Direct Visualization of Disulfide Bonds through Diselenide Proxies Using77Se NMR Spectroscopy

NMR methods for determining disulfide-bond connectivities

Animal toxins are the major class of secreted disulfide-rich proteins, with approximately 70% containing two or more disulfide bonds. Incorrect pairing of these disulfide bonds typically leads to a non-native three-dimensional fold accompanied by a loss of protein function. Determination of the native disulfide-bond framework is therefore a key component in the structural characterization of toxins. In this article, we review NMR approaches for elucidation of disulfide-bond connectivities. A major advantage of these NMR approaches is that they are non-invasive, leaving the sample intact at the end of the analysis for use in other studies.

Disulfide-Depleted Selenoconopeptides: a Minimalist Strategy to Oxidative Folding of Cysteine-Rich Peptides

Despite the therapeutic promise of disulfide-rich, peptidic natural products, their discovery and structure/function studies have been hampered by inefficient oxidative folding methods for their synthesis. Here we report that converting the three disulfide-bridged mu-conopeptide KIIIA into a disulfide-depleted selenoconopeptide (by removal of a noncritical disulfide bridge and substitution of a disulfide- with a diselenide-bridge) dramatically simplified its oxidative folding while preserving the peptide's ability to block voltage-gated sodium channels. The simplicity of synthesizing disulfide-depleted selenopeptide analogs containing a single disulfide bridge allowed rapid positional scanning at Lys7 of mu-KIIIA, resulting in the identification of K7L as a mutation that improved the peptide's selectivity in blocking a neuronal (Na(v)1.2) over a muscle (Na(v)1.4) subtype of sodium channel. The disulfide-depleted selenopeptide strategy offers regioselective folding compatible with high throughput chemical synthesis and on-resin oxidation methods, and thus shows great promise to accelerate the use of disulfide-rich peptides as research tools and drugs.

Site-specific effects of diselenide bridges on the oxidative folding of a cystine knot peptide, omega-selenoconotoxin GVIA

Structural and functional studies of small, disulfide-rich peptides depend on their efficient chemical synthesis and folding. A large group of peptides derived from animals and plants contains the Cys pattern C-C-CC-C-C that forms the inhibitory cystine knot (ICK) or knottin motif. Here we report the effect of site-specific incorporation of pairs of selenocysteine residues on oxidative folding and the functional activity of omega-conotoxin GVIA, a well-characterized ICK-motif peptidic antagonist of voltage-gated calcium channels. Three selenoconotoxin GVIA analogues were chemically synthesized; all three folded significantly faster in the glutathione-based buffer compared to wild-type GVIA. One analogue, GVIA[C8U,C19U], exhibited significantly higher folding yields. A recently described NMR-based method was used for mapping the disulfide connectivities in the three selenoconotoxin analogues. The diselenide-directed oxidative folding of selenoconotoxins was predominantly driven by amino acid residue loop sizes formed by the resulting diselenide and disulfide cross-links. Both in vivo and in vitro activities of the analogues were assessed; the block of N-type calcium channels was comparable among the analogues and wild-type GVIA, suggesting that the diselenide replacement did not affect the bioactive conformation. Thus, diselenide substitution may facilitate oxidative folding of pharmacologically diverse ICK peptides. The diselenide replacement has been successfully applied to a growing number of bioactive peptides, including alpha-, mu-, and omega-conotoxins, suggesting that the integrated oxidative folding of selenopeptides described here may prove to be a general approach for efficient synthesis of diverse classes of disulfide-rich peptides.