Substitutions of cysteine residues of Escherichia coli heat-stable enterotoxin by oligonucleotide-directed mutagenesis

Abstract

The Escherichia coli 18-amino-acid, heat-stable enterotoxin STp has six cysteine residues linked intramolecularly by three disulfide bonds. These disulfide bonds are important for toxic activity, but the precise role of each bond is not clear. We substituted cysteine residues of STp in vivo by oligonucleotide-directed site-specific mutangenesis to dissociate each disulfide bond and examined the biological activities of the resulting mutants. The Cys-6→Ala and Cys-17→Ala mutations caused a complete loss of toxic activity. The Cys-5→Ala, Cys-10→Ser, and Gly-16, Cys-17→Cys-16, Gly-17 mutations caused a large decrease in toxic activity. These results mean that all three disulfide bonds formed at fixed positions are required for full expression of the biological activity of STp. However, a weak but significant toxicity still remained after three mutations, Cys-5→Ala, Cys-10→Ser, and Gly-16, Cys-17→Cys-16, Gly-17. This indicates that STp has some flexibilities in its conformation to exert toxic activity and that the role of each disulfide bond in exerting toxic activity is not quite the same.