The three-dimensional solution structure of mini-M conotoxin BtIIIA reveals a disconnection between disulfide connectivity and peptide fold

Abstract

Conotoxins are bioactive peptides from the venoms of marine snails and have been divided into several superfamilies based on homologies in their precursor sequences. The M-superfamily conotoxins can be further divided into five branches based on the number of residues in the third loop of the peptide sequence. Recently two M-1 branch conotoxins (tx3a and mr3e) with a C1–C5, C2–C4, C3–C6 disulfide connectivity and one M-2 branch conotoxin (mr3a) with a C1–C6, C2–C4, C3–C5 disulfide connectivity were described. Here we report the disulfide connectivity, chemical synthesis and the three-dimensional NMR structure of the novel 14-residue conotoxin BtIIIA, extracted from the venom of Conus betulinus. It has the same disulfide connectivity as mr3a, which puts it in the M-2 branch conotoxins but has a distinctly different structure from other M-2 branch conotoxins. 105 NOE distance restraints and seven dihedral angle restraints were used for the structure calculations. The three-dimensional structure was determined with CYANA based on torsion angle dynamics and refinement in a water solvent box was carried out with CNS. Fifty structures were calculated and the 20 lowest energy structures superimposed with a RMSD of 0.49±0.16Å. Even though it has the M-2 branch disulfide connectivity, BtIIIA was found to have a ‘flying bird’ backbone motif depiction that is found in the M-1 branch conotoxin mr3e. This study shows that conotoxins with the same cysteine framework can have different disulfide connectivities and different peptide folds.