Peptide neurotoxins from cone snails continue to supply compounds with therapeutic potential. Although several analgesic conotoxins have already reached human clinical trials, a continuing need exists for the discovery and development of novel nonopioid analgesics, such as subtype-selective sodium channel blockers. -Conotoxin KIIIA is representative of -conopeptides previously characterized as inhibitors of tetrodotoxin (TTX)-resistant sodium channels in amphibian dorsal root ganglion neurons. Here, we show that KIIIA has potent analgesic activity in the mouse pain model. Surprisingly, KIIIA was found to block most (>80%) of the TTX-sensitive, but only ϳ20% of the TTX-resistant, sodium current in mouse dorsal root ganglion neurons. KIIIA was tested on cloned mammalian channels expressed in Xenopus oocytes. Both Na V 1.2 and Na V 1.6 were strongly blocked; within experimental wash times of 40 -60 min, block was reversed very little for Na V 1.2 and only partially for Na V 1.6. Other isoforms were blocked reversibly: Na V 1.3 (IC 50 8 M), Na V 1.5 (IC 50 284 M), and Na V 1.4 (IC 50 80 nM). "Alanine-walk" and related analogs were synthesized and tested against both Na V 1.2 and Na V 1.4; replacement of Trp-8 resulted in reversible block of Na V 1.2, whereas replacement of Lys-7, Trp-8, or Asp-11 yielded a more profound effect on the block of Na V 1.4 than of Na V 1.2. Taken together, these data suggest that KIIIA is an effective tool to study structure and function of Na V 1.2 and that further engineering of -conopeptides belonging to the KIIIA group may provide subtype-selective pharmacological compounds for mammalian neuronal sodium channels and potential therapeutics for the treatment of pain.Venoms are a rich source of neuroactive compounds that target various ion channels and receptors with exquisite potency and selectivity (1-4). There is a continuing need for more subtype-selective pharmacological agents against sodium channels (5), and cone snail venoms provide a unique pharmacopoeia of diverse sodium channel-targeting toxins, including channel blockers as well as inhibitors of channel inactivation (6 -18). -Conotoxins are short peptides that potently block sodium channels (Table 1). The first -conotoxins to be discovered from venom of Conus snails, GIIIA, GIIIB, GIIIC, and PIIIA, were paralytic in fish and potently inhibited skeletal muscle sodium channels in amphibian and mammalian systems.Recently, a second group of -conotoxins has been identified that, in contrast to previously characterized peptides that targeted the skeletal muscle sodium channels, inhibited TTX-resistant (TTX-r) 4 sodium channels when screened on amphibian neuronal preparations (19 -21). This group of conotoxins includes -conotoxin SmIIIA from Conus stercusmuscarum and -conotoxin KIIIA from Conus kinoshitai (Fig. 1). Structural and functional studies on peptides in this group to date suggest that amino acid residues in the C-terminal region of these peptides, including Trp and His (see Table 1), are important for function (19,22).It ...
Disulfide-rich neurotoxins from venomous animals continue to provide compounds with therapeutic potential. Minimizing neurotoxins often results in removal of disulfide bridges or critical amino acids. To address this drug-design challenge, we explored the concept of disulfide-rich scaffolds consisting of isostere polymers and peptidic pharmacophores. Flexible spacers, such as amino-3-oxapentanoic or 6-aminohexanoic acids, were used to replace conformationally constrained parts of a three-disulfide-bridged conotoxin, SIIIA. The peptide-polymer hybrids, polytides, were designed based on cladistic identification of nonconserved loci in related peptides. After oxidative folding, the polytides appeared to be better inhibitors of sodium currents in dorsal root ganglia and sciatic nerves in mice. Moreover, the polytides appeared to be significantly more potent and longer-lasting analgesics in the inflammatory pain model in mice, when compared to SIIIA. The resulting polytides provide a promising strategy for transforming disulfide-rich peptides into therapeutics.
MuO-conotoxin MrVIB is a blocker of voltage-gated sodium channels, including TTX-sensitive and -resistant subtypes. A comprehensive characterization of this peptide has been hampered by the lack of sufficient synthetic material. Here, we describe the successful chemical synthesis and oxidative folding of MrVIB that has made an investigation of the pharmacological properties and therapeutic potential of the peptide feasible. We show for the first time that synthetic MrVIB blocks rat NaV1.8 sodium channels and has potent and long-lasting local anesthetic effects when tested in two pain assays in rats. Furthermore, MrVIB can block propagation of action potentials in A- and C-fibers in sciatic nerve as well as skeletal muscle in isolated preparations from rat. Our work provides the first example of analgesia produced by a conotoxin that blocks sodium channels. The emerging diversity of antinociceptive mechanisms targeted by different classes of conotoxins is discussed.
Specificity, affinity and efficacy of iota-conotoxin RXIA, an agonist of voltage-gated sodium channels NaV1.2, 1.6 and 1.7
The excitotoxic conopeptide iota-RXIA induces repetitive action potentials in frog motor axons and seizures upon intracranial injection into mice. We recently discovered that iota-RXIA shifts the voltage-dependence of activation of voltage-gated sodium channel Na(V)1.6 to a more hyperpolarized level. Here, we performed voltage-clamp experiments to examine its activity against rodent Na(V)1.1 through Na(V)1.7 co-expressed with the beta1 subunit in Xenopus oocytes and Na(V)1.8 in dissociated mouse DRG neurons. The order of sensitivity to iota-RXIA was Na(V)1.6 > 1.2 > 1.7, and the remaining subtypes were insensitive. The time course of iota-RXIA-activity on Na(V)1.6 during exposure to different peptide concentrations were well fit by single-exponential curves that provided k(obs). The plot of k(obs)versus [iota-RXIA] was linear, consistent with a bimolecular reaction with a K(d) of approximately 3 microM, close to the steady-state EC(50) of approximately 2 microM. iota-RXIA has an unusual residue, D-Phe, and the analog with an L-Phe instead, iota-RXIA[L-Phe44], had a two-fold lower affinity and two-fold faster off-rate than iota-RXIA on Na(V)1.6 and furthermore was inactive on Na(V)1.2. iota-RXIA induced repetitive action potentials in mouse sciatic nerve with conduction velocities of both A- and C-fibers, consistent with the presence of Na(V)1.6 at nodes of Ranvier as well as in unmyelinated axons. Sixteen peptides homologous to iota-RXIA have been identified from a single species of Conus, so these peptides represent a rich family of novel sodium channel-targeting ligands.
Conotoxin ι-RXIA, from the fish-hunting species Conus radiatus, is a member of the recently characterized I 1 -superfamily, which contains eight cysteine residues arranged in a −C-C-CC-CC-C-C-pattern. ι-RXIA (formerly designated r11a) is one of three characterized I 1 peptides in which the third last residue is post-translationally isomerized to the D-configuration. Naturally occurring ι-RXIA with D-Phe44 is significantly more active as an excitotoxin than the L-Phe analogue both in vitro and in vivo. We have determined the solution structures of both forms by NMR spectroscopy, the first for an I 1 -superfamily member. The disulfide connectivities were determined from structure calculations and confirmed chemically as 5-19, 12-22, 18-27, and 21-38, suggesting that ι-RXIA has an ICK structural motif with one additional disulfide (21-38). Indeed, apart from the first few residues, the structure is well defined up to around residue 35 and does adopt an ICK structure. The C-terminal region, including Phe44, is disordered. Comparison of the D-Phe44 and L-Phe44 forms indicates that the switch from one enantiomer to the other has very little effect on the structure, even though it is clearly important for receptor interaction based on activity data. Finally, we identify the target of ι-RXIA as a voltage-gated sodium channel; ι-RXIA is an agonist, shifting the voltage dependence of activation of mouse Na V 1.6 expressed in Xenopus oocytes to more hyperpolarized potentials. Thus, there is a convergence of structure and function in ι-RXIA, as its disulfide pairing and structure resemble those of funnel web spider toxins that also target sodium channels.Through adaptive evolution, marine cone snails of the genus Conus have generated more than 70,000 different venom peptides (conopeptides) (1-3). These highly diverse peptides can be organized into several structural classes, with peptides in the same structural class generally belonging to the same gene superfamily. The peptides in a given superfamily share a highly conserved precursor signal sequence and a disulfide scaffold with a characteristic number, pattern, and pairing of cysteine residues in the mature toxin (1-3). Thus, despite hypermutation of amino acids between half-cystines, the disulfide framework remains conserved within a superfamily. In addition to the accelerated evolution of conopeptide sequences, further † This work was supported in part by N. NIH Public Access Author ManuscriptBiochemistry. Author manuscript; available in PMC 2008 October 13. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript molecular diversity is introduced through post-translational modifications. The occurrence of diverse modifications in Conus peptides is now well established (4) but the functional consequences of most post-translational modifications remain unknown, and mechanistic insights require detailed structure/function analyses, which have not been performed in most cases.Recently, we described the I-superfamily of Conus peptides, defined by...
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