A marker-coupled method for site-directed mutagenesis

A marker-coupled method for site-directed mutagenesis (SDM) has been developed. In this method, target DNA is first cloned into a plasmid vector which carries an inactivated tetracycline-resistance (TcR)-encoding tet gene. Using this cloned plasmid as template, polymerase chain reaction (PCR) is performed with a mutagenic primer and a marker primer. The mutagenic primer contains the desired mutations to be introduced into the target DNA, and the marker primer contains a mutation for restoring the activity of the inactivated tet gene. The PCR product is annealed with a gapped duplex plasmid template, extended and ligated in vitro. The resulting uni-strand-mutated plasmid is converted into the gapped duplex form, transformed into Escherichia coli JM109 and spread on yeast extract/tryptone culture medium + Tc plates. The TcR colonies grown on these plates all carry active tet genes. Due to the 'tight coupling' between the marker primer and the mutagenic primer formed in the PCR product, these TcR colonies should also carry the mutagenic primer, e.g., the desired mutations in the target DNA. In fact, practically all of the TcR colonies have been found to be the desired mutants in the present experiments. Therefore, this method provides a very efficient approach for SDM.     

Creating random mutagenesis libraries using megaprimer PCR of whole plasmid

The conventional method for cloning a DNA fragment is to insert it into a vector and ligate it. Although this method is commonly used, it is labor intensive because the ratio and concentrations of the DNA insert and the vector need optimizing. Even then, the resultant library is often plagued with unwanted plasmids that have no inserts or multiple inserts. These species have to be eradicated to avoid tedious screening, especially when producing a mutant gene library. To overcome these problems, we modified the QuikChange protocol so that each plasmid carries a single insert. Although the QuikChange was originally developed for site-directed mutagenesis using complementary mutagenic oligonucleotide primers in whole plasmid PCR, we found that the protocol also worked for megaprimers consisting of hundreds of nucleotides. Based on this discovery, we used insert fragments, which we wanted to clone, as the primers in the QuikChange reaction. The resultant libraries were virtually free from species with no inserts or multiple inserts. The present method, which we designated MEGAWHOP (megaprimer PCR of whole plasmid), is thus ideal for creating random mutagenesis megalibraries.     

Suggestions for "safe" residue substitutions in site-directed mutagenesis

The conserved topological structure observed in various molecular families such as globins or cytochromes c allows structural equivalencing of residues in every homologous structure and defines in a coherent way a global alignment in each sequence family. A search was performed for equivalent residue pairs in various topological families that were buried in protein cores or exposed at the protein surface and that had mutated but maintained similar unmutated environments. Amino acid residues with atoms in contact with the mutated residue pairs defined the environment. Matrices of preferred amino acid exchanges were then constructed and preferred or avoided amino acid substitutions deduced. Given the conserved atomic neighborhoods, such natural in vivo substitutions are subject to similar constrains as point mutations performed in site-directed mutagenesis experiments. The exchange matrices should provide guidelines for "safe" amino acid substitutions least likely to disturb the protein structure, either locally or in its overall folding pathway, and most likely to allow probing the structural and functional significance of the substituted site.     

An improved dual-tube megaprimer approach for multi-site saturation mutagenesis

Saturation mutagenesis is a powerful tool in protein engineering. Even though QuikChange site-directed mutagenesis method is dominantly used in laboratories, it could not be successfully applied to the generation of a focused mutant library of human glutathione transferase A2-2. In the present study, we further developed an improved versatile dual-tube approach of randomizing difficult-to-amplify targets, exhibiting significant improvement towards equal distribution of nucleotides at randomized sites compared to other published methods.     

A novel simple and rapid PCR-based site-directed mutagenesis method

Site-directed mutagenesis (SDM) is a powerful tool for exploring protein structure and function, and several procedures adjusted to specific purposes are still being developed. Herein we describe a straightforward and efficient method with versatile applications for introducing site-specific alterations in any deoxyribonucleic acid (DNA) sequence cloned in a plasmidic expression vector. In this polymerase chain reaction (PCR)-based SDM method, forward and reverse primers are used to amplify the plasmid containing the sequence of interest. The primers are designed so that the desired modifications are introduced at the 5′ end of one of the primers, whereas the other primer starts with the nucleotide at position (−1) of the one to be modified. The PCR is carried out using Pfu DNA polymerase. The blunt-ended PCR-generated DNA fragment is self-ligated and used to transform Escherichia coli. Mutant clones are screened by colony hybridization using the mutagenic primer as probe and the presence of the mutation is confirmed by direct DNA sequencing. This procedure was used efficiently to introduce substitutions, deletions, and insertions in the DNA sequences coding for a recombinant form (scFv) of antibody 107 specific of the human CR3 molecule, the rat α integrin CD11b A-domain and the human CD8β cloned in pPICZαB, pGEX-2T, and CDM8 expression vectors, respectively.     

A high efficiency method for site-directed mutagenesis with any plasmid

A procedure is described which allows for the site-directed mutagenesis of DNA segments in any double-stranded plasmid with high efficiency. There are no limitations as to the position of the mutation. The protocol involves only simple enzymatic manipulations and no difficult to control operations, such as partial digestions, are required. The method was developed and used to mutagenize two different genes (encoding human interferon-beta and interleukin-2) cloned in a eukaryotic expression vector. For ten mutageneses with different oligodeoxyribonucleotides the average yield of mutants was 60%.     

A novel megaprimed and ligase-free, PCR-based, site-directed mutagenesis method

In this study, we report a novel megaprimed and ligase-free, PCR-based, site-directed mutagenesis method modified from the QuikChange site-directed mutagenesis (QCM). One mutagenic oligonucleotide and one universal flanking primer were used to produce the complementary megaprimers that were then used to amplify the whole plasmid template. This method yields a mutagenesis efficiency ( approximately 90%) similar to that of QCM but uses only one mutagenic oligonucleotide instead of two of them, and the length of the oligonucleotide could be shorter. This method can be further extended to double mutations that are located at distant sites by using two mutagenic oligonucleotides and even to site saturation mutagenesis by introducing randomized codons.     

Rapid and efficient site-directed mutagenesis by single-tube 'megaprimer' PCR method.

We describe a rapid and efficient megaprimer PCR procedure for site-directed mutagenesis that does not require any intermediate purification of DNA between the two rounds of PCR. This protocol is based on the design of forward and reverse flanking primers with significantly different melting temperatures ( T m). A megaprimer is synthesized in the first PCR reaction using a mutagenic primer, the low T m flanking primer and a low annealing temperature. The second PCR reaction is performed in the same tube as the first PCR and utilizes the high T m flanking primer, the megaprimer product of the first PCR and a high annealing temperature, which prevents priming by the low T m primer from the first PCR reaction. We have used this protocol with two different plasmids to produce cDNAs encoding seven distinct mutated proteins. We have observed an average mutagenesis efficiency of 82% in these experiments.     

Activation of aspartase by site-directed mutagenesis

To elucidate the role of sulfhydryl groups in the enzymatic reaction of the aspartase from Escherichia coli, we used site-directed mutagenesis which showed that the enzyme was activated by replacement of Cys-430 with a tryptophan. This mutation produced functional alterations without appreciable structural change: The kcat values became 3-fold at pH 6.0; the Hill coefficient values became higher under both pH conditions; the dependence of enzyme activity on divalent metal ions increased; and hydroxylamine, a good substrate for the wild-type enzyme, proved a poor substrate for the mutant.     

Saturation site-directed mutagenesis of thymidylate synthase

We have subjected 12 different codons of a synthetic Lactobacillus casei thymidylate synthase (TS) gene to saturation site-directed mutagenesis to create amino acid "replacement sets" at each of those positions. The target residues were chosen because they are highly conserved and because they are important for the structure and function of the protein as indicated by solution and structural studies. The mutagenesis procedure involved excision of a fragment of the synthetic gene containing the target codon, followed by its replacement with a mixture of oligonucleotides which code for all 20 amino acids and the amber stop codon. TS mutants were identified by DNA sequencing, and catalytically active mutants were identified by genetic complementation using a Thy- strain of Escherichia coli. Only 3 of the 12 target amino acids examined were essential for TS activity; and of the 125 total mutants identified, 57 were catalytically active. These results point to a high degree of plasticity of TS in accommodating function with structural change.