Molecular phylogeny, classification and evolution of conopeptides.

Conopeptides are toxins expressed in the venom duct of cone snails (Conoidea, Conus). These are mostly well-structured peptides and mini-proteins with high potency and selectivity for a broad range of cellular targets. In view of these properties, they are widely used as pharmacological tools and many are candidates for innovative drugs. The conopeptides are primarily classified into superfamilies according to their peptide signal sequence, a classification that is thought to reflect the evolution of the multigenic system. However, this hypothesis has never been thoroughly tested. Here we present a phylogenetic analysis of 1,364 conopeptide signal sequences extracted from GenBank. The results validate the current conopeptide superfamily classification, but also reveal several important new features. The so-called "cysteine-poor" conopeptides are revealed to be closely related to "cysteine-rich" conopeptides; with some of them sharing very similar signal sequences, suggesting that a distinction based on cysteine content and configuration is not phylogenetically relevant and does not reflect the evolutionary history of conopeptides. A given cysteine pattern or pharmacological activity can be found across different superfamilies. Furthermore, a few conopeptides from GenBank do not cluster in any of the known superfamilies, and could represent yet-undefined superfamilies. A clear phylogenetically based classification should help to disentangle the diversity of conopeptides, and could also serve as a rationale to understand the evolution of the toxins in the numerous other species of conoideans and venomous animals at large.

New conopeptides of the D-superfamily selectively inhibiting neuronal nicotinic acetylcholine receptors.

The venom of cone snails (Conus spp.) is a rich source of peptides exhibiting a wide variety of biological activities. Several of these conopeptides are neuronal nicotinic acetylcholine receptor (nAChR) antagonists and belong to the A-, M-, S-, C and the recently described D-superfamily (alphaD-conopeptides). Here we describe the discovery and characterization of two alphaD-conopeptides isolated from the venom of Conus mustelinus and Conus capitaneus. Their primary structure was determined by Edman degradation, MS/MS analysis and by a PCR based approach. These peptides show close structural homology to the alphaD-VxXIIA, -B and -C conopeptides from the venom of Conus vexillum and are dimers (about 11kDa) of similar or identical peptides with 49 amino acid residues and a characteristic arrangement of ten conserved cysteine residues. These novel types of conopeptides specifically block neuronal nAChRs of the alpha7, alpha3beta2 and alpha4beta2 subtypes in nanomolar concentrations. Due to their high affinity, these new ligands may provide a tool to decipher the localisation and function of the various neuronal nAChRs.

A new omega-conotoxin that targets N-type voltage-sensitive calcium channels with unusual specificity.

A new specific voltage-sensitive calcium channel (VSCC) blocker has been isolated from the venom of the fish-hunting cone snail Conus consors. This peptide, named omega-Ctx CNVIIA, consists of 27 amino acid residues folded by 3 disulfide bridges. Interestingly, loop 4, which is supposed to be crucial for selectivity, shows an unusual sequence (SSSKGR). The synthesis of the linear peptide was performed using the Fmoc strategy, and the correct folding was achieved in the presence of guanidinium chloride, potassium buffer, and reduced/oxidized glutathione at 4 degrees C for 3 days. Both synthetic and native toxin caused an intense shaking activity, characteristic of omega-conotoxins targeting N-type VSCC when injected intracerebroventricularly to mice. Binding studies on rat brain synaptosomes revealed that the radioiodinated omega-Ctx CNVIIA specifically and reversibly binds to high-affinity sites with a K(d) of 36.3 pM. Its binding is competitive with omega-Ctx MVIIA at low concentration (K(i) = 2 pM). Moreover, omega-Ctx CNVIIA exhibits a clear selectivity for N-type VSCCs versus P/Q-type VSCCs targeted respectively by radioiodinated omega-Ctx GVIA and omega-Ctx MVIIC. Although omega-Ctx CNVIIA clearly blocked N-type Ca(2+) current in chromaffin cells, this toxin did not inhibit acetylcholine release evoked by nerve stimuli at the frog neuromuscular junction, in marked contrast to omega-Ctx GVIA. omega-Ctx CNVIIA thus represents a new selective tool for blocking N-type VSCC that displays a unique pharmacological profile and highlights the diversity of voltage-sensitive Ca(2+) channels in the animal kingdom.

Moving pieces in a proteomic puzzle: mass fingerprinting of toxic fractions from the venom of Tityus serrulatus (Scorpiones, Buthidae).

Scorpion venoms are very complex mixtures of molecules, most of which are peptides that display different kinds of biological activity. These venoms have been studied in the light of their pharmacological targets and their constituents are able to bind specifically to a variety of ionic channels located in prey tissues, resulting in neurotoxic effects. Toxins that modulate Na(+), K(+), Ca(++) and Cl(-) currents have been described in scorpion venoms. Mass spectrometry was employed to analyze toxic fractions from the venom of the Brazilian scorpion Tityus serrulatus in order to shed light on the molecular composition of this venom and to facilitate the search for novel pharmacologically active compounds. T. serrulatus venom was first subjected to gel filtration to separate its constituents according to their molecular size. The resultant fractions II and III, which account for 90 and 10% respectively of the whole venom toxic effect, were further analyzed by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS), on-line liquid chromatography/electrospray mass spectrometry (LC/ESMS) and off-line LC/MALDI-TOFMS in order to establish their mass fingerprints. The molecular masses in fraction II were predominantly between 6500 and 7500 Da. This corresponds to long-chain toxins that mainly act on voltage-gated Na(+) channels. Fraction III is more complex and predominantly contained molecules with masses between 2500 and 5000 Da. This corresponds to the short-chain toxin family, most of which act on K(+) channels, and other unknown peptides. Finally, we were able to measure the molecular masses of 380 different compounds present in the two fractions investigated. To our knowledge, this is the largest number of components ever detected in the venom of a single animal species. Some of the toxins described previously from T. serrulatus venom could be detected by virtue of their molecular masses. The interpretation of this large set of data has provided us with useful proteomic information on the venom, and the implications of these findings are discussed.

A new conotoxin isolated from Conus consors venom acting selectively on axons and motor nerve terminals through a Na+-dependent mechanism.

A novel conotoxin was isolated and characterized from the venom of the fish-hunting marine snail Conus consors. The peptide was identified by screening chromatography fractions of the crude venom that produced a marked contraction and extension of the caudal and dorsal fins in fish, and noticeable spontaneous contractions of isolated frog neuromuscular preparations. The peptide, named CcTX, had 30 amino acids and the following scaffold: X11CCX7CX2CXCX3C. At the frog neuromuscular junction, CcTx at nanomolar concentrations selectively increased nerve terminal excitability so that a single nerve stimulation triggered trains of repetitive or spontaneous synaptic potentials and action potentials. In contrast, CcTx had no noticeable effect on muscle excitability even at concentrations 100 x higher than those that affected motor nerve terminals, as revealed by direct muscle stimulation. In addition, CcTx increased miniature endplate potential (MEPP) frequency in a Ca2+-free medium supplemented with ethylene glycol-bis-(beta-aminoethyl ether)-N,N,N', N'-tetraacetic acid (EGTA). Blockade of voltage-dependent sodium channels with tetrodotoxin (TTX) either prevented or suppressed the increase of MEPP frequency induced by the toxin. CcTx also produced a TTX-sensitive depolarization of the nodal membrane in single myelinated axons giving rise, in some cases, to repetitive and/or spontaneous action potential discharges. In addition, CcTx increased the nodal volume of myelinated axons, as determined using confocal laser scanning microscopy. This increase was reversed by external hyperosmolar solutions and was prevented by pretreatment of axons with TTX. It is suggested that CcTx, by specifically activating neuronal voltage-gated sodium channels at the resting membrane potential, produced Na+ entry into nerve terminals and axons without directly affecting skeletal muscle fibres. CcTx belongs to a novel family of conotoxins that targets neuronal voltage-gated sodium channels.

The strategy used by some piscivorous cone snails to capture their prey: the effects of their venoms on vertebrates and on isolated neuromuscular preparations.

Three piscivorous Conus species, C. ermineus, C. consor and C. catus were acclimatized in aquaria. The study of their strategy to capture the prey and details of their radula's morphology revealed that all of them used a 'hook and line' strategy which consists of immobilizing the prey rapidly before engulfing it. The venoms from these piscivorous species clearly elicit, when injected into fish, an excitotoxic shock characterized by a sudden tetanus of the prey. In mammals, the venoms induce both flaccid paralysis via i.p. injection and seizures via i.c.v. injection. Intracellular recordings from frog nerve-muscle preparations revealed that the venoms from these Conus species first caused spontaneous synaptic potentials which in turn triggered muscle action potentials. Such spontaneous activity is due to an increased nerve terminal excitability. In addition, the venoms suppressed neuromuscular transmission probably by blocking postsynaptic nicotinic acetylcholine receptors. No direct effect of these Conus venoms was observed on the membrane of skeletal muscle fibres. In conclusion, C. ermineus, C. consor and C. catus, which have not securely tethered their prey used a mixture of toxins which target both pre-and postsynaptic elements of the neuromuscular junction and which produce rapid immobilization of their prey.

Biochemical characterization and nuclear magnetic resonance structure of novel alpha-conotoxins isolated from the venom of Conus consors.

Two novel alpha-conotoxins were purified and characterized from the venom of the fish-hunting cone snail Conus consors. These peptides were identified by screening HPLC fractions of the crude venom and by binding experiments with Torpedo nicotinic acetylcholine receptor. The toxins named alpha-CnIA and alpha-CnIB exhibited sequences of 14 and 12 amino acids, respectively. The alpha-CnIA represents the main alpha-conotoxin contained in the venom, whereas alpha-CnIB is present in a relatively small amount. Chemical synthesis of alpha-CnIA was carried out using the Fmoc methodology by selective disulfide bond formation. The biological activity of the toxin was assessed in fish and mice. The alpha-CnIA inhibited the fixation of iodinated alpha-bungarotoxin to Torpedo nicotinic acetylcholine receptors with an IC50 of 0.19 microM which can be compared to the IC50 of 0.31 microM found for the previously characterized alpha-MI isolated from the piscivorous Conus magus. The synthetic alpha-CnIA blocked spontaneous and evoked synaptic potentials in frog and mouse isolated neuromuscular preparations at sub-micromolar concentrations. Solution NMR of this toxin indicated a conformational heterogeneity with the existence of different conformers in solution, at slow and intermediate exchange rates relative to the NMR chemical shift time scale, similar to that reported for alpha-GI and alpha-MI. NMR structures were calculated for the major NMR signals representing more than 80% of the population at 5 degrees C.

[Conus venoms: a source of toxins which interact with membrane- potential-dependent sodium channels]. / Les venins de cônes: source de toxines qui interagissent avec les canaux sodium dépendant du potentiel de membrane.

Marine snails of the genus Conus, as they are carnivorous predators, have a venom apparatus used to capture their prey. The toxins contained in the venoms of Conidae, called conotoxins, are of a particular high degree of diversity and represent powerful tools in the neuroscience field. Indeed, these toxins specifically bind with a high affinity to receptors and ionic channels. Therefore, they provide original pharmacological tools which receive increasing investigation both to identify and study some functions of the nervous systems and to characterize new types and closely related subtypes of receptors or ionic channels. The voltage-gated sodium channel, because of its fundamental role in cell membrane excitability, is the specific target of a large number of animal and vegetal toxins. Actually, at least seven toxin receptor sites have been identified on this channel-protein. These toxins, and in particular conotoxins, are used to precise the role of different types and/or closely related subtypes of sodium channels in the peripheral and central nervous systems. The focus of the present review is to summarize our current knowledge of the consequences of physiological interactions between different conotoxin families and sodium channels.

A review on conotoxins targeting ion channels and acetylcholine receptors of the vertebrate neuromuscular junction.

In this article we present an overview of some peptides extracted and purified from the venom of marine snails of the genus Conus. These active peptides named conotoxins can be used as research tools to target voltage-gated ion channels as well as ligand-gated receptors. Because of their relatively small size, conotoxins can be chemically synthesized and made widely available. In this review we focus on conotoxins that target voltage-sensitive sodium channels, voltage-dependent calcium channels and nicotinic acetylcholine receptors of the vertebrate neuromuscular junction. Emphasis is given on summarizing our current knowledge of their primary structure and their specific pharmacological actions at the pre- and the post-synaptic level of the neuromuscular junction. Evidence is presented for conotoxins that discriminate between pre- and post-synaptic voltage-gated sodium channels. Among these peptides, the mu-conotoxin family is well characterized by its ability to block selectively sodium channels in skeletal muscle fibres without affecting axonal and nerve terminal Na+ channels. Furthermore, new conotoxins like Conus consors toxin (CcTx) and conotoxin EVIA selectively target Na+ channels in axons and nerve terminals without affecting skeletal muscle fibres. omega-conotoxins known as highly potent and selective blockers of voltage-sensitive calcium channels have proven to be valuable in determining the roles of the various subtypes of channels involved in acetylcholine release from motor nerve endings. Finally, Conus peptides which act at muscle nicotinic acetylcholine receptors constitute the most extensive characterized family of conopeptides that exhibit sequence similarity, different structural motifs and surprising diversity in their competitive and non-competitive actions.

A review on conotoxins targeting ion channels and acetylcholine receptors of the vertebrate neuromuscular junction

In this article we present an overview of some peptides extracted and purified from the venom of marine snails of the genus Conus. These active peptides named conotoxins can be used as research tools to target voltage-gated ion channels as well as ligand-gated receptors. Because of their relatively small size, conotoxins can be chemically synthesized and made widely available. In this review we focus on conotoxins that target voltage-sensitive sodium channels, voltage-dependent calcium channels and nicotinic acetylcholine receptors of the vertebrate neuromuscular junction. Emphasis is given on summarizing our current knowledge of their primary structure and their specific pharmacological actions at the pre- and the post-synaptic level of the neuromuscular junction. Evidence is presented for conotoxins that discriminate between pre- and post-synaptic voltage-gated sodium channels. Among these peptides, the mu-conotoxin family is well characterized by its ability to block selectively sodium channels in skeletal muscle fibres without affecting axonal and nerve terminal Na+ channels. Furthermore, new conotoxins like Conus consors toxin (CcTx) and conotoxin EVIA selectively target Na+ channels in axons and nerve terminals without affecting skeletal muscle fibres. omega-conotoxins known as highly potent and selective blockers of voltage-sensitive calcium channels have proven to be valuable in determining the roles of the various subtypes of channels involved in acetylcholine release from motor nerve endings. Finally, Conus peptides which act at muscle nicotinic acetylcholine receptors constitute the most extensive characterized family of conopeptides that exhibit sequence similarity, different structural motifs and surprising diversity in their competitive and non-competitive actions.

Use of newly designed microperifusion system with amperometric sensors for near-continuous on-line monitoring of hormone secretion. I. correlation with the luteinizing hormone secretory response to gonadotropin-releasing hormone.

LH is rapidly secreted from the anterior pituitary gland in response to episodic release of GnRH. To understand better the detailed dynamics of this secretory process and related time- and dose-dependent effects, we developed a microperifusion system able to preserve resolution of dynamic secretory responses by minimizing dispersion and with capabilities for automation and continuous on-line monitoring. To monitor secretion at a frequency greater than that feasible with discrete samples, we determined whether LH or another molecule cosecreted by anterior pituitary cells could be monitored on a near-continuous basis using amperometric electrochemical sensors operated under conditions of cyclic voltammetry. The developed culture system incorporated a 32-mu l cell chamber in a controllable constant environment. Miniature sensors were positioned immediately adjacent to the cells to permit differential measurements of the input and effluent streams of medium. With the system, square wave pulses of electrochemically active, biologically inert molecules, e.g. ascorbate and phenol red, showed similar redox profiles before and after the cells, with minimal dispersion. Enzymatically dispersed ovine anterior pituitary cells were cultured on SoloHill glass beads for 4 days, loaded into the chamber, and perifused with DMEM containing 10% FCS for 2 h. After stabilization, the medium was switched to protein-free, HEPES-buffered HBSS with L-glutamine and allowed to flow for a 1-h washout period, followed by GnRH challenges of varying concentrations in a random order. Perifusate was collected in six-drop fractions at approximately 30-sec intervals. Although LH, its individual subunits, and FSH could not be detected amperometrically, GnRH stimulation of the cells simultaneously induced a several log order dose-dependent secretion of both an electrochemically detectable molecule and LH, as measured by RIA. The secretory profiles of the amperometrically detected signal and immunoactive LH were very similar. Dose-response relationships of the amperometric signal and LH to a wide range of GnRH were similar. The responses of both secreted LH and the amperometric signaling molecule(s) to GnRH were triphasic; an initial peak of activity was observed within 20-40 sec, a lower plateau level was observed for the duration of the 4-min GnRH stimulation, and a gradual return to baseline followed. The cells then maintained a constant level of GnRH-independent basal secretion. These results indicate that it is feasible to monitor the complex dynamics of endocrine and cellular responsiveness to secretagogues from endocrine cells/tissues continuously in real-time.

The enzymatic estimation of organic hydroperoxides in the rat retina.

An enzymatic procedure for the estimation of organic hydroperoxides has been adapted to biological tissues and applied to the measurement of hydroperoxides in the rat retina. Hydroperoxides are determined from the coupled activities of glutathione peroxidase and glutathione reductase as measured by the loss of NADPH absorbance. To minimize the effects of tissue catalyzed peroxide degradation, incubations were performed in the presence of 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU); which inhibited the activity of retinal tissue glutathione reductase by 85%. For comparisons to the enzymatic technique, retinal tissue hydroperoxides were also estimated by the absorption of tissue extracts at 232 nm. Using the enzymatic procedure the hydroperoxide concentration in whole retina homogenates was significantly higher in 19-day-old rats than in either 35-day or adult animals. Hydroperoxides in the retina of young rats exposed to light for one hour were significantly lower than in non-exposed controls, while in adult rats, following light, hydroperoxides increased 13%. Fractionation of rat retinas into crude ROS and retina minus ROS components revealed that the ROS fractions contain at least twice the hydroperoxide concentration of the remaining retina. The concentration of hydroperoxides in the ROS fractions from dark-reared rats were significantly lower than in cyclic-light-reared animals. In both types of rats, one hour intense light exposure resulted in an increase in ROS hydroperoxides but the increases were not significant. ROS hydroperoxides were also found to be 85-90% water soluble. Estimates of the retinal hydroperoxide content obtained by absorption at 232 nm gave similar results to the enzymatic technique, but the levels were significantly lower. When retinas were maintained in vitro for one hour before analysis, hydroperoxides determined by either technique were significantly higher than in retinas assayed immediately, but A232 hydroperoxides were still significantly lower than hydroperoxides measured by the enzymatic procedure. It is concluded: (1) that the observed retinal hydroperoxide concentration depends upon animal age and the method of measurement; (2) that within the retina the photoreceptor cell contains at least a two-fold higher concentration of hydroperoxides than the remaining retina and that prior light history can affect those hydroperoxide levels (it appears that the photoreceptor cell is also a major site of hydroperoxide formation in the retina); (3) that during intense light exposure of short duration significant levels of hydroperoxides do not accumulate in the retinas of rats.