Denise A. Adams

Novel omega -Conotoxins from Conus catus Discriminate among Neuronal Calcium Channel Subtypes

ω-Conotoxins selective for N-type calcium channels are useful in the management of severe pain. In an attempt to expand the therapeutic potential of this class, four new ω-conotoxins (CVIA–D) have been discovered in the venom of the piscivorous cone snail, Conus catus, using assay-guided fractionation and gene cloning. Compared with other ω-conotoxins, CVID has a novel loop 4 sequence and the highest selectivity for N-type over P/Q-type calcium channels in radioligand binding assays. CVIA−D also inhibited contractions of electrically stimulated rat vas deferens. In electrophysiological studies, ω-conotoxins CVID and MVIIA had similar potencies to inhibit current through central (α1B-d) and peripheral (α1B-b) splice variants of the rat N-type calcium channels when coexpressed with rat β3 in Xenopus oocytes. However, the potency of CVID and MVIIA increased when α1B-d and α1B-b were expressed in the absence of rat β3, an effect most pronounced for CVID at α1B-d (up to 540-fold) and least pronounced for MVIIA at α1B-d (3-fold). The novel selectivity of CVID may have therapeutic implications. 1H NMR studies reveal that CVID possesses a combination of unique structural features, including two hydrogen bonds that stabilize loop 2 and place loop 2 proximal to loop 4, creating a globular surface that is rigid and well defined.

Isolation and Structure-Activity of μ-Conotoxin TIIIA, A Potent Inhibitor of Tetrodotoxin-Sensitive Voltage-Gated Sodium Channels

μ-Conotoxins are three-loop peptides produced by cone snails to inhibit voltage-gated sodium channels during prey capture. Using polymerase chain reaction techniques, we identified a gene sequence from the venom duct of Conus tulipa encoding a new μ-conotoxin-TIIIA (TIIIA). A 125I-TIIIA binding assay was established to isolate native TIIIA from the crude venom of Conus striatus. The isolated peptide had three post-translational modifications, including two hydroxyproline residues and C-terminal amidation, and <35% homology to other μ-conotoxins. TIIIA potently displaced [3H]saxitoxin and 125I-TIIIA from rat brain (Nav1.2) and skeletal muscle (Nav1.4) membranes. Alanine and glutamine scans of TIIIA revealed several residues, including Arg14, that were critical for high-affinity binding to tetrodotoxin (TTX)-sensitive Na+ channels. We were surprised to find that [E15A]TIIIA had a 10-fold higher affinity than TIIIA for TTX-sensitive sodium channels (IC50, 15 vs. 148 pM at rat brain membrane). TIIIA was selective for Nav1.2 and -1.4 over Nav1.3, -1.5, -1.7, and -1.8 expressed in Xenopus laevis oocytes and had no effect on rat dorsal root ganglion neuron Na+ current. 1H NMR studies revealed that TIIIA adopted a single conformation in solution that was similar to the major conformation described previously for μ-conotoxin PIIIA. TIIIA and analogs provide new biochemical probes as well as insights into the structure-activity of μ-conotoxins.

Neuronally Selective μ-Conotoxins from Conus striatus Utilize an α-Helical Motif to Target Mammalian Sodium Channels

μ-Conotoxins are small peptide inhibitors of muscle and neuronal tetrodotoxin (TTX)-sensitive voltage-gated sodium channels (VGSCs). Here we report the isolation of μ-conotoxins SIIIA and SIIIB by 125I-TIIIA-guided fractionation of milked Conus striatus venom. SIIIA and SIIIB potently displaced 125I-TIIIA from native rat brain Nav1.2 (IC50 values 10 and 5 nm, respectively) and muscle Nav1.4 (IC50 values 60 and 3 nm, respectively) VGSCs, and both inhibited current through Xenopus oocyte-expressed Nav1.2 and Nav1.4. An alanine scan of SIIIA-(2–20), a pyroglutamate-truncated analogue with enhanced neuronal activity, revealed residues important for affinity and selectivity. Alanine replacement of the solvent-exposed Trp-12, Arg-14, His-16, Arg-18 resulted in large reductions in SIIIA-(2–20) affinity, with His-16 replacement affecting structure. In contrast, [D15A]SIIIA-(2–20) had significantly enhanced neuronal affinity (IC50 0.65 nm), while the double mutant [D15A/H16R]SIIIA-(2–20) showed greatest Nav1.2 versus 1.4 selectivity (136-fold). 1H NMR studies revealed that SIIIA adopted a single conformation in solution comprising a series of turns and anα-helical motif across residues 11–16 that is not found in larger μ-conotoxins. The structure of SIIIA provides a new structural template for the development of neuronally selective inhibitors of TTX-sensitive VGSCs based on the smaller μ-conotoxin pharmacophore.

N- and c-terminal extensions of μ-conotoxins increase potency and selectivity for neuronal sodium channels

μ‐Conotoxins are peptide blockers of voltage‐gated sodium channels (sodium channels), inhibiting tetrodotoxin‐sensitive neuronal (Nav1.2) and skeletal (Nav1.4) subtypes with highest affinity. Structure‐activity relationship studies of μ‐conotoxins SIIIA, TIIIA, and KIIIA have shown that it is mainly the C‐terminal part of the three‐loop peptide that is involved in binding to the sodium channel. In this study, we characterize the effect of N‐ and C‐terminal extensions of μ‐conotoxins SIIIA, SIIIB, and TIIIA on their potency and selectivity for neuronal versus muscle sodium channels. Interestingly, extending the N‐ or C‐terminal of the peptide by introducing neutral, positive, and/or negatively charged residues, the selectivity of the native peptide can be altered from neuronal to skeletal and the other way around. The results from this study provide further insight into the binding profile of μ‐conotoxins at voltage‐gated sodium channels, revealing that binding interactions outside the cysteine‐stablilized loops can contribute to μ‐conotoxin affinity and sodium channel selectivity.