Abstract
β-Diguetoxin-Dc1a (Dc1a) is a toxin from the desert bush spider Diguetia canities that incapacitates insects at concentrations that are non-toxic to mammals. Dc1a promotes opening of German cockroach voltage-gated sodium (Nav) channels (BgNav1), whereas human Nav channels are insensitive. Here, by transplanting commonly targeted S3b–S4 paddle motifs within BgNav1 voltage sensors into Kv2.1, we find that Dc1a interacts with the domain II voltage sensor. In contrast, Dc1a has little effect on sodium currents mediated by PaNav1 channels from the American cockroach even though their domain II paddle motifs are identical. When exploring regions responsible for PaNav1 resistance to Dc1a, we identified two residues within the BgNav1 domain II S1–S2 loop that when mutated to their PaNav1 counterparts drastically reduce toxin susceptibility. Overall, our results reveal a distinct region within insect Nav channels that helps determine Dc1a sensitivity, a concept that will be valuable for the design of insect-selective insecticides.
Similar content being viewed by others
Introduction
Insect voltage-gated sodium (Nav) channels share a common architecture with their mammalian orthologues1. The pore-forming subunit consists of four connected domains (DI–IV), each with six transmembrane segments (S1–S6). These homologous, but not identical, domains each contain a voltage sensor (S1–S4) and a portion of the pore through which Na+ can diffuse (S5–S6)2. While they have yet to be identified in insect Nav channels, each voltage-sensing domain within mammalian and bacterial Nav channels contains an S3b–S4 helix-turn-helix motif, the voltage-sensor paddle, which drives voltage-sensor activation3,4,5,6. Aside from its vital role in channel gating, the paddle motif is also an important pharmacological target, as peptide toxins interact with this region to modify channel opening3,4,7. Insect Nav channels likely possess similar motifs since residue substitutions in homologous regions can abolish channel susceptibility to toxins found in animal venoms1. Even though voltage-sensing domains are extensively targeted by naturally occurring peptides, commercially available insecticides such as pyrethroids and oxadiazines typically interact with the channel pore region or intracellular linker between S4 and S5 to disrupt opening or closing (that is, gating)8,9. However, insects have responded to this threat by mutating residues at strategic locations within the channel that result in a reduced sensitivity to these compounds9. Moreover, the conserved nature of the Nav channel pore throughout the animal kingdom often leads to undesired biological activity of insecticides in beneficial insect orders or mammals8,9,10. Since the amino acid composition of voltage-sensing domains varies considerably between related Nav channel isoforms, these regions may replace the pore as a target for designing insecticides with a higher degree of phyletic selectivity, an intriguing notion that has yet to be fully explored.
Nav channels have been governing electrical excitability in a wide range of organisms for millions of years, even before the development of neurons2,11. Thus, it is not surprising that ancient organisms such as spiders developed an arsenal of toxins geared towards incapacitating prey by modulating Nav channel function12,13,14,15. One intriguing specimen is the desert bush spider (Diguetia canities) whose habitat spans the Southwestern deserts of the United States16,17. The venom of this relatively unexplored primitive weaving spider contains a 57-residue peptide known as DTX9.2 (or β-diguetoxin-Dc1a18, hereafter Dc1a; Fig. 1a), one of the most potent insect-selective neurotoxins found in arthropod venoms19. Although its precise molecular target has yet to be elucidated, neurophysiological studies on housefly larvae revealed excitation of sensory and neuromuscular preparations on Dc1a application that could be blocked by the Nav channel-blocking compound tetrodotoxin20.
Here, we show that Dc1a potently promotes opening of the German cockroach Nav channel BgNav1 (ref. 21) by interacting with the paddle motif in domain II. Surprisingly, Dc1a has little effect on PaNav1-expressing neurons isolated from the American cockroach (Periplaneta americana)22, even though the toxin-binding site is identical in these two cockroach channels. By exploring regions responsible for the remarkable insect-family specificity of Dc1a, we uncovered an important role for the domain II S1–S2 loop in determining PaNav1 resistance to Dc1a. Together with the unique solution structure of Dc1a, our results provide a proof of concept that toxins—and by extension small molecules—can selectively target insect Nav channels by interacting with their voltage-sensing domains, thus facilitating the development of new insecticides.
Results
Production of recombinant Dc1a
We first produced recombinant Dc1a peptide (rDc1a) using a novel approach that addresses the challenge of correctly folding disulphide-rich spider toxins in E. coli23. To this end, we created an isopropyl-β-D-thiogalactopyranoside (IPTG)-inducible construct (Fig. 1b) that allows for export of a His6-MBP-Dc1a fusion protein to the E. coli periplasm, where the enzymes involved in disulphide-bond formation are located23. On recovery from the soluble cell fraction, the fusion protein was purified using nickel affinity chromatography (Fig. 1c). Subsequent cleavage and chromatographic purification yielded a single major disulphide-bond isomer with a purity of >98% as assessed by SDS-polyacrylamide gel electrophoresis and matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry (Fig. 1d). Note that, with four disulphide bonds, there are 105 possible disulphide-bond isomers of rDc1a. Overall, the final yield was ~1.1 mg of toxin per litre of culture. Since native Dc1a was unavailable to us, we confirmed the insecticidal activity of rDc1a by injection into the blowfly Lucilia cuprina and the housefly Musca domestica, which yielded LD50 values of 231±32 pmol g−1 and 493±52 pmol g−1, respectively (n=3) (Supplementary Fig. 1). We therefore conclude that rDc1a has a similar lethality to agricultural pests when compared with native toxin19.
Solution structure of rDc1a
The development of an efficient bacterial expression system allowed us to produce uniformly 13C/15N-labelled rDc1a protein for structure determination using heteronuclear NMR. 1HN, 15N, 13Cα, 13Cβ, and 13C′ resonance assignments for the toxin were obtained from analysis of amide-proton strips in three-dimensional (3D) HNCACB, CBCA(CO)NH, and HNCO spectra. Sidechain 1H and 13C chemical shifts were obtained using a four-dimensional (4D) HCC(CO)NH-TOCSY experiment, which has the advantage of providing sidechain 1H–13C connectivities24. Complete chemical shift assignments have been deposited in BioMagResBank (Accession Number 19666). CYANA was used for automated NOESY assignment and structure calculation25. The disulphide-bond pattern (1–4, 2–5, 3–8, 6–7) was unambiguously determined from preliminary structures calculated without disulphide-bond restraints26 and is identical to the framework predicted in the UniProtKB entry for Dc1a (P49126). Of the 200 structures that were calculated from random starting conformations, 20 conformers with high stereochemical quality (as judged by MolProbity27) were selected to represent the solution structure of rDc1a (Fig. 2a). Atomic coordinates for the final ensemble of 20 structures are available from the Protein Data Bank (PDB; Accession Number 2MI5).
Statistics highlighting the high precision and stereochemical quality of the ensemble of rDc1a structures are shown in Supplementary Table 1. The average MolProbity score of 1.24 places the ensemble in the 99th percentile relative to all other structures ranked by MolProbity. The high stereochemical quality of the ensemble stems from a complete absence of bad close contacts and an excellent Ramachandran plot quality (>99% of residues in the most favoured region). The structural ensemble is also highly precise with backbone and heavy-atom root-mean-square deviation (r.m.s.d.) values over all the structural ordered regions (residues 3–42, 52–56) of 0.27±0.07 Å and 0.70±0.11 Å, respectively. The ensemble of rDc1a structures ranks as ‘very high resolution’ based on these measures of precision and stereochemical quality28.
Three of the four disulphide bonds in rDc1a form a classical inhibitor cysteine knot (ICK) motif in which the Cys13–Cys26 and Cys20–Cys40 disulphide bonds and the intervening sections of the polypeptide backbone form a 23-residue ring that is pierced by the Cys25–Cys54 disulphide bond (Fig. 2b). This ICK motif is commonly found in spider toxins, and this particular scaffold provides these peptides (so-called `knottins') with an unusually high degree of chemical, thermal and biological stability15. However, the structure of rDc1a differs markedly from other ICK toxins, and a DALI search29 of the PDB returned no structural homologues. First, rDc1a contains an additional disulphide bond (Cys42–Cys52) that appears to serve as a molecular staple which limits the flexibility of a disordered serine-rich hairpin loop (residues 43–51) (Fig. 2b). Stapled hairpins of this kind have been observed in only a small number of spider toxins30. Second, the extended N terminus of rDc1a along with an unusually large loop between Cys26 and Cys40 enables the formation of an amino-terminal (N-terminal) three-stranded antiparallel β-sheet that is not found in any other knottin (Fig. 2b,c). The uniqueness of the rDc1a structure can readily be seen by comparison with the structure of As1a, a typical spider venom–derived knottin that modulates the activity of insect NaV channels30. The two toxins can be aligned over their core ICK regions with an rmsd of 1.9 Å (Fig. 2c) consistent with them both being members of the knottin family. However, when aligned over this ICK region, the N-terminal β-sheet of rDc1a is entirely separate to the region of structural overlap (Fig. 2c). Despite its structural uniqueness, the molecular surface of rDc1a contains a relatively uniform distribution of charged residues (Fig. 2d); moreover, there are no distinct clusters of hydrophobic residues that might mediate an interaction with lipid bilayers7,31 (Supplementary Movie 1).
rDc1a opens the German cockroach Nav channel BgNav1
Diguetia spiders are generalist predators and their diet consists of various insects ranging from small ants to sizeable prey such as grasshoppers and cockroaches16,32. As such, we decided to test whether rDc1a influences the gating properties of BgNav1, a well-studied Nav channel isoform cloned from the German cockroach8,21. We functionally expressed BgNav1 in Xenopus oocytes and applied various concentrations of rDc1a. At 1 μM, rDc1a produced robust opening of BgNav1 at voltages where the channel is normally closed. This was achieved by a drastic shift in channel activation to more negative potentials (V1/2 was shifted from −27.3±0.2 mV (mean±s.e.m.) (slope 4.0±0.2) to −49.4±0.4 mV (slope 3.5±0.3) in the presence of 1 μM rDc1a; Fig. 3a) whereas steady-state inactivation (or channel availability) was only slightly affected (V1/2 was shifted from −52.2±0.1 mV to −55.1±0.1 mV in the presence of 1 μM rDc1a; Fig. 3a). The rate of recovery from fast inactivation was also not significantly altered (τ is 2.1±0.1 ms versus 2.2±0.1 ms; Fig. 3b). On addition of 1 μM rDc1a to channels depolarized to −60 mV every 5 s, sodium currents became rapidly visible as a result of the −22 mV shift in voltage-dependent opening of BgNav1 (Fig. 3c). Moreover, rDc1a similarly affects the channel when voltage-steps to −60 mV were applied every 50 s, suggesting that the toxin can access its binding site when BgNav1 is in the resting state12. Channels completely recovered following washout in toxin-free solution (Fig. 3c). The persistent nature of the emerging current does not stem from the inhibition of fast inactivation by rDc1a since wild-type (WT) BgNav1 inherently possesses these characteristics at mildly depolarizing voltages33. Fitting the Hill equation to the concentration dependence for toxin-induced current potentiation, as determined by shifts in V1/2, yielded an EC50 of 65±1 nM and a Hill coefficient of 1.19±0.02 (Fig. 3d), suggesting that the toxin may interact with only one binding site.
Interestingly, 1 μM rDc1a did not affect any of the tested vertebrate Nav channel isoforms or the hERG channel34, a member of the cardiac voltage-gated potassium (Kv) channel family and an Food and Drug Administration-mandated screening target for potential off-target drug effects (Supplementary Fig. 2a). These results are consistent with the report that Dc1a has no effect in mice when injected intraperitoneally or intracerebroventricularly at doses of 4.1 and 1.0 mg kg−1, respectively19.
rDc1a interacts with the domain II paddle motif in BgNav1
Subsequently, we were interested in identifying the receptor sites for rDc1a within insect Nav channels that result in such a profound shift in the voltage dependence of activation. Our experiments with BgNav1 suggest that rDc1a functions as an excitatory toxin to activate insect Nav channels at membrane voltages where they are normally closed. Hence, the toxin may interact with S3b–S4 paddle motifs within BgNav1 voltage sensors in a manner analogous to previously described β-scorpion toxins3,35,36. In order to test this hypothesis, we first needed to establish whether BgNav1 contains paddle motifs with similar functions as in Kv channels37,38,39 and in mammalian Nav channel isoforms where they have been identified (rNav1.2a, rNav1.4, rNav1.8, rNav1.9, and hNav1.9)3,4. To this end, we employed a previously reported approach in which specific S3b–S4 regions from each voltage-sensing domain of a Nav channel were transplanted into homotetrameric Kv channels (Fig. 4a)3,4,7. After several attempts (Fig. 4a), we were able to generate functional chimeras between BgNav1 and Kv2.1 using known paddle motif boundaries3,4 (Fig. 4a,b). All of the constructs contain the crucial basic residues that contribute to gating charge movement in Kv channels40,41, suggesting that each of the four voltage-sensing domains in BgNav1 contain paddle motifs that are capable of sensing membrane voltage changes.
Examination of the conductance–voltage (G–V) relationships for the BgNav1/Kv2.1 chimeras reveals that each of the four voltage-sensor paddles has a distinct effect on the gating properties of Kv2.1. This was evidenced by marked differences in the midpoints of activation for the G–V relations for the domain I, II and IV constructs which are ⩾50 mV, 13±2 mV, and −9±2 mV, respectively (Fig. 4c). The G–V relationship for the domain III BgNav1/Kv2.1 construct is bimodal, suggesting that the functional coupling between the voltage-sensing domains and the pore has been considerably altered. Although the underlying mechanism is unclear, it is possible that pore opening in this particular chimera may occur when: (1) not all four voltage sensors are fully activated42; or (2) each voltage sensor has transferred only a portion of its charge across the hydrophobic septum43,44,45. The latter scenario seems more likely since in the related Shaker Kv channel, all four voltage sensor need to be in the active position before the pore opens42,46. Moreover, intermediate states have also been observed when measuring gating currents of the Shaker Kv channel in which a mutation immobilized voltage-sensor movement between the resting and activated states, thereby shifting the voltage activation of the ionic currents47. Finally, it is worth mentioning that the domain III BgNav1/Kv2.1 construct may display multiple open states according to a model that has been described for N-type Cav channels48.
Remarkably, domain IV paddle motifs from rNav1.2a and rNav1.4 slow activation kinetics when transplanted into Kv channels. These observations support the notion that the domain IV paddle motif contributes substantially to the overall rate of voltage-sensor activation3,4. To explore whether the domain IV paddle motif serves a similar role in BgNav1, we measured the kinetics of activation and deactivation of the four BgNav1 paddle constructs in response to membrane depolarization and repolarization, respectively. Similar to previously studied chimeric channels, the activation and deactivation kinetics observed for the domain IV construct of BgNav1/Kv2.1 are slower over a wide voltage range when compared with the other domains (Fig. 4d), suggesting that this particular domain may indeed contribute to fast inactivation in insect Nav channels49,50,51. We obtained additional evidence for the functional role of the domain IV paddle motif in BgNav1 gating from experiments with BomIV, a classic insect-selective α-scorpion toxin from the venom of Buthus occitanus mardochei that inhibits fast inactivation in American cockroach neurons52. To determine whether BomIV influences BgNav1 in a similar fashion, we applied 10 nM to channel-expressing Xenopus oocytes and observed that the toxin indeed slows down fast inactivation (Supplementary Fig. 2b). Subsequent testing on the BgNav1/Kv2.1 chimeras revealed that BomIV does not affect WT Kv2.1 or the domain I, II, and III constructs. However, a dramatic toxin-induced inhibition of the domain IV chimera corroborates the importance of this particular voltage-sensing domain in toxin binding and BgNav1 fast inactivation (Supplementary Fig. 2b).
We next investigated whether rDc1a modulates the activity of any of the four BgNav1/Kv2.1 paddle chimeras and found that 1 μM rDc1a exclusively interacts with the domain II construct whereas domains I, III, IV, and WT Kv2.1 are unaffected (Fig. 4e, Supplementary Fig. 2c). This result suggests that rDc1a specifically targets the domain II voltage sensor within BgNav1 to influence channel opening.
rDc1a distinguishes between cockroach Nav1 channels
Since the domain II paddle motif in BgNav1 (ref. 21) is identical to that in PaNav1 (ref. 22), we expected a similar effect of rDc1a in whole-cell patch-clamp recordings from American cockroach dorsal unpaired median (DUM) neurons. Surprisingly, 1μM rDc1a had little effect on sodium current amplitude or kinetics in DUM neurons as reflected in the threshold, or V1/2, of Nav channel activation or the V1/2 of steady-state inactivation measurements (Supplementary Fig. 3). Furthermore, there were no significant use-dependent effects on sodium current amplitude or kinetics.
Due to the unexpectedly weak effects of 1μM rDc1a on voltage-dependent activation of P. americana DUM neurons compared with BgNav1 channels from B. germanica, acute toxicity assays were expanded to include both cockroach species (Fig. 5a,b). Remarkably, these bioassays revealed lethal toxicity of rDc1a in B. germanica compared with only mild, reversible effects in P. americana. At doses up to 5 nmol g−1, rDc1a generated only minor spastic contractions of the abdomen, some shaking and evidence of reduced motor activity in P. americana. Even though these effects were completely reversible, a very small percentage of cockroaches did develop paralysis after 24 h (7±7% knockdown, n=3). One explanation for these observations may be toxin binding to a subset of Nav channel splice variants53 or the presence of endogenous pharmacologically active auxiliary subunits54. Conversely, B. germanica underwent dose-dependent flaccid or contractile paralysis, and lethality was observed after 8 h at all doses tested (Fig. 5a). The KD50 and LD50 values at 24 h post injection were 3.0±1.2 nmol g−1 and 4.2±3.4 nmol g−1 (n=3), respectively. These observations suggest that residues in regions outside of the domain II paddle motif may underlie the remarkably different sensitivity of BgNav1 and PaNav1 to rDc1a.
The S1–S2 loop modulates Nav channel sensitivity to rDc1a
Sequence alignment of BgNav1 with PaNav1 reveals a highly conserved S1–S4 voltage sensor in domain II with only three amino acid substitutions (Fig. 6a; Supplementary Fig. 4). Of those, two residues in the S1–S2 loop are potentially accessible for a peptide toxin applied from the extracellular environment (His805 and Asp812 in BgNav1 which correspond to a Tyr and Glu in PaNav1, respectively). On mutating these residues in BgNav1 to their PaNav1 counterparts, the resulting BgNav1YE construct functionally expressed in Xenopus oocytes with a voltage-dependent activation V1/2 of −41.5±0.3 mV and a steady-state inactivation V1/2 of −56.4±0.2 mV (Fig. 6b). Unfortunately, a functional PaNav1 clone was unavailable to undertake gain-of-function experiments. Strikingly, 100 nM rDc1a was no longer sufficient to open BgNav1YE whereas this concentration generated large inward sodium currents when applied to WT channels (Fig. 6c, inset). When surveying higher concentrations of rDc1a, it becomes clear that concentrations of more than 1 μM are required to achieve a potentiation with BgNav1YE that is comparable to the WT channel (EC50 ~65 nM; Fig. 6c). Although we cannot exclude the possibility that rDc1a interacts with other PaNav1 domains at such concentrations, administering high doses of the toxin is indeed mildly toxic to P. americana (Fig. 5a,b). Thus, our mutagenesis experiments have uncovered a novel region within insect Nav channels that helps determine their sensitivity to spider toxins. This locus contributes to the drastically reduced sensitivity of the American cockroach to rDc1a from the venom of the desert bush spider whereas its German counterpart is highly susceptible.
Discussion
The initial goal of this study was to explore the mechanism underlying the efficacy of Dc1a, a potent insecticidal peptide toxin produced by desert bush spiders. To this end, we first produced recombinant rDc1a and determined its solution structure using heteronuclear NMR (Figs 1 and 2). Next, we tested rDc1a on the heterologously expressed German cockroach channel BgNav1 and discovered that the toxin dramatically promotes channel opening (Fig. 3). By taking advantage of the portable nature of S3b–S4 paddle motifs within voltage-sensing domains3,4,7,38, we demonstrated that such motifs also exist in each of the four voltage-sensing domains of BgNav1, and that rDc1a selectively interacts with the paddle motif in domain II, a feature that it shares with an extensive list of animal toxins that target this particular paddle motif3,4,12,55,56, albeit with a high degree of insect selectivity (Fig. 4). Remarkably, our insect assays revealed that German cockroaches are highly susceptible to rDc1a whereas the closely related American cockroach is virtually insensitive despite the fact that the domain II paddle motif in BgNav1 is identical to that in PaNav1 (Fig. 5; Supplementary Fig. 4). To elucidate the machinery responsible for this discrepancy, we mutated two residues in the S1–S2 loop that differ between BgNav1 and PaNav1 (His805 and Asp812) and found that the susceptibility of the resulting BgNav1YE construct to rDc1a is dramatically reduced (Fig. 6). Interestingly, mammalian Nav channel isoforms possess a Tyr and Ser at the corresponding positions, which presumably contributes to their insensitivity to rDc1a; however, their domain II paddle motif differs as well (Supplementary Fig. 4).
It is interesting to consider potential mechanisms that may underlie the insect-family specificity of rDc1a. For example, the β3–β4 hairpin (Fig. 2b) often houses the pharmacophore in spider ICK toxins that target voltage-gated ion channels57, but the unusual architecture of rDc1a (Fig. 2c) and its unique ability to dramatically promote opening of insect Nav channels (Fig. 3) suggests that it might interact with the voltage sensors of these channels in a unique manner. As such, the domain II S1–S2 loop may play a role in positioning the toxin into a water-filled cavity adjacent to the S3–S4 paddle motif58, thereby placing particular toxin residues in strategic positions to stabilize the domain II voltage sensor in an activated position. This hypothesis is strengthened by the observation that the substitution of two residues in the domain II S1–S2 loop within mammalian Nav1.2 channels decreases sensitivity to the functionally related β-scorpion toxin CssIV by a factor of four59. Another possible mechanism is that rDc1a binding to the domain II S1–S2 loop in BgNav1 allosterically influences channel opening. Such a hypothesis was postulated when a domain III S1 splice variant of BgNav1 revealed an increased susceptibility to the insect-selective β-scorpion toxin Lqh-dprIT3 (ref. 60). However, one caveat is that a depolarizing prepulse is needed to potentiate the maximal effect of CssIV and Lqh-dprIT3 (refs 49, 50). Similar to the structurally unrelated spider toxin Magi5 which activates rat Nav1.2 channels by binding to the domain II voltage sensor61, rDc1a does not require such a prepulse.
In summary, the current study provides a molecular explanation for the remarkable insect selectivity of Dc1a, the most potent insecticidal toxin identified in the venom of the desert bush spider. Moreover, we have uncovered a novel toxin receptor site within insect Nav channels that provides a new framework for the design of molecules capable of targeting specific insect families. This knowledge may be used in the future to develop insecticides that target specific insect pests without affecting beneficial insects or endangering human health.
Methods
Chemicals
All chemicals were purchased from Sigma-Aldrich Australia (Castle Hill, NSW, Australia), Sigma-Aldrich USA (St Louis, MO, USA), or Merck Chemicals (Kilsyth, Victoria, Australia) with the exception of IPTG and streptomycin (Life Technologies, Victoria, Australia), tetrodotoxin (Alomone Labs, Israel), and high-performance liquid chromatography (HPLC)-grade acetonitrile (RCI Labscan, Bangkok, Thailand). 13C6-glucose and 15NH4Cl were from Sigma-Aldrich Australia. Recombinant His6-TEV protease (EC 3.4.22.44) was produced in-house using a published protocol62.
Production of recombinant rDc1a
A synthetic gene encoding Dc1a, with codons optimized for expression in Escherichia coli, was produced and cloned into a variant of the pLIC-MBP expression vector by GeneArt (Invitrogen, Regensburg, Germany). This vector (pLIC-NSB3) encodes a MalE signal sequence for periplasmic export, a His6 tag for affinity purification, a maltose-binding protein (MBP) fusion tag to aid solubility, and a tobacco etch virus (TEV) protease recognition site directly preceding the codon-optimized Dc1a gene23. The plasmid encoding Dc1a was transformed into E. coli strain BL21(λDE3) for recombinant toxin production. Protein expression and purification were performed as described previously30 with minor modifications. In summary, cultures were grown in Luria-Bertani broth at 37 °C with shaking. Toxin gene expression was induced with 500 μM IPTG at an OD600 of 1.0–1.1, then cells were grown at 20 °C for a further 12 h before collecting by centrifugation for 15 min at 10,500 g. For production of uniformly 13C/15N-labelled rDc1a, cultures were grown in minimal medium supplemented with 13C6-glucose and 15NH4Cl as the sole carbon and nitrogen sources, respectively. The His6-MBP-toxin fusion protein was extracted from the bacterial periplasm by cell disruption at 27 kPa (TS Series Cell Disrupter, Constant Systems Ltd, Northants, UK), and then captured by passing the extract (buffered in 40 mM Tris, 450 mM NaCl, pH 8.0) over Ni-NTA Superflow resin (Qiagen, Chadstone, Australia). Proteins bound non-specifically were removed by washing with 10 mM imidazole then the fusion protein was eluted with 600 mM imidazole. The eluted fusion protein was concentrated to 10 ml and the buffer was exchanged to remove imidazole. Reduced and oxidized glutathione were then added to a final concentration of 0.6 mM and 0.4 mM, respectively, to maintain TEV protease activity and promote folding of the protein. Approximately, 100 μg of His6-tagged TEV protease was added per mg of rDc1a, then the cleavage reaction was allowed to proceed at room temperature for 12 h. The cleaved His6-MBP and His6-TEV were precipitated by addition of 1% trifluoroacetic acid (TFA), then the sample was centrifuged at 16,000 g. The supernatant was filtered using a 0.45-μm syringe filter (Millipore, MA, USA) and subjected to further purification using RP-HPLC. RP-HPLC was performed on a Vydac C18 column (250 × 4.6 mm, particle size 5 μm) using a flow rate of 1 ml min−1 and a gradient of 20–45% Solvent B (0.043% TFA in 90% acetonitrile) in Solvent A (0.05% TFA in water) over 30 min. rDc1a contains a non-native N-terminal serine residue (a vestige of the TEV protease cleavage site), making it one residue longer than native Dc1a.
Mass spectrometry
Toxin masses were confirmed by MALDI-TOF mass spectrometry using a Model 4700 Proteomics Bioanalyser (Applied Biosystems, CA, USA). RP-HPLC fractions were mixed (1:1 v-v) with α-cyano-4 hydroxycinnamic acid matrix (5 mg ml−1 in 50/50 acetonitrile/H2O) and MALDI-TOF spectra were acquired in positive reflector mode. All reported masses are for monoisotopic [M+H]+ ions.
Structure determination
Several buffer conditions were screened to optimize quality of NMR data recorded for rDc1a, including 20 mM phosphate buffer, pH 6.0; 20 mM MES buffer, pH 6.0 and 20 mM acetate buffer pH 5.0. Initial buffer screening revealed the acetate buffer, pH 5.0 was optimal for acquisition of NMR data. Recombinant 15N/13C-labelled rDc1a was dissolved in 20 mM acetate buffer, pH 5.0 to a final concentration of 350 μM. 5% 2H2O was added, then the sample was filtered using a low-protein-binding Ultrafree-MC centrifugal filter (0.22 μm pore size; Millipore, MA, USA) and 300 μl was added to a susceptibility matched 5 mm outer-diameter microtube (Shigemi Inc., Japan). NMR data were acquired at 25 °C using a 900 MHz NMR spectrometer (Bruker BioSpin, Germany) equipped with a cryogenically cooled probe. 3D and 4D data used for resonance assignments were acquired using non-uniform sampling. Sampling schedules that approximated the signal decay in each indirect dimension were generated using sched3D26. Non-uniform sampling data were processed using the Rowland NMR toolkit ( www.rowland.org/rnmrtk/toolkit.html) and maximum entropy parameters were automatically selected as previously described63. 13C- and 15N-edited HSQC-NOESY (mixing time of 200 ms) experiments were acquired using uniform sampling. All experiments were acquired in H2O containing 5% 2H2O. Dihedral angles (φ, ψ) were derived from TALOS+chemical shift analysis64 and the restraint range for structure calculations was set to twice the estimated s.d. The Gly9–Pro10 and Arg36–Pro37 peptide bond was determined to be in the trans conformation on the basis of characteristic NOEs and the Cα and Cβ chemical shifts of Pro residues. NOESY spectra were manually peak picked and integrated, then peak lists were automatically assigned, distance restraints extracted and an ensemble of structures calculated using the torsion angle dynamics package CYANA 3.0 (ref. 25). The tolerances used for CYANA 3.0 were 0.025 p.p.m. in the direct 1H dimension, 0.03 p.p.m. in the indirect 1H dimension and 0.3 p.p.m. for the heteronucleus (13C/15N). During the automated NOESY assignment/structure calculation process, CYANA assigned 92% of all NOESY crosspeaks (2,271 out of 2,469).
Insecticidal assays
rDc1a was dissolved in insect saline and injected into the ventro-lateral thoracic region of adult sheep blowflies (Lucilia cuprina;), adult houseflies (M. domestica), adult American cockroaches (Periplaneta americana) and adult German cockroaches (Blattella germanica)65. Injections were made using a 1.0 ml Terumo Insulin syringe (B-D Ultra-Fine, Terumo Medical Corporation, Maryland, USA) with a fixed 29 G needle fitted to an Arnold hand micro-applicator (Burkard Manufacturing Co. Ltd., England). A maximum volume of 2 μl was injected per L. cuprina, M. domestica and B. germanica and 5 μl for the larger P. americana. Thereafter, flies were individually housed in 2-ml tubes and provided with 10% sucrose while cockroaches were housed in closed Petri dishes and provided with dry food and water. The paralytic activity was then determined over a 24-h period. For each acute toxicity assay up to fourteen doses of rDc1a (n=10 insects per dose) and the appropriate control (insect saline; n=10 insects) were used. The assay was repeated three times. Median knockdown (KD50) and median lethal (LD50) doses were calculated as described previously66 and averaged to produce KD50 and LD50 values.
Electrophysiological measurements on DUM neurons
DUM neurons were isolated from unsexed adult American cockroaches (P. americana) as described previously30. Briefly, terminal abdominal ganglia were removed and placed in normal insect saline (NIS) containing (in mM): NaCl 180, KCl 3.1, N-hydroxyethylpiperazine-N-ethanesulfonic acid (HEPES) 10 and D-glucose 20. Ganglia were then incubated in 1 mg ml−1 collagenase (type IA) for 40 min at 29 °C. Following enzymatic treatment, ganglia were washed three times in NIS and triturated through a fire-polished Pasteur pipette. The resultant cell suspension was then distributed onto 12-mm diameter glass coverslips pre-coated with 2 mg ml−1 concanavalin A (type IV). DUM neurons were maintained in NIS supplemented with 5 mM CaCl2, 4 mM MgCl2, 5% foetal bovine serum and 1% penicillin and streptomycin (Life Technologies, Victoria, Australia), and maintained at 29 °C, 100% humidity. Ionic currents were recorded in voltage-clamp mode using the whole-cell patch-clamp technique employing version 10.2 of the pCLAMP data acquisition system (Molecular Devices, Sunnyvale, CA). Data were filtered at 5–10 kHz with a low-pass Bessel filter with leakage and capacitive currents subtracted using P-P/4 procedures. Digital sampling rates were set between 15 and 25 kHz depending on the length of the protocol. Single-use 0.8–2.5 MΩ electrodes were pulled from borosilicate glass and fire-polished prior to current recordings. Liquid junction potentials were calculated using JPCALC, and all data were compensated for these values. Cells were bathed in external solution through a continuous pressurized perfusion system at 1 ml min−1, while toxin solutions were introduced via direct pressurized application via a perfusion needle at ~50 μl min−1 (Automate Scientific, San Francisco, CA). Control data were not acquired until at least 20 min after whole-cell configuration was achieved to eliminate the influence of initially fast time-dependent shifts in steady-state inactivation resulting in NaV channel current (INa) rundown. All experiments were performed at ambient temperature (20–23 °C). To record INa, the external bath solution contained (in mM): NaCl 80, CsCl 5, CaCl2 1.8, tetraethylammonium chloride 50, 4-aminopyridine 5, HEPES 10, NiCl2 0.1, and CdCl2 1, adjusted to pH 7.4 with 1 M NaOH. The pipette solution contained (in mM): NaCl 34, CsF 135, MgCl2 1, HEPES 10, ethylene glycol-bis(2-aminoethylether)-N,N,N′,N′-tetraacetic acid 5, and ATP-Na2 3, adjusted to pH 7.4 with 1 M CsOH. To eliminate any influence of differences in osmotic pressure, all internal and external solutions were adjusted with sucrose to 400±5 mOsmol l−1. Experiments were rejected if there were large leak currents or currents showed signs of poor space clamping.
Off-line data analysis was performed using Axograph X version 1.3 or Clampfit 10 (Molecular Devices, USA). Voltage–activation relationships were obtained by measuring steady-state currents elicited by stepwise depolarizations of 5–10 mV from a holding potential of –90 mV and calculating peak conductance (GNa) using the following equation: G=INa/(Vm–Erev) where G is peak conductance, INa is peak inward sodium current, Vm is the test potential and Erev is the reversal potential. Reversal potentials were individually estimated for each data set67 by fitting the INa-V data with the following equation: INa=[1+exp(–0.03937 × z × (Vm–V1/2))]−1 × g × (Vm–Vrev) where z is the apparent gating charge, g is a factor related to the number of channels contributing to the macroscopic whole-cell INa, Vm is equal to the voltage potential of the pulse, and V1/2 is the voltage at half-maximal activation. The normalized conductance was fitted to a two-state Boltzmann function of the form: G/Gmax=1/(1+exp((–0.3937 × z × (Vm–V1/2))) where G, z, Vm and V1/2 have the same meaning. The voltage dependence of steady-state Nav channel inactivation (h∞/V) data were normalized to the maximum peak current in the control or maximum peak current and fitted using the following Boltzmann equation: h∞=A/(1+exp((Vm–V1/2)/k)) where A is the fraction of control maximal peak INa (value of 1.0 under control conditions), V1/2 is the midpoint of steady-state inactivation, k is the slope factor and Vm is the prepulse voltage. The rate of recovery from fast inactivation data were fitted to the following single-exponential function: I/Imax=1−exp(–τ/t) where τ is the time constant of current recovery. Dose–response curves to determine LD50 and KD50 values were fitted using the following form of the logistic equation: y=1/(1+[x]/Dose50)nH where x is the toxin dose, nH the Hill coefficient (slope parameter) and Dose50 is the median inhibitory dose causing lethality (LD50) or knockdown (KD50). Non-linear curve-fitting of data were performed using GraphPad Prism version 6.00c for Macintosh (GraphPad Software, San Diego) or Origin 8 (OriginLab, MA, USA). Comparisons of two sample means were made using a paired Student’s t-test and differences were considered to be significant if P<0.05. All data are presented as mean±s.e.m. of n independent experiments.
Electrophysiological measurements on oocytes
Chimeras and channel mutants were generated using sequential PCRs with Kv2.1Δ7 (ref. 68) and BgNav1 (ref. 21) as templates. The Kv2.1Δ7 construct contains seven point mutations in the outer vestibule, rendering the channel sensitive to agitoxin-2. The DNA sequence of all constructs and mutants was confirmed by automated DNA sequencing and cRNA was synthesized using T7 polymerase (mMessage mMachine kit, Life Technologies, USA) after linearizing the DNA with appropriate restriction enzymes. Channel constructs including hNav1.1–hNav1.7 and hERG were expressed in Xenopus oocytes by themselves or, in the case of BgNav1, together with the TipE subunit69 (1:5 molar ratio), and studied following 1–2 days incubation after cRNA injection (incubated at 17 °C in 96 mM NaCl, 2 mM KCl, 5 mM HEPES, 1 mM MgCl2 and 1.8 mM CaCl2, 50 μg ml−1 gentamycin, pH 7.6 with NaOH) using two-electrode voltage-clamp recording techniques (OC-725C, Warner Instruments, USA) with a 150-μl recording chamber. Data were filtered at 4 kHz and digitized at 20 kHz using pClamp software (Molecular Devices, USA). Microelectrode resistances were 0.5–1 MΩ when filled with 3 M KCl. For most Kv channel experiments, the external recording solution contained (in mM): 50 KCl, 50 NaCl, 5 HEPES, 1 MgCl2, 0.3 CaCl2, pH 7.6 with NaOH. For Nav channel experiments, the external recording solution contained (in mM): 96 NaCl, 2 KCl, 5 HEPES, 1 MgCl2 and 1.8 CaCl2, pH 7.6 with NaOH. All experiments were performed at room temperature (~22 °C). Leak and background conductances, identified by blocking the channel with agitoxin-2 (Alomone labs) or tetrodotoxin, were subtracted for most of the Kv or BgNav1 currents shown.
Voltage–activation relationships were obtained by measuring tail currents for Kv channels or steady-state currents and calculating conductance for Nav channels. Protocols for other measurements are described in the figure legends. After addition of the toxin to the recording chamber, the equilibration between the toxin and the channel was monitored using weak depolarizations elicited at 5-s intervals. For all channels, we recorded voltage–activation relationships in the absence and presence of toxin. Off-line data analysis was performed using Clampfit 10 (Molecular Devices, USA), Origin 8.0 (Originlab) and Microsoft Solver (Microsoft Excel).
Additional information
How to cite this article: Bende, N. S. et al. A distinct sodium channel voltage-sensor locus determines insect selectivity of the spider toxin Dc1a. Nat. Commun. 5:4350 doi: 10.1038/ncomms5350 (2014).
Accession codes: Complete chemical shift assignments for rDc1a have been deposited in BioMagResBank under accession code 19666.
References
King, G. F., Escoubas, P. & Nicholson, G. M. Peptide toxins that selectively target insect NaV and CaV channels. Channels 2, 100–116 (2008).
Hille, B. Ion Channels of Excitable Membranes 3rd edn Sinauer Associates, Inc. (2001).
Bosmans, F., Martin-Eauclaire, M. F. & Swartz, K. J. Deconstructing voltage sensor function and pharmacology in sodium channels. Nature 456, 202–208 (2008).
Bosmans, F., Puopolo, M., Martin-Eauclaire, M. F., Bean, B. P. & Swartz, K. J. Functional properties and toxin pharmacology of a dorsal root ganglion sodium channel viewed through its voltage sensors. J. Gen. Physiol. 138, 59–72 (2011).
Payandeh, J., Scheuer, T., Zheng, N. & Catterall, W. A. The crystal structure of a voltage-gated sodium channel. Nature 475, 353–358 (2011).
Zhang, X. et al. Crystal structure of an orthologue of the NaChBac voltage-gated sodium channel. Nature 486, 130–134 (2012).
Milescu, M. et al. Interactions between lipids and voltage sensor paddles detected with tarantula toxins. Nat. Struct. Mol. Biol. 16, 1080–1085 (2009).
Dong, K. Insect sodium channels and insecticide resistance. Invert. Neurosci. 7, 17–30 (2007).
Soderlund, D. M. Molecular mechanisms of pyrethroid insecticide neurotoxicity: recent advances. Arch. Toxicol. 86, 165–181 (2012).
Tan, J. & Soderlund, D. M. Divergent actions of the pyrethroid insecticides S-bioallethrin, tefluthrin, and deltamethrin on rat NaV1.6 sodium channels. Toxicol. Appl. Pharmacol. 247, 229–237 (2010).
Zakon, H. H. Adaptive evolution of voltage-gated sodium channels: the first 800 million years. Proc. Natl Acad. Sci. USA 109, 10619–10625 (2012).
Bosmans, F. & Swartz, K. J. Targeting voltage sensors in sodium channels with spider toxins. Trends Pharmacol. Sci. 31, 175–182 (2010).
Fry, B. G. et al. The toxicogenomic multiverse: convergent recruitment of proteins into animal venoms. Annu. Rev. Genomics Hum. Genet. 10, 483–511 (2009).
Klint, J. K. et al. Spider-venom peptides that target voltage-gated sodium channels: pharmacological tools and potential therapeutic leads. Toxicon 60, 478–491 (2012).
King, G. F. & Hardy, M. C. Spider-venom peptides: structure, pharmacology, and potential for control of insect pests. Annu. Rev. Entomol. 58, 475–496 (2013).
Boulton, A. M. & Polis, G. A. Phenology and life history of the desert spider, Diguetia majavea. J. Arachnol. 27, 513–521 (1999).
Gertsch, W. J. The Spider Family Diguetidae American Museum Novitates No. 1904, (1985).
King, G. F., Gentz, M. C., Escoubas, P. & Nicholson, G. M. A rational nomenclature for naming peptide toxins from spiders and other venomous animals. Toxicon 52, 264–276 (2008).
Krapcho, K. J., Kral, R. M. Jr, Vanwagenen, B. C., Eppler, K. G. & Morgan, T. K. Characterization and cloning of insecticidal peptides from the primitive weaving spider Diguetia canities. Insect Biochem. Mol. Biol. 25, 991–1000 (1995).
Bloomquist, J. R., Kinne, L. P., Deutsch, V. & Simpson, S. F. Mode of action of an insecticidal peptide toxin from the venom of a weaving spider (Diguetia canities). Toxicon 34, 1072–1075 (1996).
Dong, K. A single amino acid change in the para sodium channel protein is associated with knockdown-resistance (kdr) to pyrethroid insecticides in German cockroach. Insect Biochem. Mol. Biol. 27, 93–100 (1997).
Moignot, B., Lemaire, C., Quinchard, S., Lapied, B. & Legros, C. The discovery of a novel sodium channel in the cockroach Periplaneta americana: evidence for an early duplication of the para-like gene. Insect Biochem. Mol. Biol. 39, 814–823 (2009).
Klint, J. K. et al. Production of recombinant disulfide-rich venom peptides for structural and functional analysis via expression in the periplasm of E. coli. PLoS ONE 8, e63865 (2013).
Mobli, M. & King, G. F. NMR methods for determining disulfide-bond connectivities. Toxicon 56, 849–854 (2010).
Güntert, P. Automated NMR structure calculation with CYANA. Methods Mol. Biol. 278, 353–378 (2004).
Mobli, M., Stern, A. S., Bermel, W., King, G. F. & Hoch, J. C. A non-uniformly sampled 4D HCC(CO)NH-TOCSY experiment processed using maximum entropy for rapid protein sidechain assignment. J. Magn. Reson. 204, 160–164 (2010).
Davis, I. W. et al. MolProbity: all-atom contacts and structure validation for proteins and nucleic acids. Nucleic Acids Res. 35, W375–W383 (2007).
Kwan, A. H., Mobli, M., Gooley, P. R., King, G. F. & Mackay, J. P. Macromolecular NMR spectroscopy for the non-spectroscopist. FEBS J. 278, 687–703 (2011).
Holm, L. & Rosenstrom, P. Dali server: conservation mapping in 3D. Nucleic Acids Res. 38, W545–W549 (2010).
Bende, N. S. et al. The insecticidal neurotoxin Aps III is an atypical knottin peptide that potently blocks insect voltage-gated sodium channels. Biochem. Pharmacol. 85, 1542–1554 (2013).
Milescu, M. et al. Tarantula toxins interact with voltage sensors within lipid membranes. J. Gen. Physiol. 130, 497–511 (2007).
Eberhard, W. Attack behavior of diguetid spiders and the origin of prey wrapping in spiders. Psyche 74, 173–181 (1967).
Liu, Z., Song, W. & Dong, K. Persistent tetrodotoxin-sensitive sodium current resulting from U-to-C RNA editing of an insect sodium channel. Proc. Natl Acad. Sci. USA 101, 11862–11867 (2004).
Trudeau, M. C., Warmke, J. W., Ganetzky, B. & Robertson, G. A. HERG, a human inward rectifier in the voltage-gated potassium channel family. Science 269, 92–95 (1995).
Cestele, S. et al. Structure and function of the voltage sensor of sodium channels probed by a beta-scorpion toxin. J. Biol. Chem. 281, 21332–21344 (2006).
Cestele, S. et al. Voltage sensor-trapping: enhanced activation of sodium channels by β-scorpion toxin bound to the S3-S4 loop in domain II. Neuron 21, 919–931 (1998).
Swartz, K. J. Tarantula toxins interacting with voltage sensors in potassium channels. Toxicon 49, 213–230 (2007).
Alabi, A. A., Bahamonde, M. I., Jung, H. J., Kim, J. I. & Swartz, K. J. Portability of paddle motif function and pharmacology in voltage sensors. Nature 450, 370–375 (2007).
Long, S. B., Tao, X., Campbell, E. B. & MacKinnon, R. Atomic structure of a voltage-dependent K+ channel in a lipid membrane-like environment. Nature 450, 376–382 (2007).
Aggarwal, S. K. & MacKinnon, R. Contribution of the S4 segment to gating charge in the Shaker K+ channel. Neuron 16, 1169–1177 (1996).
Seoh, S. A., Sigg, D., Papazian, D. M. & Bezanilla, F. Voltage-sensing residues in the S2 and S4 segments of the Shaker K+ channel. Neuron 16, 1159–1167 (1996).
Zagotta, W. N., Hoshi, T. & Aldrich, R. W. Shaker potassium channel gating. III: evaluation of kinetic models for activation. J. Gen. Physiol. 103, 321–362 (1994).
Delemotte, L., Tarek, M., Klein, M. L., Amaral, C. & Treptow, W. Intermediate states of the Kv1.2 voltage sensor from atomistic molecular dynamics simulations. Proc. Natl Acad. Sci. USA 108, 6109–6114 (2011).
Jensen, M. O. et al. Mechanism of voltage gating in potassium channels. Science 336, 229–233 (2012).
Tao, X., Lee, A., Limapichat, W., Dougherty, D. A. & MacKinnon, R. A gating charge transfer center in voltage sensors. Science 328, 67–73 (2010).
Gagnon, D. G. & Bezanilla, F. A single charged voltage sensor is capable of gating the Shaker K+ channel. J. Gen. Physiol. 133, 467–483 (2009).
Lacroix, J. J. et al. Intermediate state trapping of a voltage sensor. J. Gen. Physiol. 140, 635–652 (2012).
Buraei, Z., Anghelescu, M. & Elmslie, K. S. Slowed N-type calcium channel (CaV2.2) deactivation by the cyclin-dependent kinase inhibitor roscovitine. Biophys. J. 89, 1681–1691 (2005).
Capes, D. L., Goldschen-Ohm, M. P., Arcisio-Miranda, M., Bezanilla, F. & Chanda, B. Domain IV voltage-sensor movement is both sufficient and rate limiting for fast inactivation in sodium channels. J. Gen. Physiol. 142, 101–112 (2013).
Chanda, B. & Bezanilla, F. Tracking voltage-dependent conformational changes in skeletal muscle sodium channel during activation. J. Gen. Physiol. 120, 629–645 (2002).
Sheets, M. F., Kyle, J. W., Kallen, R. G. & Hanck, D. A. The Na channel voltage sensor associated with inactivation is localized to the external charged residues of domain IV, S4. Biophys. J. 77, 747–757 (1999).
Cestele, S. et al. Scorpion α-like toxins, toxic to both mammals and insects, differentially interact with receptor site 3 on voltage-gated sodium channels in mammals and insects. Eur. J. Neurosci. 11, 975–985 (1999).
Tan, J., Liu, Z., Nomura, Y., Goldin, A. L. & Dong, K. Alternative splicing of an insect sodium channel gene generates pharmacologically distinct sodium channels. J. Neurosci. 22, 5300–5309 (2002).
Bourdin, C. M. et al. Intron retention in mRNA encoding ancillary subunit of insect voltage-gated sodium channel modulates channel expression, gating regulation and drug sensitivity. PLoS ONE 8, e67290 (2013).
Catterall, W. A. et al. Voltage-gated ion channels and gating modifier toxins. Toxicon 49, 124–141 (2007).
Xiao, Y., Jackson, J. O. 2nd, Liang, S. & Cummins, T. R. Common molecular determinants of tarantula huwentoxin-IV inhibition of Na+ channel voltage sensors in domains II and IV. J. Biol. Chem. 286, 27301–27310 (2011).
Saez, N. J. et al. Spider-venom peptides as therapeutics. Toxins 2, 2851–2871 (2010).
Krepkiy, D. et al. Structure and hydration of membranes embedded with voltage-sensing domains. Nature 462, 473–479 (2009).
Zhang, J. Z. et al. Structure-function map of the receptor site for β-scorpion toxins in domain II of voltage-gated sodium channels. J. Biol. Chem. 286, 33641–33651 (2011).
Song, W. et al. Substitutions in the domain III voltage-sensing module enhance the sensitivity of an insect sodium channel to a scorpion β-toxin. J. Biol. Chem. 286, 15781–15788 (2011).
Corzo, G. et al. Distinct primary structures of the major peptide toxins from the venom of the spider Macrothele gigas that bind to sites 3 and 4 in the sodium channel. FEBS Lett. 547, 43–50 (2003).
Fang, L. et al. An improved strategy for high-level production of TEV protease in Escherichia coli and its purification and characterization. Protein Expr. Purif. 51, 102–109 (2007).
Mobli, M., Maciejewski, M. W., Gryk, M. R. & Hoch, J. C. An automated tool for maximum entropy reconstruction of biomolecular NMR spectra. Nat. Methods 4, 467–468 (2007).
Shen, Y., Delaglio, F., Cornilescu, G. & Bax, A. TALOS+: a hybrid method for predicting protein backbone torsion angles from NMR chemical shifts. J. Biomol. NMR 44, 213–223 (2009).
Eitan, M. et al. A scorpion venom neurotoxin paralytic to insects that affects sodium current inactivation: purification, primary structure, and mode of action. Biochemistry 29, 5941–5947 (1990).
Herzig, V. & Hodgson, W. C. Neurotoxic and insecticidal properties of venom from the Australian theraphosid spider Selenotholus foelschei. Neurotoxicology 29, 471–475 (2008).
Zhou, W. & Goldin, A. L. Use-dependent potentiation of the Nav1.6 sodium channel. Biophys. J. 87, 3862–3872 (2004).
Swartz, K. J. & MacKinnon, R. Hanatoxin modifies the gating of a voltage-dependent K+ channel through multiple binding sites. Neuron 18, 665–673 (1997).
Feng, G., Deak, P., Chopra, M. & Hall, L. M. Cloning and functional analysis of TipE, a novel membrane protein that enhances Drosophila para sodium channel function. Cell 82, 1001–1011 (1995).
Nguyen, M. N., Tan, K. P. & Madhusudhan, M. S. CLICK—topology-independent comparison of biomolecular 3D structures. Nucleic Acids Res. 39, W24–W28 (2011).
Acknowledgements
We would like to thank Ke Dong (Michigan State University), Kenton J Swartz (NIH), Peter Ruben (Simon Fraser University), Chris Ahern (University of Iowa), James Barrow (Johns Hopkins University/Lieber Institute for Brain Development), and Marie-France Martin-Eauclaire and Pierre E Bougis (University of Marseille) for sharing BgNav1/TipE, Kv2.1, hNav1.4, hNav1.5, hERG and BomIV, respectively. We thank Sandipan Chowdhury and Carlos Villalba-Galea for helpful discussions and Geoff Brown (Department of Agriculture, Fisheries and Forestry, Brisbane) for supply of blowflies. Parts of the research in this publication were supported by the Australian Research Council (Discovery Grant DP130103813 to G.F.K.) and the National Institute of Neurological Disorders and Stroke (NINDS) of the National Institutes of Health (NIH) under award number R00NS073797 (F.B.).
Author information
Authors and Affiliations
Contributions
N.S.B., S.D., M.M., V.H., J.G., G.M.N., G.F.K. and F.B. designed research; N.S.B., S.D., M.M., V.H., J.G., J.W., G.M.N., G.F.K. and F.B. performed research; N.S.B., S.D., M.M., V.H., G.M.N., G.F.K. and F.B. analysed data; N.S.B., S.D., M.M., V.H., G.M.N., G.F.K. and F.B. wrote the paper.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Supplementary information
Supplementary Figures, Table and Reference
Supplementary Figures 1-4, Supplementary Table 1 and Supplementary Reference (PDF 962 kb)
Supplementary Movie 1
Molecular surface representation of rDc1a with cationic, anionic, and hydrophobic residues colored blue, red, and green, respectively. (MOV 11636 kb)
Rights and permissions
About this article
Cite this article
Bende, N., Dziemborowicz, S., Mobli, M. et al. A distinct sodium channel voltage-sensor locus determines insect selectivity of the spider toxin Dc1a. Nat Commun 5, 4350 (2014). https://doi.org/10.1038/ncomms5350
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/ncomms5350
This article is cited by
-
Towards a generic prototyping approach for therapeutically-relevant peptides and proteins in a cell-free translation system
Nature Communications (2022)
-
An insecticidal toxin from Nephila clavata spider venom
Amino Acids (2017)
-
Gene design, fusion technology and TEV cleavage conditions influence the purification of oxidized disulphide-rich venom peptides in Escherichia coli
Microbial Cell Factories (2017)
-
Molecular basis of the interaction between gating modifier spider toxins and the voltage sensor of voltage-gated ion channels
Scientific Reports (2016)
-
Selective spider toxins reveal a role for the Nav1.1 channel in mechanical pain
Nature (2016)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.