Dalia Gordon

Functional Anatomy of Scorpion Toxins Affecting Sodium Channels

AbstractLong chain scorpion toxins (made of 60 to 70 amino acids) acting on voltage-gated sodium channels in excitable cells are responsible for human envenomation, and comprise a-toxins that inhibit sodium current inactivation and p-toxins, that modify the activation process. These toxins may be further divided according to their pharmacological activities. Thus, a-toxins highly active on mammals or insects, as well as α like toxins may be distinguished within the α-toxin class. The β-toxin class includes toxins active on mammals and, as a separate group, the excitatory and depressant toxins active exclusively on insects. All these toxins possess 4 disulfide bridges and share 15 similar non cystine residues. Accordingly, their 3D structure is highly conserved, comprising an α-helix and a triple stranded β-sheet. The most solvent exposed turns of this structure are prone to insertions or deletions, and accordingly correspond to the most structurally variable regions of the toxins. They have been tested by...

An excitatory and a depressant insect toxin from scorpion venom both affect sodium conductance and possess a common binding site

Two insect selective toxins were purified by gel-permeation and ion-exchange chromatographies from the venom of the scorpion, Leiurus quinquestriatus quinquestriatus, and their chemical and pharmacological properties were studied. The first toxin (LqqIT1) induces a fast excitatory contraction paralysis of fly larvae and is about 40 times more toxic than the crude venom. It is a polypeptide composed of 71 amino acids, including 8 half-cystines and devoid of methionine and tryptophan, with an estimated molecular weight of 8189 and a pI value of 8.5. The second toxin (LqqIT2) induces a slow depressant, flaccid paralysis of fly larvae. It is composed of 72 amino acids, including 8 half-cystines, is devoid of proline methionine and histidine, and has an estimated molecular weight of 7990 and a pI value of 8.3. The contrasting symptomatology of these toxins is interpreted in terms of their effects on an isolated axonal preparation of the cockroach in current and voltage clamp conditions. LqqIT1 (0.5-4 microM) induced repetitive firing of the axon which was attributable to two changes in the sodium conductance, a small increase in the peak conductance and a slowing of its turning off. LqqIT2 (1-8 microM) caused a blockage of the evoked action potentials, attributable to both a strong depolarization of the axonal membrane and a progressive suppression of the sodium current. Neither toxin affected potassium conductance. The two toxins differ mainly in their opposite effects on the activatable sodium permeability. In binding assays to a preparation of insect synaptosomal membrane vesicles, the two toxins were shown to competitively displace the radioiodinated excitatory insect toxin derived from the venom of the scorpion, Androctonus australis [( 125I]AaIT), which strongly resembles, in its chemistry and action, the LqqIT1 toxin. The present two toxins have demonstrated a strong affinity closely resembling the AaIT, with KD values of 0.4, 1.9, and 1.0 nM for LqqIT1, LqqIT2, and AaIT, respectively. These data suggest the possibility that the excitatory and depressant insect toxins share a common binding site associated with sodium channels in insect neuronal membranes.

Mapping the receptor site for α-scorpion toxins on a Na+ channel voltage sensor

The α-scorpions toxins bind to the resting state of Na+ channels and inhibit fast inactivation by interaction with a receptor site formed by domains I and IV. Mutants T1560A, F1610A, and E1613A in domain IV had lower affinities for Leiurus quinquestriatus hebraeus toxin II (LqhII), and mutant E1613R had ∼73-fold lower affinity. Toxin dissociation was accelerated by depolarization and increased by these mutations, whereas association rates at negative membrane potentials were not changed. These results indicate that Thr1560 in the S1-S2 loop, Phe1610 in the S3 segment, and Glu1613 in the S3-S4 loop in domain IV participate in toxin binding. T393A in the SS2-S6 loop in domain I also had lower affinity for LqhII, indicating that this extracellular loop may form a secondary component of the receptor site. Analysis with the Rosetta-Membrane algorithm resulted in a model of LqhII binding to the voltage sensor in a resting state, in which amino acid residues in an extracellular cleft formed by the S1-S2 and S3-S4 loops in domain IV interact with two faces of the wedge-shaped LqhII molecule. The conserved gating charges in the S4 segment are in an inward position and form ion pairs with negatively charged amino acid residues in the S2 and S3 segments of the voltage sensor. This model defines the structure of the resting state of a voltage sensor of Na+ channels and reveals its mode of interaction with a gating modifier toxin.

The Putative Bioactive Surface of Insect-selective Scorpion Excitatory Neurotoxins

Scorpion neurotoxins of the excitatory group show total specificity for insects and serve as invaluable probes for insect sodium channels. However, despite their significance and potential for application in insect-pest control, the structural basis for their bioactivity is still unknown. We isolated, characterized, and expressed an atypically long excitatory toxin, Bj-xtrIT, whose bioactive features resembled those of classical excitatory toxins, despite only 49% sequence identity. With the objective of clarifying the toxic site of this unique pharmacological group, Bj-xtrIT was employed in a genetic approach using point mutagenesis and biological and structural assays of the mutant products. A primary target for modification was the structurally unique C-terminal region. Sequential deletions of C-terminal residues suggested an inevitable significance of Ile73 and Ile74 for toxicity. Based on the bioactive role of the C-terminal region and a comparison of Bj-xtrIT with a Bj-xtrIT-based model of a classical excitatory toxin, AaHIT, a conserved surface comprising the C terminus is suggested to form the site of recognition with the sodium channel receptor.

Sea anemone toxins affecting voltage-gated sodium channels - molecular and evolutionary features

The venom of sea anemones is rich in low molecular weight proteinaceous neurotoxins that vary greatly in structure, site of action, and phyletic (insect, crustacean or vertebrate) preference. This toxic versatility likely contributes to the ability of these sessile animals to inhabit marine environments co-habited by a variety of mobile predators. Among these toxins, those that show prominent activity at voltage-gated sodium channels and are critical in predation and defense, have been extensively studied for more than three decades. These studies initially focused on the discovery of new toxins, determination of their covalent and folded structures, understanding of their mechanisms of action on different sodium channels, and identification of the primary sites of interaction of the toxins with their channel receptors. The channel binding site for Type I and the structurally unrelated Type III sea anemone toxins was identified as neurotoxin receptor site 3, a site previously shown to be targeted by scorpion alpha-toxins. The bioactive surfaces of toxin representatives from these two sea anemone types have been characterized by mutagenesis. These analyses pointed to heterogeneity of receptor site 3 at various sodium channels. A turning point in evolutionary studies of sea anemone toxins was the recent release of the genome sequence of Nematostella vectensis, which enabled analysis of the genomic organization of the corresponding genes. This analysis demonstrated that Type I toxins in Nematostella and other species are encoded by gene families and suggested that these genes developed by concerted evolution. The current review provides a brief historical description of the discovery and characterization of sea anemone toxins that affect voltage-gated sodium channels and delineates recent advances in the study of their structure-activity relationship and evolution.

Diversification of neurotoxins by C-tail ‘wiggling’: a scorpion recipe for survival

The structure of bioactive surfaces of proteins is a subject of intensive research, yet the mechanisms by which such surfaces have evolved are largely unknown. Polypeptide toxins produced by ven¬omous animals such as sea anemones, cone snails, scorpions, and snakes show multiple routes for active site diversification, each maintaining a typical con¬served scaffold. Comparative analysis of an array of genetically related scorpion polypeptide toxins that modulate sodium channels in neuronal membranes suggests a unique route of toxic site diversification. This premise is based on recent identification of bioactive surfaces of toxin representative of three distinct pharmacological groups and a comparison of their 3‐dimensional structures. Despite their similar scaffold, the bioactive surfaces of the various toxins vary consid¬erably, but always coincide with the molecular exterior onto which the C‐tail is anchored. Superposition of the toxin structures indicates that the C‐tails diverge from a common structural start point, which suggests that the pharmacological versatility displayed by these toxins might have been achieved along evolution via structural reconfiguration of the C‐tail, leading to reshaping of new bioactive surfaces.—Gurevitz, M., Gordon, D., Ben‐Natan, S., Turkov, M., Froy, O. Diversification of neurotoxins by C‐tail ‘wiggling’: a scorpion recipe for survival. FASEB J. 15, 1201–1205 (2001)

Binding of an α scorpion toxin to insect sodium channels is not dependent on membrane potential

The insect‐specific LqhαIT toxin resembles α scorpion toxins affecting mammals by its amino acid sequence and effects on sodium conductance. The present study reveals that LqhαIT does not bind to rat brain membranes and possesses in locust neuronal membranes a single class of high affinity (K d = 1.06 ± 0.15 nM) and low capacity (B max = 0.7 ± 0.19 protein) binding sites. The latter are: (1) distinct from binding sites of other sodium channel neurotoxins; (2) inhibited by sea anemone toxin II; (3) cooperatively interacting with veratridine; (4) not dependent on membrane potential, in contrast to the binding sites of α toxins in vertebrate systems. These data suggest the occurrence of (a) conformational‐structural differences between insect and mammal sodium channels and (b) the animal group specificity and pharmacological importance of the α scorpion toxins.

Positions under positive selection - key for selectivity and potency of scorpion α-toxins

Alpha-neurotoxins target voltage-gated sodium channels (Na(v)s) and constitute an important component in the venom of Buthidae scorpions. These toxins are short polypeptides highly conserved in sequence and three-dimensional structure, and yet they differ greatly in activity and preference for insect and various mammalian Na(v)s. Despite extensive studies of the structure-function relationship of these toxins, only little is known about their evolution and phylogeny. Using a broad data set based on published sequences and rigorous cloning, we reconstructed a reliable phylogenetic tree of scorpion alpha-toxins and estimated the evolutionary forces involved in the diversification of their genes using maximum likelihood-based methods. Although the toxins are largely conserved, four positions were found to evolve under positive selection, of which two (10 and 18; numbered according to LqhalphaIT and Lqh2 from the Israeli yellow scorpion Leiurus quinquestriatus hebraeus) have been previously shown to affect toxin activity. The putative role of the other two positions (39 and 41) was analyzed by mutagenesis of Lqh2 and LqhalphaIT. Whereas substitution P41K in Lqh2 did not alter its activity, substitution K41P in LqhalphaIT significantly decreased the activity at insect and mammalian Na(v)s. Surprisingly, not only that substitution A39L in both toxins increased their activity by 10-fold but also LqhalphaIT(A39L) was active at the mammalian brain channel rNa(v)1.2a, which otherwise is hardly affected by LqhalphaIT, and Lqh2(A39L) was active at the insect channel, DmNa(v)1, which is almost insensitive to Lqh2. Thus, position 39 is involved not only in activity but also in toxin selectivity. Overall, this study describes evolutionary forces involved in the diversification of scorpion alpha-toxins, highlights the key role of positions under positive selection for selectivity and potency, and raises new questions as to the toxin-channel face of interaction.

Structure-Function Map of the Receptor Site for β-Scorpion Toxins in Domain II of Voltage-gated Sodium Channels

Voltage-gated sodium (Nav) channels are the molecular targets of β-scorpion toxins, which shift the voltage dependence of activation to more negative membrane potentials by a voltage sensor-trapping mechanism. Molecular determinants of β-scorpion toxin (CssIV) binding and action on rat brain sodium channels are located in the S1-S2 (IIS1-S2) and S3-S4 (IIS3-S4) extracellular linkers of the voltage-sensing module in domain II. In IIS1-S2, mutations of two amino acid residues (Glu779 and Pro782) significantly altered the toxin effect by reducing binding affinity. In IIS3-S4, six positions surrounding the key binding determinant, Gly845, define a hot spot of high-impact residues. Two of these substitutions (A841N and L846A) reduced voltage sensor trapping. The other three substitutions (N842R, V843A, and E844N) increased voltage sensor trapping. These bidirectional effects suggest that the IIS3-S4 loop plays a primary role in determining both toxin affinity and efficacy. A high resolution molecular model constructed with the Rosetta-Membrane modeling system reveals interactions of amino acid residues in sodium channels that are crucial for toxin action with residues in CssIV that are required for its effects. In this model, the wedge-shaped CssIV inserts between the IIS1-S2 and IIS3-S4 loops of the voltage sensor, placing key amino acid residues in position to interact with binding partners in these extracellular loops. These results provide new molecular insights into the voltage sensor-trapping model of toxin action and further define the molecular requirements for the development of antagonists that can prevent or reverse toxicity of scorpion toxins.

δ-Atracotoxins from Australian funnel-web spiders compete with scorpion α-toxin binding on both rat brain and insect sodium channels

δ‐Atracotoxins are novel peptide toxins from the venom of Australian funnel‐web spiders that slow sodium current inactivation in a similar manner to scorpion α‐toxins. To analyse their interaction with known sodium channel neurotoxin receptor sites we determined their effect on scorpion toxin, batrachotoxin and saxitoxin binding. Nanomolar concentrations of δ‐atracotoxin‐Hv1 and δ‐atracotoxin‐Ar1 completely inhibited the binding of the scorpion α‐toxin AaH II to rat brain synaptosomes as well as the binding of LqhαIT, a scorpion α‐toxin highly active on insects, to cockroach neuronal membranes. Moreover, δ‐atracotoxin‐Hv1 cooperatively enhanced batrachotoxin binding to rat brain synaptosomes in an analogous fashion to scorpion α‐toxins. Thus the δ‐atracotoxins represent a new class of toxins which bind to both mammalian and insect sodium channels at sites similar to, or partially overlapping with, the receptor binding sites of scorpion α‐toxins.