies for different toxin-channel pairs were quantified from the half-blocking concentrations using mutant cycle analysis. We find that Asp(762) and Glu(765) interact strongly with Gln(14) and Arg(19) but not Arg(1) and that Asp(1241) is tightly coupled to Lys(16) but not Arg(1) or Lys(11). These newly identified toxin-channel interactions within adjacent domains, interpreted in light of the known asymmetric toxin structure, fix the orientation of the toxin with respect to the channel and reveal that the four internal domains of Na(+) channels are arranged in a clockwise configuration as viewed from the extracellular surface.

Novel structural determinants of mu-conotoxin (GIIIB) block in rat skeletal muscle (mu1) Na+ channels

mu-Conotoxin (mu-CTX) specifically occludes the pore of voltage-dependent Na(+) channels. In the rat skeletal muscle Na(+) channel (mu1), we examined the contribution of charged residues between the P loops and S6 in all four domains to mu-CTX block. Conversion of the negatively charged domain II (DII) residues Asp-762 and Glu-765 to cysteine increased the IC(50) for mu-CTX block by approximately 100-fold (wild-type = 22.3 +/- 7.0 nm; D762C = 2558 +/- 250 nm; E765C = 2020 +/- 379 nm). Restoration or reversal of charge by external modification of the cysteine-substituted channels with methanethiosulfonate reagents (methanethiosulfonate ethylsulfonate (MTSES) and methanethiosulfonate ethylammonium (MTSEA)) did not affect mu-CTX block (D762C: IC(50, MTSEA+) = 2165.1 +/- 250 nm; IC(50, MTSES-) = 2753.5 +/- 456.9 nm; E765C: IC(50, MTSEA+) = 2200.1 +/- 550.3 nm; IC(50, MTSES-) = 3248.1 +/- 2011.9 nm) compared with their unmodified counterparts. In contrast, the charge-conserving mutations D762E (IC(50) = 21.9 +/- 4.3 nm) and E765D (IC(50) = 22.0 +/- 7.0 nm) preserved wild-type blocking behavior, whereas the charge reversal mutants D762K (IC(50) = 4139.9 +/- 687.9 nm) and E765K (IC(50) = 4202.7 +/- 1088.0 nm) destabilized mu-CTX block even further, suggesting a prominent electrostatic component of the interactions between these DII residues and mu-CTX. Kinetic analysis of mu-CTX block reveals that the changes in toxin sensitivity are largely due to accelerated toxin dissociation (k(off)) rates with little changes in association (k(on)) rates. We conclude that the acidic residues at positions 762 and 765 are key determinants of mu-CTX block, primarily by virtue of their negative charge. The inability of the bulky MTSES or MTSEA side chain to modify mu-CTX sensitivity places steric constraints on the sites of toxin interaction.

Post-translationally modified neuropeptides from Conus venoms

Predatory cone snails (genus Conus) comprise what is arguably the largest living genus of marine animals (500 species). All Conus use complex venoms to capture prey and for other biological purposes. Most biologically active components of these venoms are small disulfide-rich peptides, generally 7-35 amino acids in length. There are probably of the order of 100 different peptides expressed in the venom of each of the 500 Conus species [1,2]. Peptide sequences diverge rapidly between Conus species, resulting in a distinct peptide complement for each species. Thus, the genus as a whole has probably generated approximately 50 000 different peptides, which can be organized into families and superfamilies with shared sequence elements [3]. In this minireview, we provide a brief overview of the neuropharmacological, molecular and cell-biological aspects of the Conus peptides. However, the major focus of the review will be the remarkable array of post-translational modifications found in these peptides.

Peptide toxin blockers of voltage-sensitive K+ channels: inotropic effects on diaphragm

Agents that block many types of K+ channels (e.g., the aminopyridines) have substantial inotropic effects in skeletal muscle. Specific blockers of ATP-sensitive and Ca2+-activated K+ channels, on the other hand, do not, or minimally, alter the force of nonfatigued muscle, consistent with a predominant role for voltage-gated K+ channels in regulating muscle force. To test this more directly, we examined the effects of peptide toxins, which in other tissues specifically block voltage-gated K+ channels, on rat diaphragm in vitro. Twitch force was increased in response to alpha-, beta-, and gamma-dendrotoxin and tityustoxin Kalpha (17 +/- 6, 22 +/- 5, 42 +/- 14, and 13 +/- 5%; P < 0.05, < 0.01, < 0.05, < 0.05, respectively) but not in response to delta-dendrotoxin or BSA (in which toxins were dissolved). Force during 20-Hz stimulation was also increased significantly by alpha-, beta-, and gamma-dendrotoxin and tityustoxin Kalpha. Among agents, increases in twitch force correlated with the degree to which contraction time was prolonged (r = 0.88, P < 0.02). To determine whether inotropic effects could be maintained during repeated contractions, muscle strips underwent intermittent 20-Hz train stimulation for a duration of 2 min in presence or absence of gamma-dendrotoxin. Force was significantly greater with than without gamma-dendrotoxin during repetitive stimulation for the first 60 s of repetitive contractions. Despite the approximately 55% higher value for initial force in the presence vs. absence of gamma-dendrotoxin, the rate at which fatigue occurred was not accelerated by the toxin, as assessed by the amount of time over which force declined by 25 and 50%. These data suggest that blocking voltage-activated K+ channels may be a useful therapeutic strategy for augmenting diaphragm force, provided less toxic blockers of these channels can be found.

Pore residues critical for mu-CTX binding to rat skeletal muscle Na+ channels revealed by cysteine mutagenesis

We have studied mu-conotoxin (mu-CTX) block of rat skeletal muscle sodium channel (rSkM1) currents in which single amino acids within the pore (P-loop) were substituted with cysteine. Among 17 cysteine mutants expressed in Xenopus oocytes, 7 showed significant alterations in sensitivity to mu-CTX compared to wild-type rSkM1 channel (IC50 = 17.5 +/- 2.8 nM). E758C and D1241C were less sensitive to mu-CTX block (IC50 = 220 +/- 39 nM and 112 +/- 24 nM, respectively), whereas the tryptophan mutants W402C, W1239C, and W1531C showed enhanced mu-CTX sensitivity (IC50 = 1.9 +/- 0.1, 4.9 +/- 0.9, and 5.5 +/- 0.4 nM, respectively). D400C and Y401C also showed statistically significant yet modest (approximately twofold) changes in sensitivity to mu-CTX block compared to WT (p < 0.05). Application of the negatively charged, sulfhydryl-reactive compound methanethiosulfonate-ethylsulfonate (MTSES) enhanced the toxin sensitivity of D1241C (IC50 = 46.3 +/- 12 nM) while having little effect on E758C mutant channels (IC50 = 199.8 +/- 21.8 nM). On the other hand, the positively charged methanethiosulfonate-ethylammonium (MTSEA) completely abolished the mu-CTX sensitivity of E758C (IC50 > 1 microM) and increased the IC50 of D1241C by about threefold. Applications of MTSEA, MTSES, and the neutral MTSBN (benzyl methanethiosulfonate) to the tryptophan-to-cysteine mutants partially or fully restored the wild-type mu-CTX sensitivity, suggesting that the bulkiness of the tryptophan's indole group is a determinant of toxin binding. In support of this suggestion, the blocking IC50 of W1531A (7.5 +/- 1.3 nM) was similar to W1531C, whereas W1531Y showed reduced toxin sensitivity (14.6 +/- 3.5 nM) similar to that of the wild-type channel. Our results demonstrate that charge at positions 758 and 1241 are important for mu-CTX toxin binding and further suggest that the tryptophan residues within the pore in domains I, III, and IV negatively influence toxin-channel interaction.

Electrophysiological analysis of transmission at the skeletal neuromuscular junction

The review is divided into two sections. The first deals with methods and problems associated with performing electrophysiological experimentation on the skeletal muscle neuromuscular junction. The second section concentrates on the computer analysis of electrophysiological data. In the first section, the various techniques available for producing skeletal muscle paralysis are described. These include the use of pharmacological manipulations, such as an excess of magnesium ions or a competitive postjunctional nicotinic acetylcholine antagonist, physiological manipulations, such as cutting the muscle fibers, and the muscle fiber sodium channel toxin, mu-conotoxin. Also, in this section, a comparison is made of the use of voltage- and current-recording techniques, including descriptions of, and solutions to, the problems associated with membrane capacitance, nonlinear summation, membrane space constant, and electrical and mechanical interference. In the second section, details are given of the types of computer system commonly used for the analysis of electrophysiological data and also the requirements of the data analysis software. The use of computer algorithms for signal detection, signal evaluation, signal averaging, and curve fitting are qualitatively described, along with some of the problems and pitfalls often associated with these methods.

Use of mu-conotoxin GIIIA for the study of synaptic transmission at the frog neuromuscular junction

We have looked at the effect of synthetic mu-conotoxin GIIIA, a selective blocker of muscle Na channels, on various parameters of synaptic transmission at the frog sartorius nerve-muscle preparation. We found that 5 microM mu-conotoxin consistently blocked muscle action potentials, but had no effect on nerve action potentials. The toxin also had no effect on the amplitude or frequency of miniature endplate potentials (MEPPs), on the amplitude or time course of endplate potentials (EPPs), or on stimulation-induced changes in EPP amplitude. The lack of an effect of synthetic mu-conotoxin GIIIA on transmitter release makes this toxin an invaluable tool in the study of neuromuscular transmission under conditions of normal levels of release.

Tertiary structure of conotoxin GIIIA in aqueous solution

The three-dimensional structure of conotoxin GIIIA, an important constituent of the venom from the marine hunting snail Conus geographus L., was determined in aqueous solution by two-dimensional proton nuclear magnetic resonance and simulated annealing based methods. On the basis of 162 assigned nuclear Overhauser effect (NOE) connectivities obtained at the medium field strength frequency of 400 MHz, 74 final distance constraints of sequential and tertiary ones were derived and used together with 18 torsion angle (phi, chi 1) constraints and 9 distance constraints derived from disulfide bridges. A total of 32 converged structures were obtained from 200 runs of calculations. The atomic root-mean-square (RMS) difference about the mean coordinate positions (excluding the terminal residues 1 and 22) is 0.8 A for backbone atoms (N, C alpha, C). Conotoxin GIIIA is characterized by a particular folding of the 22 amino acid peptidic chain, which is stabilized by three disulfide bridges arranged in cage at the center of a discoidal structure of approximately 20-A diameter. The seven cationic side chains of lysine and arginine residues project radially into the solvent and form potential sites of interaction with the skeletal muscle sodium channel for which the toxin is a strong inhibitor. The present results provide a molecular basis to elucidate the remarkable physiological properties of this neurotoxin.

Disulfide pairings in geographutoxin I, a peptide neurotoxin from Conus geographus

The three intramolecular disulfide linkages of geographutoxin I, a peptide neurotoxin isolated from the venom of the marine snail Conus geographus, were examined by a novel method for determination of the positions of disulfide linkages in peptides [(1989) Bull. Chem. Soc. Jp. 62, 1986-1994]. The disulfide bridges were found to be between Cys3 and Cys15, Cys4 and Cys20, and Cys21, indicating that geographutoxin I has a rigid conformation consisting of three loops stabilized by these three disulfide linkages.

Geographutoxin-sensitive and insensitive sodium currents in mouse skeletal muscle developing in situ

1. The whole-cell voltage-clamp technique was used to examine developmental changes of Na+ current properties in single fibres of mouse flexor digitorum brevis muscles developing in situ from birth to 20 days post-natal. 2. Geographutoxin II (GTX II), a novel polypeptide toxin from the marine snail Conus geographus, distinguished two different types of voltage-sensitive Na+ currents: GTX II-sensitive and GTX II-insensitive currents, which corresponded respectively to currents with high or low TTX sensitivity. 3. Voltage-dependent activation and inactivation of the GTX II-insensitive currents occurred at membrane potentials 10-20 mV more negative than those for the GTX II-sensitive currents. 4. The GTX II-insensitive current in fibres from mice older than 8 days inactivated more slowly than the GTX II-sensitive current. However, in fibres from younger mice, the two currents decayed with similar speed. 5. The mean specific Na+ conductance (gNa) for the total (GTX II-sensitive plus GTX II-insensitive) Na+ channels was 0.22 mS/muF at a Na+ concentration of 5 mM at birth. The total gNa increased 6-fold to 1.32 mS/muF during the first 20 days after birth. 6. The mean specific gNa for the GTX II-insensitive channels was 0.15 mS/muF at birth, remained at approximately the same level for the first 8 days, and then decreased progressively to become undetectable by day 16. 7. In muscle fibres denervated 12 days after birth, the GTX II-insensitive gNa increased over the next 8 days, whereas the total gNa increased less than normal. 8. By contrast, in fibres denervated on day 4, the total gNa increased more than normal in the following 8 days, and the GTX II-insensitive specific gNa increased above the level seen at birth. 9. Half-maximal activation and inactivation potentials of the total and the GTX II-insensitive currents shifted in the negative direction by 9-17 mV in the first 8 days after birth. 10. We conclude that the regulatory effects of innervation on the total gNa are either suppressive or enhancing depending on the stage of development. On the other hand, denervation elicits an increase in GTX II-insensitive Na+ currents at all ages studied.

Use of geographutoxin II (mu-conotoxin) for the study of neuromuscular transmission in mouse

1. Endplate potentials (e.p.ps) were investigated in the presence of geographutoxin II (GTXII) in the mouse phrenic nerve diaphragm preparation. This toxin preferentially blocks muscle Na+ channels which allows the study of e.p.ps in the absence of nicotinic receptor antagonists or substances to depress acetylcholine release. 2. GTXII abolished muscle action potentials and antagonized the depolarization of the muscle membrane produced by the crotamine-induced opening of Na+ channels. 3. E.p.ps as large as 19-25 mV were observed after 2-4 micrograms ml-1 GTXII. These concentrations of GTXII did not cause discernible changes of resting membrane potential and frequency and amplitude of miniature e.p.ps. 4. Lower concentrations (1-2 micrograms ml-1) of GTXII caused incomplete blockade of the muscle Na+ channel resulting in exaggerated 'e.p.ps', while higher concentrations of GTXII (8 micrograms ml-1) abolished e.p.ps by a prejunctional effect. 5. Trains of e.p.ps on repetitive stimulation after GTXII neither ran down, as in tubocurarine-treated preparations, nor facilitated, as in low Ca2+ and/or high Mg2+-treated preparations, and were indistinguishable from those of untreated cut muscle preparation. 6. In cut muscle preparations, GTXII did not affect the rise and decay times, amplitude or rundown of e.p.ps. 7. It is concluded that GTXII is a useful agent for studying neuromuscular transmission. This method provides e.p.ps which are neither attenuated nor modified because manipulations that alter transmitter release and postjunctional receptor responses are avoided.

mu-conotoxin GIIIA, a peptide ligand for muscle sodium channels: chemical synthesis, radiolabeling, and receptor characterization

The peptide conotoxin GIIIA from Conus geographus L. venom, which specifically blocks sodium channels in muscle, has been synthesized by a solid-phase method. The three disulfide bridges were formed by air oxidation. After HPLC purification, the synthetic product was shown to be identical with the native conotoxin GIIIA from Conus geographus. A high specific activity, 125I derivative of mu-conotoxin was prepared and used for binding assays to the Na channel from Electrophorus electric organ. Specific binding could be abolished by competition with tetrodotoxin. The radiolabeled toxin was specifically cross-linked to the Na channel. These studies demonstrate that mu-conotoxin GIIIA can be used to define the guanidinium toxin binding site and will be a useful ligand for understanding functionally important differences between Na channel subtypes.

Preferential block of skeletal muscle sodium channels by geographutoxin II, a new peptide toxin from Conus geographus

The effects of geographutoxin II (GTX II), a novel polypeptide toxin isolated from the marine snail Conus geographus, on nerves and muscles were studied by current clamp and voltage clamp techniques. GTX II (5 X 10(-7) M) abolished the action potential of the guinea pig skeletal muscle without change in the resting potential. However, action potentials of the crayfish giant axon, mouse neuroblastoma N1E-115 cell and guinea pig cardiac muscle were not affected by GTX II even at concentrations higher than 1 X 10(-6) M. In the voltage clamped bullfrog skeletal muscle fiber, sodium currents were almost completely blocked by GTX II (1 X 10(-6) M), and slowly recovered after washout. The time course of sodium currents was not appreciably altered by GTX II. These results suggest that GTX II selectively blocks skeletal muscle sodium channels in much the same way as tetrodotoxin.

[Venomous animals and their venoms]

Animal venoms have aroused great interest during the past decades. During recent years, especially substances from marine animals have been investigated, not only in regard to their chemical structures but also to their biological relevance. Neurotoxic peptides from scorpions opened new aspects of action mechanisms on cell membranes; from snake venoms also ingredients have been obtained which serve as valuable pharmaceutical drugs.

Blockade of [3H]lysine-tetrodotoxin binding to sodium channel proteins by conotoxin GIII

Conotoxin GIII from Conus geographus inhibited the binding of [3H]lysine-tetrodotoxin (4 nM) to electroplax membranes from Electrophorus electricus and to the rat brain P2 fraction with IC50 values of 13 nM and 7.9 microM, respectively. This inhibition observed with electroplax membranes was irreversible. These and physiological findings (Life Sci., 21 (1977) 1759-1770 suggest that conotoxin GIII inhibits Na channel activation by its interaction with the tetrodotoxin binding site of the Na channel. The differences in structures related to the activation of Na channels between the eel electroplax and the rat brain are indicated.

Peptide neurotoxins from fish-hunting cone snails

To paralyze their more agile prey, the venomous fish-hunting cone snails (Conus) have developed a potent biochemical strategy. They produce several classes of toxic peptides (conotoxins) that attack a series of successive physiological targets in the neuromuscular system of the fish. The peptides include presynaptic omega-conotoxins that prevent the voltage-activated entry of calcium into the nerve terminal and release of acetylcholine, postsynaptic alpha-conotoxins that inhibit the acetylcholine receptor, and muscle sodium channel inhibitors, the mu-conotoxins, which directly abolish muscle action potentials. These distinct peptide toxins share several common features: they are relatively small (13 to 29 amino acids), are highly cross-linked by disulfide bonds, and strongly basic. The fact that they inhibit sequential steps in neuromuscular transmission suggests that their action is synergistic rather than additive. Five new omega-conotoxins that block presynaptic calcium channels are described. They vary in their activity against different vertebrate classes, and also in their actions against different synapses from the same animal. There are susceptible forms of the target molecule in peripheral synapses of fish and amphibians, but those of mice are resistant. However, the mammalian central nervous system is clearly affected, and these toxins are thus of potential significance for investigating the presynaptic calcium channels.

A sleep-inducing peptide from Conus geographus venom

A novel peptide toxin, which causes a sleep-like state upon intracerebral injection in mice, has been purified to homogeneity from the venom of the piscivorous marine snail Conus geographus L. It elicits no obvious effects when injected i.p. into either mice or fish. The purified toxin is a highly acidic heptadecapeptide with no cystine residues (Lys1, Arg1, Asx2, Ser1, Glx7-8, Gly1, Ile1, Leu2). This composition is in marked contrast to those of other conotoxins, which are basic and disulphide-bridged. The N-terminal residue is Gly and the COOH-terminal sequence is Ser-Asn-NH2.