CSTX-13, a highly synergistically acting two-chain neurotoxic enhancer in the venom of the spider Cupiennius salei (Ctenidae)

An increasing number of ion channel toxins and related polypeptides have been found to adopt a common structural motif designated the inhibitor cystine knot motif (Pallaghy P. K., Nielsen, K. J., Craik, D. J., Norton, R. S. (1994) A common structural motif incorporating a cystine knot and triple-stranded beta-sheet in toxic and inhibitory polypeptides. Protein Science 3, 1833-1839). These globular, disulfide-stabilized molecules come from phylogenetically diverse sources, including spiders, cone shells, plants and fungi, and have various functions, although many target voltage-gated ion-channels. The common motif consists of a cystine knot and a triple-stranded, anti-parallel beta-sheet. Examples of ion-channel toxins known to adopt this structure are the omega-conotoxins and omega-agatoxins, and, more recently, robustoxin, versutoxin and protein 5 from spiders, as well as kappa-conotoxin PVIIA and conotoxin GS from cone shells. The variations on the motif structure exemplified by these structures are described here. We also consider the sequences of several polypeptides that might adopt this fold, including SNX-325 from a spider, delta-conotoxin PVIA and the muO-conotoxins from cone shells, and various plant and fungal polypeptides. The interesting case of the two- and three-disulfide bridged binding domains of the cellobiohydrolases from the fungus Trichoderma reesei is also discussed. The compact and robust nature of this motif makes it an excellent scaffold for the design and engineering of novel polypeptides with enhanced activity against existing targets, or with activity against novel targets.

Histamine has been shown to play a role in arthropod vision; it is the major neurotransmitter of arthropod photoreceptors. Histamine-gated chloride channels have been identified in insect optic lobes. We report the first isolation of cDNA clones encoding histamine-gated chloride channel subunits from the fruit fly Drosophila melanogaster. The encoded proteins, HisCl1 and HisCl2, share 60% amino acid identity with each other. The closest structural homologue is the human glycine alpha3 receptor, which shares 45 and 43% amino acid identity respectively. Northern hybridization analysis suggested that hisCl1 and hisCl2 mRNAs are predominantly expressed in the insect eye. Oocytes injected with in vitro transcribed RNA, encoding either HisCl1 or HisCl2, produced substantial chloride currents in response to histamine but not in response to GABA, glycine, and glutamate. The histamine sensitivity was similar to that observed in insect laminar neurons. Histamine-activated currents were not blocked by picrotoxinin, fipronil, strychnine, or the H2 antagonist cimetidine. Co-injection of both hisCl1 and hisCl2 RNAs resulted in expression of a histamine-gated chloride channel with increased sensitivity to histamine, demonstrating coassembly of the subunits. The insecticide ivermectin reversibly activated homomeric HisCl1 channels and, more potently, HisCl1 and HisCl2 heteromeric channels.

Five amphipathic peptides with antimicrobial, hemolytic, and insecticidal activity were isolated from the crude venom of the wolf spider Oxyopes kitabensis. The peptides, named oxyopinins, are the largest linear cationic amphipathic peptides from the venom of a spider that have been chemically characterized at present. According to their primary structure Oxyopinin 1 is composed of 48 amino acid residues showing extended sequence similarity to the ant insecticidal peptide ponericinL2 and to the frog antimicrobial peptide dermaseptin. Oxyopinins 2a, 2b, 2c, and 2d have highly similar sequences. At least 27 out of 37 amino acid residues are conserved. They also show a segment of sequence similar to ponericinL2. Circular dichroism analyses showed that the secondary structure of the five peptides is essentially alpha-helical. Oxyopinins showed disrupting activities toward both biological membranes and artificial vesicles, particularly to those rich in phosphatidylcholine. Electrophysiological recordings performed on insect cells (Sf9) showed that the oxyopinins produce a drastic reduction of cell membrane resistance by opening non-selective ion channels. Additionally, a new paralytic neurotoxin named Oxytoxin 1 was purified from the same spider venom. It contains 69 amino acid residue cross-linked by five disulfide bridges. Application of mixtures containing oxyopinins and Oxytoxin 1 to insect larvae showed a potentiation phenomenon, by which an increase lethality effect is observed. These results suggest that the linear amphipathic peptides in spider venoms and neuropeptides cooperate to capture insects efficiently.