“Weak Toxin” from Naja kaouthia Is a Nontoxic Antagonist of α7 and Muscle-type Nicotinic Acetylcholine Receptors

Utkin, Yuri N.; Kukhtina, Viktoriya V.; Kryukova, Elena V.; Chiodini, Florence; Bertrand, Daniel; Methfessel, Christoph; Tsetlin, Victor I.

doi:10.1074/jbc.m100788200

Cited by 111 publications

(102 citation statements)

References 39 publications

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“…One such toxin, candoxin from Bungarus candidus, blocks both the muscle and ␣7 nAChRs with nanomolar affinity (35), whereas another non-conventional toxin, weak toxin from the cobra Naja kaouthia, acts on these receptors only with micromolar affinity (36). Thus, ws-LYNX1 in terms of affinities for nAChRs is close to weak toxin, but this toxin still shows virtual irreversibility of action (36). Interestingly, a common feature of ws-LYNX1 and weak toxin is their action on muscarinic acetylcholine receptors (3, 37).…”

Section: Discussionmentioning

confidence: 99%

Water-soluble LYNX1 Residues Important for Interaction with Muscle-type and/or Neuronal Nicotinic Receptors

Lyukmanova

Shulepko

Buldakova

et al. 2013

Journal of Biological Chemistry

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Background: Information was not available about prototoxin LYNX1 amino acid residues involved in binding to muscle and neuronal nicotinic receptors. Results: A series of water-soluble LYNX1 (ws-LYNX1) mutants was obtained and their interaction with nicotinic receptors was analyzed. Conclusion: There are both common and selective ws-LYNX1 residues recognizing distinct receptor types. Significance: For the first time, several functionally important residues in ws-LYNX1 are identified.

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Section: Discussionmentioning

confidence: 99%

Water-soluble LYNX1 Residues Important for Interaction with Muscle-type and/or Neuronal Nicotinic Receptors

Lyukmanova

Shulepko

Buldakova

et al. 2013

Journal of Biological Chemistry

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“…However, electrophysiological studies have revealed that a -bungarotoxin (IC 50 approximately 5 nM) produced an irreversible block of muscle (a 1) 2 b1gd receptors (68), whereas candoxin (IC 50 approximately 10 nM) produced a reversible blockade of the same receptor (58). Furthermore, WTX (Naja kaouthia), a non-conventional toxin that is structurally similar to candoxin but a 1000-fold weaker antagonist of muscle nAChRs, is almost irreversible in its action (54). Therefore, the reversibility of a -neurotoxin action at the neuromuscular junction is not always a reflection of their binding affinity to the receptor and may perhaps be associated with a specific area of interaction on the toxin molecule, distinct from the receptor recognition site (67).…”

Section: Pharmacology Of Three-finger A-neurotoxinsmentioning

confidence: 99%

“…Short-chain a -neurotoxins as well as atypical longchain toxins (Lc-a and Lc-b from Laticauda colubrina), which lack this fifth disulfide bridge and non-conventional toxins WTX (Naja kaouthia) and Wntx-5 (Naja sputatrix), both of which have the fifth disulfide bridge in loop I and lack the loop II helical conformation, have weak affinity, in micromolar concentrations (K d approximately 3 -22 mM) at best, for the neuronal a 7 nAChR (50,54,56). Interestingly, candoxin (Bungarus candidus) is the first known toxin that lacks this critical helix-like conformation cyclized by the fifth disulfide bridge in loop II and yet blocks neuronal a 7 nAChRs in low nanomolar concentrations (58).…”

Section: Conformational Determinants Of Structure-function Of A-nmentioning

confidence: 99%

“…1). Some studies have suggested that non-conventional toxins are typically characterized by a lower order of toxicity (LD 50 varying from approximately 5 -80 mg / kg) (25,54) as opposed to prototype a -neurotoxins (LD 50 approximately 0.04 -0.3 mg / kg) (55), and because of this, they are also referred to as weak toxins (54). However, while some non-conventional toxins from cobra venoms (e.g., WTX (Naja kaouthia) (54) and Wntx-5 (Naja sputatrix) (56)) produced a weak inhibition of muscle (a1) 2 b1gd nAChRs in micromolar inhibitory concentrations, and candoxin from a krait venom (Bungarus candidus) was a potent inhibitor of muscle (a1) 2 b1gd nAChRs in low nanomolar (IC 50 approximately 10 nM) inhibitory concentrations (57).…”

Section: Non-conventional Neurotoxinsmentioning

confidence: 99%

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Three-Finger α-Neurotoxins and the Nicotinic Acetylcholine Receptor, Forty Years On

2004

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Abstract. The discovery, about forty years ago, of a -bungarotoxin, a three-finger a -neurotoxin from Bungarus multicinctus venom, enabled the isolation of the nicotinic acetylcholine receptor (nAChR), making it one of the most thoroughly characterized receptors today. Since then, the sites of interaction between a -neurotoxins and nAChRs have largely been delineated, revealing the remarkable plasticity of the three-finger toxin fold that has optimally evolved to utilize different combinations of functional groups to generate a panoply of target specificities to discern subtle differences between nAChR subtypes. New facets in toxinology have now broadened the scope for the use of a-neurotoxins in scientific discovery. For instance, the development of short, combinatorial library-derived, synthetic peptides that bind with subnanomolar affinity to a -bungarotoxin and prevent its interaction with muscle nAChRs has led to the in vivo neutralization of experimental a -bungarotoxin envenomation, while the successful introduction of pharmatopes bearing "a -bungarotoxin-sensitive sites" into toxin-insensitive nAChRs has permitted the use of various a -neurotoxin tags to localize and characterize new receptor subtypes. More ambitious strategies can now be envisaged for engineering rationally designed novel activities on three-finger toxin scaffolds to generate lead peptides of therapeutic value that target the nicotinic pharmacopoeia. This review details the progress made towards achieving this goal.

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“…To date, only two proteins with this disulfide bridge scaffold have been structurally characterized. They are bucandin (pdb: 1F94 (X-ray) and 1IJC (NMR)), another toxin from Bungarus candidus venom [35][36] and Cd59 (pdb: 1CDQ), which is a cell surface protein 37 .…”

Section: Issn 1424-6376 Page 12mentioning

confidence: 99%

Solution structure of candoxin, a novel three-finger toxin from the venom of Bungarus candidus

Parvathy¹,

Chary²,

Kini³

et al. 2006

Arkivoc

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Candoxin, a novel toxin purified from the venom of the Malayan krait (Bungarus candidus), is a 66-residue polypeptide containing five disulfide bridges, and is a reversible antagonist of postjunctional nicotinic acetylcholine receptors of the neuromuscular junction. A family of structures were calculated using a combination of distance geometry and simulated annealing with nOe, hydrogen bond and dihedral angle constraints. After refinement 19 structures, which satisfy the experimental constraints, were obtained. A comparison of each of the final structures with the average structure, gives an RMSD of 1.20 Å for backbone atoms. Candoxin has an overall conformation similar to other three-finger toxins with a two-stranded and a three-stranded β-sheets. In spite of the low sequence homology, the tertiary fold of candoxin closely resembles those of erabutoxin b and cobrotoxin, with the exception of the disulfide bridge in the Loop I. Though candoxin lags the most conserved Tyr at the origin of the central loop it posses the most popular 3-dimensional array of residues (W31, R35 and K49), which is reported to be critical for curaremimetic neurotoxicity. The presence of the kink at the tip of the first loop (Loop I) caused by the C6-C11 disulphide bridge, shortens the Loop and hence may isolate this portion of the molecule and prevent its interference with the rest of the molecule, and facilitate specific interaction with receptor/acceptor protein. These observations suggest that candoxin may bind to acetylcholine receptor with lower affinity compared to other neurotoxins and hence could account for its relatively lower toxicity.

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“Weak Toxin” from Naja kaouthia Is a Nontoxic Antagonist of α7 and Muscle-type Nicotinic Acetylcholine Receptors

Cited by 111 publications

References 39 publications

Water-soluble LYNX1 Residues Important for Interaction with Muscle-type and/or Neuronal Nicotinic Receptors

Water-soluble LYNX1 Residues Important for Interaction with Muscle-type and/or Neuronal Nicotinic Receptors

Three-Finger α-Neurotoxins and the Nicotinic Acetylcholine Receptor, Forty Years On

Solution structure of candoxin, a novel three-finger toxin from the venom of Bungarus candidus

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