Disulfide-bound dimers of three-fingered toxins have been discovered in the Naja kaouthia cobra venom; that is, the homodimer of ␣-cobratoxin (a long-chain ␣-neurotoxin) and heterodimers formed by ␣-cobratoxin with different cytotoxins. According to circular dichroism measurements, toxins in dimers retain in general their three-fingered folding. The functionally important disulfide 26 -30 in polypeptide loop II of ␣-cobratoxin moiety remains intact in both types of dimers. Biological activity studies showed that cytotoxins within dimers completely lose their cytotoxicity. However, the dimers retain most of the ␣-cobratoxin capacity to compete with ␣-bungarotoxin for binding to Torpedo and ␣7 nicotinic acetylcholine receptors (nAChRs) as well as to Lymnea stagnalis acetylcholine-binding protein. Electrophysiological experiments on neuronal nAChRs expressed in Xenopus oocytes have shown that ␣-cobratoxin dimer not only interacts with ␣7 nAChR but, in contrast to ␣-cobratoxin monomer, also blocks ␣32 nAChR. In the latter activity it resembles -bungarotoxin, a dimer with no disulfides between monomers. These results demonstrate that dimerization is essential for the interaction of three-fingered neurotoxins with heteromeric ␣32 nAChRs.
Three-fingered toxins (TFTs)2 are the main components of the Elapidae snake venoms. TFTs consist of one polypeptide chain, their spatial structure being characterized by a hydrophobic core stabilized by four disulfide bridges, which confine three polypeptide loops (fingers). In cobra venom TFTs are represented mainly by ␣-neurotoxins and cytotoxins. So-called short-chain ␣-neurotoxins (60 -62 amino acid residues, 4 intramolecular disulfides) effectively block nicotinic acetylcholine receptors (nAChRs) of muscle-type, and long-chain ␣-neurotoxins (65-75 residues with an additional disulfide in central loop II) block neuronal homopentameric ␣7 nAChR as well (1, 2). These toxins are widely used as tools in the nAChR studies. Cytotoxins, structurally related to short-chain ␣-neurotoxins, manifest another activity; they non-selectively disrupt cell membranes and, thus, kill the cells (3).Another example of TFT interacting with nAChR are -bungarotoxins (-Bgts), minor components of the krait (Elapidae) venom (4, 5). All -Bgts consist of 66 amino acid residues and, similar to long-chain ␣-neurotoxins, contain five disulfide bonds. However, in contrast to ␣-neurotoxins, -Bgts practically do not block muscle-type nAChRs and only weakly act on ␣7 nAChR but with high efficiency interact with ␣32 neuronal receptors (6). Despite the vast array of data on structure-activity relationship for ␣-neurotoxins and -Bgts, it is not yet clear what are the main structural features determining the specificity of a toxin to the particular receptor type. Recently, based on the x-ray structure of ␣-cobratoxin (␣-CT) with acetylcholinebinding protein, Bourne et al. (7) suggested that Lys-29 is the main residue determining the difference in specificity between ␣-neurotoxins and -bungarotoxins. However, A29K mut...
