A Novel Lid-Covering Peptide Inhibitor of Nicotinic Acetylcholine Receptors Derived from αD-Conotoxin GeXXA.

Nicotinic acetylcholine receptors (nAChRs) play a fundamental role in nervous signal transmission, therefore various antagonists and agonists are highly desired to explore the structure and function of nAChRs. Recently, a novel dimeric αD-conotoxin GeXXA was identified to inhibit nAChRs by binding at the top surface of the receptors, and the monomeric C-terminal domain (CTD) of αD-GeXXA retains some inhibitory activity. In this study, the internal dimeric N-terminal domain (NTD) of this conopeptide was further investigated. We first developed a regio-selective protection strategy to chemically prepare the anti-parallel dimeric NTD, and found that the isolated NTD part of GeXXA possesses the nAChR-inhibitory activity, the subtype-dependence of which implies a preferred binding of NTD to the ß subunits of nAChR. Deletion of the NTD N-terminal residues did not affect the activity of NTD, indicating that the N-terminus is not involved in the interaction with nAChRs. By optimizing the sequence of NTD, we obtained a fully active single-chain cyclic NTD, based on which 4 Arg residues were found to interact with nAChRs. These results demonstrate that the NTD part of αD-GeXXA is a "lid-covering" nAChR inhibitor, displaying a novel inhibitory mechanism distinct from other allosteric ligands of nAChRs.

Conopeptide Vt3.1 preferentially inhibits BK potassium channels containing ß4 subunits via electrostatic interactions.

BK channel ß subunits (ß1-ß4) modulate the function of channels formed by slo1 subunits to produce tissue-specific phenotypes. The molecular mechanism of how the homologous ß subunits differentially alter BK channel functions and the role of different BK channel functions in various physiologic processes remain unclear. By studying channels expressed in Xenopus laevis oocytes, we show a novel disulfide-cross-linked dimer conopeptide, Vt3.1 that preferentially inhibits BK channels containing the ß4 subunit, which is most abundantly expressed in brain and important for neuronal functions. Vt3.1 inhibits the currents by a maximum of 71%, shifts the G-V relation by 45 mV approximately half-saturation concentrations, and alters both open and closed time of single channel activities, indicating that the toxin alters voltage dependence of the channel. Vt3.1 contains basic residues and inhibits voltage-dependent activation by electrostatic interactions with acidic residues in the extracellular loops of the slo1 and ß4 subunits. These results suggest a large interaction surface between the slo1 subunit of BK channels and the ß4 subunit, providing structural insight into the molecular interactions between slo1 and ß4 subunits. The results also suggest that Vt3.1 is an excellent tool for studying ß subunit modulation of BK channels and for understanding the physiological roles of BK channels in neurophysiology.

Various conotoxin diversifications revealed by a venomic study of Conus flavidus.

Conotoxins are peptide neurotoxins produced by predatory cone snails. They are mostly cysteine-rich short peptides with remarkable structural diversity. The conserved signal peptide sequences of their mRNA-encoded precursors have enabled the grouping of known conotoxins into a limited number of superfamilies. However, the conotoxins within each superfamily often present variable sequences, cysteine frameworks, and post-translational modifications. To understand better how conotoxins are diversified, we performed a venomic study with C. flavidus, an uninvestigated vermivorous Conus species, by combining transcriptomic and proteomic analyses. In order to obtain the full-length conotoxin sequences, protease digestion was not performed with the venom extraction prior to spectra acquisition via tandem mass spectrometry (MS/MS). Because conotoxins are produced from mRNA-encoded precursors by means of proteolytic cleavage, nonspecific digestion of precursors was applied during the database search. Special attention was also paid in interpreting the MS/MS spectra. All together, these analyses identified 69 nonredundant cDNA sequences and 31 conotoxin components with confident MS/MS spectra. A new Q-superfamily was also identified. More importantly, this study revealed that conotoxin-encoding transcripts are diversified by hypermutation, fragment insertion/deletion, and mutation-induced premature termination, and that a single mRNA species can produce multiple toxin products through alternative post-translational modifications and alternative cleavages of the translated precursor. These multiple diversification strategies at different levels may explain, at least in part, the diversity of conotoxins, and provide the basis for further investigation.