Site-specific forced misincorporation mutagenesis using modified T7 DNA polymerase

A new method for forced misincorporation site-specific mutagenesis is described. The method uses an exonuclease-deficient modified version of T7 DNA polymerase in the presence of one dNTP to force a misincorporation. Analysis by PAGE is used to monitor the efficiency of such misincorporation reactions. Brief extension of the terminally mismatched primer/template using the same enzyme in the presence of all four dNTPs is followed by chase/ligation using unmodified T7 DNA polymerase and T4 DNA ligase to give heteroduplex DNA. We have applied the method to mutagenesis of the Lac Z region of M13 and found that, using strand selection, efficiencies of mutagenesis at one site are greater than 50%. When the mutating dNTP is complementary to a neighbouring homopolymeric tract on the template, multiple mutation is observed and efficiences are lower. The method is more general than internal mismatch mutagenesis and, because of its rapidity, is more expedient than existing methods of forced misincorporation mutagenesis.     

One-step random mutagenesis by error-prone rolling circle amplification

In vitro random mutagenesis is a powerful tool for altering properties of enzymes. We describe here a novel random mutagenesis method using rolling circle amplification, named error-prone RCA. This method consists of only one DNA amplification step followed by transformation of the host strain, without treatment with any restriction enzymes or DNA ligases, and results in a randomly mutated plasmid library with 3–4 mutations per kilobase. Specific primers or special equipment, such as a thermal-cycler, are not required. This method permits rapid preparation of randomly mutated plasmid libraries, enabling random mutagenesis to become a more commonly used technique.     

Error-prone rolling circle amplification: the simplest random mutagenesis protocol

A simple protocol to introduce random mutations, named error-prone rolling circle amplification (RCA), is described. A template plasmid is amplified by RCA in the presence of MnCl2 and used for transformation of a host strain to give a mutant library with three to four random point mutations per kilobase throughout the entire plasmid. The prime advantage of this method is its simplicity. This protocol requires neither the design of specific primers nor the exploration of thermal cycling conditions. It takes just 10 min to prepare the reaction mixture, followed by overnight incubation and transformation of a host strain. This method permits rapid preparation of randomly mutated plasmid libraries, and will enable the wider adoption of random mutagenesis.     

Improved oligonucleotide site-directed mutagenesis using M13 vectors.

An improved method is described for the construction of mutations in M13 vectors using synthetic oligonucleotides. The DNA is first cloned into a novel M13 vector (based upon M13mp18 or M13mp19), which carries a genetic marker that can be selected against, such as an EcoK or EcoB site, or an amber mutation in an essential phage gene. In this "coupled priming" technique, one primer is used to construct the silent mutation of interest, and a second primer is used to eliminate the selectable marker on the minus strand. After primer extension and ligation, the heteroduplex DNA is transfected into a strain of E. coli which is repair deficient and selects against the plus strand marker. Over 50 mutants have been constructed with this approach, and the yields can be excellent (up to 70%). For the stepwise construction of mutations using separate rounds of mutagenesis, the EcoK and EcoB markers offer a particular advantage over the amber marker. They permit selection in each round, as it is possible to cycle between the two markers. However for construction of multiple mutations over a short region, long synthetic oligonucleotides with multiple mismatches to the template can offer an alternative strategy.     

Enhanced error-prone RCA mutagenesis by concatemer resolution

Error-prone rolling circle amplification (RCA) is a promising alternative to error-prone PCR for random mutagenesis. The main disadvantage of error-prone RCA is the low transformation efficiency of the DNA concatemer produced in the amplification reaction. We improved the method by introducing loxP recombination site of bacteriophage P1 Cre recombinase into the target plasmid and reducing the concatemer by Cre recombinase to plasmid-sized units, increasing the number of transformants 50-fold in non-error-prone and 13-fold in error-prone conditions. The efficiency improvement was verified by obtaining 115 ± 57 ceftazidime resistant colonies per recombined RCA reaction from randomly mutated TEM-1 β-lactamase gene library whereas only 9 ± 11 colonies were gained without recombination. Supplementation of the error-prone RCA with Cre/loxP recombination is a simple and useful tool to increase the transformable library size.     

Deletion mutagenesis in M13 by polymerase chain reaction using universal sequencing primers

A simple procedure is described for the efficient deletion of large DNA sequences. The method involves a combination of oligonucleotide-directed mutagenesis in bacteriophage M13 and amplification of the mutagenized product by polymerase chain reaction. In contrast to other protocols employing polymerase chain reaction, synthesis of only one specific primer is required. The efficiency of heteroduplex formation between mutagenic primers directing large deletions and single-stranded template is discussed.     

志贺菌福氏2a信号标签诱变突变体文库的构建

以合成的单链序列特异性标签为模板,通过PCR得到双链DNA标签并将其克隆到自杀质粒pUT-Tn5 Km2的转座子中,转化大肠杆菌S17-1λpir;然后用经转化的S17-1λpir与福氏志贺菌2a 2457T交配,挑出对氨苄青霉素敏感,对卡那霉素和萘啶酮酸抗性的菌落,结果表明构建了包含4376个福氏志贺菌突变体信号标签诱变库,为进一步鉴定该病原体的毒力基因打下了基础。     

A genetic enrichment for mutations constructed by oligodeoxynucleotide-directed mutagenesis

A genetic enrichment procedure for mutations constructed by oligodeoxynucleotide(oligo)-directed mutagenesis of DNA cloned in M13mp vectors is described. The procedure uses an M13 vector that contains the cloned target DNA and amber (am) mutations within the phage genes I and II. This vector cannot replicate in a suppressor-free (sup degrees) bacterial strain. A gapped heteroduplex is formed by annealing portions of a complementary (-)strand containing wild-type copies of genes I and II to the am-containing template (+)strand. The oligo is annealed to the single-stranded (ss) region and the remaining gaps and nicks are repaired enzymatically to form a closed circular heteroduplex structure. By transfecting the DNA into a sup degrees host we promote the propagation of heteroduplexes with the oligo-containing (-)strand since only this construction contains the wild-type copies of genes I and II. This procedure eliminates the need for any physical separation of the covalently closed circular DNA that contains the oligo from the ss template. Using this technique we have constructed 17 point mutations with mutation frequencies ranging from 2-20% for single base changes and from 0.3-9% for multiple base changes. In addition, we found that the mutation frequencies were affected by the state of DNA methylation in the (+) and (-)strands.     

A general method to select for M13 clones carrying base pair substitution mutants constructed in vitro.

In this paper we describe a method to select base pair substitution mutants constructed in vitro. The mutagenesis is performed by forcing mistakes during in vitro synthesis from a primer annealed to a single stranded DNA template. The selection is based on the fact that, following transformation, the progeny of the strand elongated in vitro and the template strand have different phenotypes. The method is general and applicable to any DNA segment; the type of base pair substitution and its position can be chosen at will. The combined efficiency of mutagenesis and selection allows for 85% frequency of mutants in all analyzed clones.     

Site-directed mutagenesis by complementary-strand synthesis using a closing oligonucleotide and double-stranded DNA templates

An approach for generating structures capable of directing full-length complementary-strand synthesis for double-stranded plasmid DNA is described. The structures are formed following heat denaturation and cooling of linearized plasmid DNA molecules in the presence of what is referred to as a "closing" oligonucleotide. Consisting of a sequence complementary to the free ends of one of the two plasmid strands, the closing oligonucleotide functions as an agent for recircularization of a DNA strand and generation of a primer-circular template structure suitable for polymerase-dependent full-length complementary-strand synthesis and ligation into a covalently closed heteroduplex molecule. When combined with a mutagenic oligonucleotide and uracil-substituted DNA templates, this approach allows site-directed mutagenesis to be performed directly on double-stranded DNA with a mutant formation efficiency of about 50%, a level amenable to rapid screening by DNA sequencing.     

Site-directed, Ligase-Independent Mutagenesis (SLIM): a single-tube methodology approaching 100% efficiency in 4 h

Site-directed, Ligase-Independent Mutagenesis (SLIM) is a novel PCR-mediated mutagenesis approach that can accommodate all three sequence modification types (insertion, deletion and substitution). The method utilizes an inverse PCR amplification of the template by two tailed long primers and two short primers in a single reaction with all steps carried out in one tube. The tailed primers are designed to contain the desired mutation on complementary overhangs at the terminus of PCR products. Upon post-amplification denaturation and re-annealing, heteroduplex formation between the mixed PCR products creates the desired clonable mutated plasmid. The technique is highly robust and suitable for applications in high-throughput gene engineering and library constructions. In this study, SLIM was employed to create sequence insertions, deletion and substitution within bacteriophage T7 gene 5. The overall efficiency for obtaining the desired product was >95%.     

TAMS technology for simple and efficient in vitro site-directed mutagenesis and mutant screening

Site-directed mutagenesis is an invaluable tool for functional studies and genetic engineering. However, most current protocols require the target DNA to be cloned into a plasmid vector before mutagenesis can be performed, and none of them are effective for multiple-site mutagenesis. We now describe a method that allows mutagenesis on any DNA template (eg. cDNA, genomic DNA and plasmid DNA), and is highly efficient for multiple-site mutagenesis (up to 100%). The technology takes advantage of the requirement that, in order for DNA polymerases to elongate, it is crucial that the 3′ sequences of the primers match the template perfectly. When two outer mutagenic oligos are incorporated together with the desired mutagenic oligos into the newly synthesised mutant strand, they serve as anchors for PCR primers which have 3′ sequences matching the mutated nucleotides, thus amplifying the mutant strand only. The same principle can also be used for mutant screening.     

Random mutagenesis and recombination of sam1 gene by integrating error-prone PCR with staggered extension process

An efficient method for creating a DNA library is presented in which gene mutagenesis and recombination can be introduced by integrating error-prone PCR with a staggered extension process in one test tube. In this process, less than 15 cycles of error-prone PCR are used to introduce random mutations. After precipitated and washed with ethanol solution, the error-prone PCR product is directly used both as template and primers in the following staggered extension process to introduce DNA recombination. The method was validated by using adenosyl-methionine (AdoMet) synthetase gene, sam1, as a model. The full-length target DNA fragment was available after a single round. After being selected with a competitive inhibitor, ethionine, a mutated gene was obtained that increased AdoMet accumulation in vivo by 56%.     

Simple and highly efficient site-specific mutagenesis, by ligation of an oligodeoxyribonucleotide into gapped heteroduplex DNA in which the template strand contains deoxyuridine

A simple and highly efficient procedure for oligodeoxynucleotide (oligo)-directed mutagenesis has been developed. In this procedure, a gapped heteroduplex DNA is first constructed and purified. The gapped heteroduplex consists of a circular 'template' strand of DNA, which contains some misincorporated deoxyuridine nucleotides, and a complementary strand which does not contain deoxyuridine, and which lacks a defined segment. Making a specific change in the sequence of the DNA within the gapped region then only requires ligation and transformation. An oligo, exactly the same length as the gap, and with the desired sequence, is synthesized, purified, and ligated directly into the gap in the heteroduplex. When this DNA is used to transform wt (ung+) Escherichia coli, about 80% of the resulting plasmids contain the sequence determined by the synthetic oligo. One gapped heteroduplex preparation can be used for many mutagenesis experiments, so that this procedure is well-suited for producing a series of defined mutations within a defined target region flanked by sites for restriction enzyme cleavage. As the method does not require a polymerase, the effects of primer displacement and polymerase infidelity are avoided.     

Formation of Template-Switching Artifacts by Linear Amplification

Linear amplification is a method of synthesizing single-stranded DNA from either a single-stranded DNA or one strand of a double-stranded DNA. In this protocol, molecules of a single primer DNA are extended by multiple rounds of DNA synthesis at high temperature using thermostable DNA polymerases. Although linear amplification generates the intended full-length single-stranded product, it is more efficient over single-stranded templates than double-stranded templates. We analyzed linear amplification over single- or double-stranded mouse H-ras DNA (exon 1–2 region). The single-stranded H-ras template yielded only the intended product. However, when the double-stranded template was used, additional artifact products were observed. Increasing the concentration of the double-stranded template produced relatively higher amounts of these artifact products. One of the artifact DNA bands could be mapped and analyzed by sequencing. It contained three template-switching products. These DNAs were formed by incomplete DNA strand extension over the template strand, followed by switching to the complementary strand at a specific Ade nucleotide within a putative hairpin sequence, from which DNA synthesis continued over the complementary strand.     

Analysis of single-stranded DNA stability and damage-induced strand loss in mammalian cells using SV40-based shuttle vectors

The fate and stability of fully or partially single-stranded DNA molecules transfected into mammalian cells have been analysed. For this, we constructed a simian virus 40 (SV40)-based shuttle vector containing the f1 bacteriophage replication origin in the two possible orientations (pi SVF1-A and pi SVF1-B). This vector contains the SV40 origin of replication, the late viral genes and DNA sequences for replication and selection in Escherichia coli. It also carries the lacO sequence, which permits the analysis of plasmid stability. Single-stranded DNA from pi SVF1-A and pi SVF1-B were produced in bacteria and annealed in vitro to form a heteroduplex molecule. We showed that, in monkey kidney COS7 cells, single-stranded vectors replicate to form duplex molecules. After transfection of the three forms of molecules (single-stranded, heteroduplex or double-stranded), replicated DNA was rescued in E. coli. Vector stability was analysed by checking for plasmid rearrangements and screening for lacO mutants. The single-stranded pi SVF1 has a lower rearrangement level, while the spontaneous mutation frequency (on the lacO target) is in the same range as for the double-stranded vector. In contrast, the level of spontaneous mutagenesis is higher for the heteroduplex than for the single- and double-stranded forms. In addition, we found that replication of heteroduplex with one strand containing ultraviolet light-induced lesions yields progeny molecules in which the irradiated strand is mostly lost. This result indicates for the first time the specific loss of the damaged strand in mammalian cells.     

Restriction enzyme-free construction of random gene mutagenesis libraries in Escherichia coli

Directed evolution relies on both random and site-directed mutagenesis of individual genes and regulatory elements to create variants with altered activity profiles for engineering applications. Central to these experiments is the construction of large libraries of related variants. However, a number of technical hurdles continue to limit routine construction of random mutagenesis libraries in Escherichia coli, in particular, inefficiencies during digestion and ligation steps. Here, we report a restriction enzyme-free approach to library generation using megaprimers termed MegAnneal. Target DNA is first exponentially amplified using error-prone polymerase chain reaction (PCR) and then linearly amplified with a single 3′ primer to generate long, randomly mutated, single-stranded megaprimers. These are annealed to single-stranded dUTP-containing template plasmid and extended with T7 polymerase to create a complementary strand, and the resulting termini are ligated with T4 DNA ligase. Using this approach, we are able to reliably generate libraries of approximately 10⁷ colony-forming units (cfu)/μg DNA/transformation in a single day. We have created MegAnneal libraries based on three different single-chain antibodies and identified variants with enhanced expression and ligand-binding affinity. The key advantages of this approach include facile amplification, restriction enzyme-free library generation, and a significantly reduced risk of mutations outside the targeted region and wild-type contamination as compared with current methods.     

A modified two primer approach to oligonucleotide-directed in vitro mutagenesis

Using oligonucleotide-directed mutagenesis, we are trying to define the features of the protein structure that are important for the DNA and c-AMP binding by CAP from E. coli, the enzymic activity and putative DNA binding of dihydrofolate reductase of L. casei, and the functionally important regions of the self-splicing RNA of the r-RNA intron of Tetrahymena thermophila. We have used a modification of the method described by Norris et al. [1]. A mutagenic primer and an M13 universal sequencing primer are annealed simultaneously to a template from an M13 clone containing the DNA to be mutagenised and, after DNA strand extension, the fragment is cut out and recloned into either M13 or plasmid vectors. We have analysed the effect on the frequency of mutation of: the temperature used for strand extension; the class of base change attempted; the host mismatch repair system. A recently developed system for phenotypic detection of mutations in the Tetrahymena intron aided in determining mutation frequencies.     

寡聚核苷酸诱导突变法改造φ×174噬菌体A基因蛋白的DNA识别序列

 为了进一步研究φX174噬菌体A基因蛋白的复制功能与其所识别的30核苷酸保守序列的关系,我们采用寡聚核苷酸诱导的定点突变法成功地改造了这30核苷酸保守序列。将此保守序列重组到M_(13)mp9噬菌体后,以其单链为模板,在14或16寡聚核苷酸的诱导下,合成共价闭环DNA。经转化到E.coli JM103菌株,用点印迹(Dot blot)杂交法筛选,得到两种重组突变株。一种突变株其30核苷酸保守序列正链的第22碱基由A改为G。另一突变株为其第10碱基A改为C,第11碱基T改为A。突变效率约为5％。制备了此突变株单链及双链DNA,分别做了双脱氧末端终止法及Maxam和Gilbert法序列分析鉴定。     

Efficient site directed in vitro mutagenesis using ampicillin selection.

A novel plasmid vector pSELECT-1 is described which can be used for highly efficient site-directed in vitro mutagenesis. The mutagenesis method is based on the use of single-stranded DNA and two primers, one mutagenic primer and a second correction primer which corrects a defect in the ampicillin resistance gene on the vector and reverts the vector to ampicillin resistance. Using T4 DNA polymerase and T4 DNA ligase the two primers are physically linked on the template. The non-mutant DNA strand is selected against by growth in the presence of ampicillin. In tests of the vector, highly efficient (60-90%) mutagenesis was obtained.