Curaremimetic toxins from snake venoms form a large family of small proteins that adopt a similar fold and which bind to Torpedo nicotinic acetylcholine receptors with high affinity. Notwithstanding its apparent homogeneity, the toxin family is subdivided into short-chain (60-62 residues and four disulfide bonds) and long-chain toxins (66-74 residues and five disulfide bonds). In agreement with this structurally-based distinction we recently showed that only long-chain toxins bind with high affinity to the neuronal nicotinic acetylcholine alpha7 receptor. We suggested that a small loop cyclized by a disulfide bond and uniquely present in long-chain toxins may act as a major discriminative element. To assess the validity of this proposal we prepared various derivatives of a long-chain toxin, using stepwise solid-phase synthesis. We found that replacement of both half cystines of the small loop by a serine caused a 35-fold affinity decrease for the neuronal receptor and only a 6-fold affinity decrease for Torpedo receptor. In addition, insertion of this loop at a homologous position of a short-chain toxin caused a 20-fold affinity increase for the neuronal receptor whereas it did not modify its affinity for the Torpedo receptor. Our findings, therefore, reveal that a small structural deviation from a toxin fold can generate exquisite discriminative recognition for some receptor subtypes.