Boiga dendrophila (mangrove catsnake) is a colubrid snake that lives in Southeast Asian lowland rainforests and mangrove swamps and that preys primarily on birds. We have isolated, purified, and sequenced a novel toxin from its venom, which we named denmotoxin. It is a monomeric polypeptide of 77 amino acid residues with five disulfide bridges. In organ bath experiments, it displayed potent postsynaptic neuromuscular activity and irreversibly inhibited indirectly stimulated twitches in chick biventer cervicis nerve-muscle preparations. In contrast, it induced much smaller and readily reversible inhibition of electrically induced twitches in mouse hemidiaphragm nerve-muscle preparations. More precisely, the chick muscle ␣ 1 ␥␦-nicotinic acetylcholine receptor was 100-fold more susceptible compared with the mouse receptor. These data indicate that denmotoxin has a bird-specific postsynaptic activity. We chemically synthesized denmotoxin, crystallized it, and solved its crystal structure at 1.9 Å by the molecular replacement method. The toxin structure adopts a non-conventional three-finger fold with an additional (fifth) disulfide bond in the first loop and seven additional residues at its N terminus, which is blocked by a pyroglutamic acid residue. This is the first crystal structure of a three-finger toxin from colubrid snake venom and the first fully characterized bird-specific toxin. Denmotoxin illustrates the relationship between toxin specificity and the primary prey type that constitutes the snake's diet. Three-finger toxins (3FTXs)3 form one of the most abundant, well recognized families of snake venom proteins. They share a similar structure and are characterized by three -stranded finger-like loops, emerging from a globular core and stabilized by four conserved disulfide bridges. An additional disulfide linkage may sometimes be present in the first (non-conventional toxins) or second (long-chain ␣-neurotoxins and -toxins) loop (1-5). All 3FTXs are monomers except for -toxins, which are noncovalent homodimers isolated from Bungarus venoms. Minor structural differences in the three-finger fold, viz. the number of -strands, overall morphology of the loops, and differential lengths of turns or C-terminal tails (6), lead to the recognition of varied targets and modulate the toxicity and specificity (7). Hence, 3FTXs affect a broad range of molecular targets, including ␣ 1 -nicotinic acetylcholine receptors (nAChRs; short-and longchain ␣-neurotoxins), ␣ 7 -nAChRs (long-chain ␣-neurotoxins), and ␣ 3 -and ␣ 4 -nAChRs (-toxins) (4, 5); muscarinic acetylcholine receptors (muscarinic toxins) (8); L-type calcium channels (calciseptine and FS2 toxin) (9, 10); integrin ␣ IIb  3 (dendroaspin) (11, 12); integrin ␣ v  3 (cardiotoxin A5) (13); acetylcholinesterase (fasciculins) (14); phospholipids and glycosphingolipids (cardiotoxins) (15); and blood coagulation protein factor VIIa (16). As the interaction with such a broad spectrum of target proteins results in a variety of pharmacological effects, the understanding...
Two muscarinic toxins, MT1 and MT7, were obtained by onestep solid-phase synthesis using the 9-fluorenylmethoxycarbonyl-based method. The synthetic and natural toxins, isolated from the snake venom or recombinantly expressed, display identical physicochemical properties and pharmacological profiles. High protein recovery allowed us to specify the selectivity of these toxins for various muscarinic receptor subtypes. Thus, sMT7 has a selectivity for the M 1 receptor that is at least 20,000 times that for the other subtypes. The stability of the toxinreceptor complexes indicates that sMT1 interacts reversibly with the M 1 receptor, unlike sMT7, which binds it quasi-irreversibly. The effect of the synthetic toxins on the atropineinduced [3 H]N-methylscopolamine (NMS) dissociation confirms that sMT7 targets the allosteric site on the M 1 receptor, whereas sMT1 seems interact on the orthosteric one. The great decreases in the binding potencies observed after the R34A modification in sMT1 and sMT7 toxins highlight the functional role of this conserved residue in their interactions with the M 1 receptor. Interestingly, after the R34A modification, the sMT7 toxin binds reversibly on the M 1 receptor. Furthermore, the potency of sMT7-R34A for the NMS-occupied receptor is lower compared with unmodified toxin, supporting the role of this residue in the allosteric interaction of sMT7. All these results and the different charge distributions observed at the two toxin surfaces of their structure models support the hypothesis that the two toxins recognize the M 1 receptor differently.
Nicotinic acetylcholine receptors (nAChR) are expressed on normal bronchial epithelial and nonsmall cell lung cancer (NSCLC) cells and are involved in cell growth regulation. Nicotine induced cell proliferation. The purpose of this study was to determine if interruption of autocrine nicotinic cholinergic signaling might inhibit A549 NSCLC cell growth. For this purpose α‐Cobratoxin (α‐CbT), a high affinity α7‐nAChR antagonist was studied. Cell growth decrease was evaluated by Clonogenic and MTT assays. Evidence of apoptosis was identified staining cell with Annexin‐V/PI. Characterization of the basal NF‐κB activity was done using the Trans‐AM NF‐κB assay colorimetric kit. “In vivo” antitumour activity was evaluated in orthotopically transplanted nude mice monitored by In vivo Imaging System technology. α‐CbT caused concentration‐dependent cell growth decrease, mitochondrial apoptosis caspases‐9 and 3‐dependent, but caspase‐2 and p53‐independent and down‐regulation of basal high levels of activated NF‐κB. α‐CbT treatment determines a significant reduction of tumor growth in nude mice orthotopically engrafted with A549‐luciferase cells (4.6% of living cells vs. 31% in untreated mice). No sign of toxicity was reported related to treatment. These findings suggest that α7‐nAChR antagonists namely α‐CbT may be useful adjuvant for treatment of NSCLC and potentially other cancers. © 2007 Wiley‐Liss, Inc.
Polycystic kidney diseases (PKDs) are genetic disorders that can cause renal failure and death in children and adults. Lowering cAMP in cystic tissues through the inhibition of the type-2 vasopressin receptor (V2R) constitutes a validated strategy to reduce disease progression. We identified a peptide from green mamba venom that exhibits nanomolar affinity for the V2R without any activity on 155 other G-protein-coupled receptors or on 15 ionic channels. Mambaquaretin-1 is a full antagonist of the V2R activation pathways studied: cAMP production, beta-arrestin interaction, and MAP kinase activity. This peptide adopts the Kunitz fold known to mostly act on potassium channels and serine proteases. Mambaquaretin-1 interacts selectively with the V2R through its first loop, in the same manner that aprotinin inhibits trypsin. Injected in mice, mambaquaretin-1 increases in a dose-dependent manner urine outflow with concomitant reduction of urine osmolality, indicating a purely aquaretic effect associated with the in vivo blockade of V2R. CD1-pcy/pcy mice, a juvenile model of PKD, daily treated with 13 [Formula: see text]g of mambaquaretin-1 for 99 d, developed less abundant (by 33%) and smaller (by 47%) cysts than control mice. Neither tachyphylaxis nor apparent toxicity has been noted. Mambaquaretin-1 represents a promising therapeutic agent against PKDs.
Mambalgins are peptides isolated from mamba venom that specifically inhibit a set of acid-sensing ion channels (ASICs) to relieve pain. We show here the first full stepwise solid phase peptide synthesis of mambalgin-1 and confirm the biological activity of the synthetic toxin both in vitro and in vivo. We also report the determination of its three-dimensional crystal structure showing differences with previously described NMR structures. Finally, the functional domain by which the toxin inhibits ASIC1a channels was identified in its loop II and more precisely in the face containing Phe-27, Leu-32, and Leu-34 residues. Moreover, proximity between Leu-32 in mambalgin-1 and Phe-350 in rASIC1a was proposed from double mutant cycle analysis. These data provide information on the structure and on the pharmacophore for ASIC channel inhibition by mambalgins that could have therapeutic value against pain and probably other neurological disorders.
Background and purpose: Venoms are a rich source of ligands for ion channels, but very little is known about their capacity to modulate G-protein coupled receptor (GPCR) activity. We developed a strategy to identify novel toxins targeting GPCRs. Experimental approach: We studied the interactions of mamba venom fractions with a1-adrenoceptors in binding experiments with 3 H-prazosin. The active peptide (AdTx1) was sequenced by Edman degradation and mass spectrometry fragmentation. Its synthetic homologue was pharmacologically characterized by binding experiments using cloned receptors and by functional experiments on rabbit isolated prostatic smooth muscle. Key results: AdTx1, a 65 amino-acid peptide stabilized by four disulphide bridges, belongs to the three-finger-fold peptide family. It has subnanomolar affinity (Ki = 0.35 nM) and high specificity for the human a1A-adrenoceptor subtype. We showed high selectivity and affinity (Kd = 0.6 nM) of radio-labelled AdTx1 in direct binding experiments and revealed a slow association constant (kon = 6 ¥ 10) with an unusually stable a1A-adrenoceptor/AdTx1 complex (t1/2diss = 3.6 h). AdTx1 displayed potent insurmountable antagonism of phenylephrine's actions in vitro (rabbit isolated prostatic muscle) at concentrations of 10 to 100 nM. Conclusions and implications:AdTx1 is the most specific and selective peptide inhibitor for the a1A-adrenoceptor identified to date. It displays insurmountable antagonism, acting as a potent relaxant of smooth muscle. Its peptidic nature can be exploited to develop new tools, as a radio-labelled-AdTx1 or a fluoro-labelled-AdTx1. Identification of AdTx1 thus offers new perspectives for developing new drugs for treating benign prostatic hyperplasia.
Muscarinic toxins isolated from the venom of Dendroaspis snakes may interact with a high affinity, large selectivity and various functional properties with muscarinic receptors. Therefore, these toxins are invaluable tools for studying the physiological role, molecular functioning and structural organization of the five subtypes of these G-Protein Coupled Receptors. We review the data on the most relevant results dealing with the isolation/identification, mode of action, structure/function and exploitation of these toxins and finally highlight the unresolved issues related to their pharmacological studies.
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