21] Site-specific mutagenesis to modify the human tumor necrosis factor gene

Abstract

Publisher Summary The development of oligonucleotide-directed site-specific mutagenesis on single-stranded phage template has provided a powerful new technique in the study of structure-function relationships of proteins. This chapter describes a simplified procedure for oligonucleotide-directed site-specific mutagenesis on M13 single-stranded phage deoxyribo nucleic acid (DNA) templates. The rationale behind this approach is to make use of the DNA repair mechanism present in the E. coli host to repair the gapped M13 phage DNA into the covalently closed circular form before replication of the DNA molecules. The mutagenesis procedure described in this chapter provides a rapid method for the modification of cloned genes. It takes advantage of the ability of E. coli to efficiently repair gapped circular DNA molecules, to shorten the overall time of the mutagenesis, from initiation of the mutagenesis reaction to the identification of the mutant phage plaque. Although this faster method is less efficient in the conversion of parent DNA to mutant DNA molecules, the ability to use the same oligonucleotide primer as a probe to identify the mutant phage plaques effectively compensates for this inefficiency.