Animal toxins acting on ion channels of excitable cells are principally highly potent short peptides that are present in limited amounts in the venoms of various unrelated species, such as scorpions, snakes, sea anemones, spiders, insects, marine cone snails and worms. These toxins have been used extensively as invaluable biochemical and pharmacological tools to characterize and discriminate between the various ion channel types that differ in ionic selectivity, structure and/or cell function. Alongside the huge molecular and functional diversity of ion channels, a no less impressive structural diversity of animal toxins has been indicated by the discovery of an increasing number of polypeptide folds that are able to target these ion channels. Indeed, it appears that these peptide toxins have evolved over time on the basis of clearly distinct architectural motifs, in order to adapt to different ion channel modulating strategies (pore blockers compared with gating modifiers). Herein, we provide an up-to-date overview of the various types of fold from animal toxins that act on ion channels selective for K+, Na+, Ca2+ or Cl- ions, with special emphasis on disulphide bridge frameworks and structural motifs associated with these peptide folds.
Animal venoms are rich natural sources of bioactive compounds, including peptide toxins acting on the various types of ion channels, i.e. K(+), Na(+), Cl(-) and Ca(2+). Among K+ channel-acting toxins, those selective for voltage-gated K(+) (Kv) channels are widely represented and have been isolated from the venoms of numerous animal species, such as scorpions, sea anemones, snakes, marine cone snails and spiders. The toxins characterized hitherto contain between 22 and 60 amino acid residues, and are cross-linked by two to four disulfide bridges. Depending on their types of fold, toxins can be classified in eight structural categories, which showed a combination of beta-strands, helices, or a mixture of both. The main architectural motifs thereof are referred to as alpha/beta scaffold and inhibitor cystine knot (ICK). A detailed analysis of toxin structures and pharmacological selectivities indicates that toxins exhibiting a similar type of fold can exert their action on several subtypes of Kv channels, whereas a particular Kv channel can be targeted by toxins that possess unrelated folds. Therefore, it appears that the ability of structurally divergent toxins to interact with a particular Kv channel relies onto a similar spatial distribution of amino acid residues that are key to the toxin-channel interaction (rather than the type of toxin fold). The diversity of Kv channel blockers and their therapeutic value in the potential treatment of a number of specific human diseases, especially autoimmune disorders, inflammatory neuropathies and cancer, are reviewed.
OSK1 (alpha-KTx3.7) is a 38-residue toxin cross-linked by three disulphide bridges that was initially isolated from the venom of the Asian scorpion Orthochirus scrobiculosus. OSK1 and several structural analogues were produced by solid-phase chemical synthesis, and were tested for lethality in mice and for their efficacy in blocking a series of 14 voltage-gated and Ca2+-activated K+ channels in vitro. In the present paper, we report that OSK1 is lethal in mice by intracerebroventricular injection, with a LD50 (50% lethal dose) value of 2 microg/kg. OSK1 blocks K(v)1.1, K(v)1.2, K(v)1.3 channels potently and K(Ca)3.1 channel moderately, with IC50 values of 0.6, 5.4, 0.014 and 225 nM respectively. Structural analogues of OSK1, in which we mutated positions 16 (Glu16-->Lys) and/or 20 (Lys20-->Asp) to amino acid residues that are conserved in all other members of the alpha-KTx3 toxin family except OSK1, were also produced and tested. Among the OSK1 analogues, [K16,D20]-OSK1 (OSK1 with Glu16-->Lys and Lys20-->Asp mutations) shows an increased potency on K(v)1.3 channel, with an IC50 value of 0.003 nM, without loss of activity on K(Ca)3.1 channel. These data suggest that OSK1 or [K16,D20]-OSK1 could serve as leads for the design and production of new immunosuppressive drugs.
Pi1 is a 35-residue scorpion toxin cross-linked by four disulphide bridges that acts potently on both small-conductance Ca2+-activated (SK) and voltage-gated (Kv) K+ channel subtypes. Two approaches were used to investigate the relative contribution of the Pi1 functional dyad (Tyr-33 and Lys-24) to the toxin action: (i) the chemical synthesis of a [A24,A33]-Pi1 analogue, lacking the functional dyad, and (ii) the production of a Pi1 analogue that is phosphorylated on Tyr-33 (P-Pi1). According to molecular modelling, this phosphorylation is expected to selectively impact the two amino acid residues belonging to the functional dyad without altering the nature and three-dimensional positioning of other residues. P-Pi1 was directly produced by peptide synthesis to rule out any possibility of trace contamination by the unphosphorylated product. Both Pi1 analogues were compared with synthetic Pi1 for bioactivity. In vivo, [A24,A33]-Pi1 and P-Pi1 are lethal by intracerebroventricular injection in mice (LD50 values of 100 and 40 microg/mouse, respectively). In vitro, [A24,A33]-Pi1 and P-Pi1 compete with 125I-apamin for binding to SK channels of rat brain synaptosomes (IC50 values of 30 and 10 nM, respectively) and block rat voltage-gated Kv1.2 channels expressed in Xenopus laevis oocytes (IC50 values of 22 microM and 75 nM, respectively), whereas they are inactive on Kv1.1 or Kv1.3 channels at micromolar concentrations. Therefore, although both analogues are less active than Pi1 both in vivo and in vitro, the integrity of the Pi1 functional dyad does not appear to be a prerequisite for the recognition and binding of the toxin to the Kv1.2 channels, thereby highlighting the crucial role of other toxin residues with regard to Pi1 action on these channels. The computed simulations detailing the docking of Pi1 peptides on to the Kv1.2 channels support an unexpected key role of specific basic amino acid residues, which form a basic ring (Arg-5, Arg-12, Arg-28 and Lys-31 residues), in toxin binding.
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