Disulfide isomerization and thiol-disulfide exchange of long neurotoxins from the venom of Ophiophagus hannah

Selective reduction on the Cys28–Cys32 disulfide of Ophiophagus hannah neurotoxins, Oh-4 and Oh-5, revealed that isomerization of this disulfide linkage caused the two toxins to have distinct conformation and different retention time on a reversed-phase column. The Cys28–Cys32 disulfide of Oh-4 and Oh-5 was prone to form mixed disulfides with glutathione following pseudo-first-order kinetics. In addition to glutathionylated proteins, Oh-4 could be promoted to convert into Oh-5 by thiol compounds. Isomerization of Oh-5 into Oh-4 was not observed in the presence of thiol compounds. Dethiolation of glutathionylated proteins produced Oh-4 and Oh-5. Oxidation of the partially reduced toxin with reduced Cys28 and Cys32 was exclusively converted into Oh-5 regardless of the absence or presence of GSH/GSSG. Acrylamide quenching studies revealed difference in degree of exposure of the single Trp27 between Oh-4 and Oh-5. Synthesized peptides with substitution of Trp27 or Phe31 with Gly abolished entirely the formation of disulfide-linked dimeric product noted with the peptide of wild-type sequence. These results suggest that disulfide formation and isomerization of Cys28–Cys32 could be regulated by thiolation, and that the bulky aromatic residues Trp27 and Phe31 facilitate favorably the occurrence of disulfide isomerization of Cys28–Cys32.