Site-directed mutagenesis of virtually any plasmid by eliminating a unique site.

We describe an efficient site-specific mutagenesis procedure that is effective with virtually any plasmid, requiring only that the target plasmid carry a unique, nonessential restriction site. The procedure employs two mutagenic oligonucleotide primers. One primer contains the desired mutation and the second contains a mutation in any unique, nonessential restriction site. The two primers are annealed to circular single-stranded DNA (produced by heating circular double-stranded DNA) and direct synthesis of a new second strand containing both primers. The resulting DNA is transformed into a mismatch repair defective (mut S) Escherichia coli strain, which increases the probability that the two mutations will cosegregate during the first round of DNA replication. Transformants are selected en masse in liquid medium containing an appropriate antibiotic and plasmid DNA is prepared, treated with the enzyme that recognizes the unique, nonessential restriction site, and retransformed into an appropriate host. Linearized parental molecules transform bacteria inefficiently. Plasmids with mutations in the unique restriction site are resistant to digestion, remain circular, and transform bacteria efficiently. By linking a selectable mutation in a unique restriction site to a nonselectable mutation, the latter can be recovered at frequencies of about 80%. Since most plasmids share common vector sequences, few primers, targeted to shared restriction sites, are needed for mutagenizing virtually any plasmid. The procedure employs simple procedures, common materials, and it can be performed in as little as 2 days.     

Artificial DNA splicing using directed ligation]

An approach to the directed genetic recombination in vitro has been devised, which allows for joining, in a predetermined chemical-enzymatic way, a series of DNA segments to give a precisely spliced polynucleotide sequence (DNA Splicing by Directed Ligation, SDL). The approach makes use of amplification, by several polymerase chain reactions (PCR), of the chosen DNA segments. The corresponding primers contain recognition sites of the class IIS restriction endonucleases, yielding protruding ends of unique primary structures. The protruding ends of the segments to be joined together are structurally predetermined to make them mutually complementary. Ligation of the mixture of the segments so synthesized gives the desired sequence in an unambiguous way. The suggested approach has been exemplified by the synthesis of a totally processed (intronless) gene encoding human mature interleukin-1 alpha.     

A reliable method for random mutagenesis: the generation of mutant libraries using spiked oligodeoxyribonucleotide primers

A new procedure for the production of a defined library of random mutants is described. Long spiked oligodeoxyribonucleotides (oligos), in which a predetermined level of the three 'wrong' phosphoramidites are used at each position, are made as primers for a standard oligo-directed mutagenesis protocol. Spiked oligo synthesis on a DNA synthesizer is achieved using an in-line mixing procedure that only requires five phosphoramidite reservoirs and which avoids contamination of any of the pure phosphoramidite reagents. Immutable positions (i.e., positions in the oligo for which pure reagents are used) can be specified, and a silent 'marker' base can be included that allows an early estimate of the mutagenesis efficiency. The randomness of the library in respect to the number, type, and position of the altered bases, is easily verified by DNA sequencing. This procedure has been used to generate a random mutant library of the gene encoding a sluggish triosephosphate isomerase. Among the transformants from this library, a number of second-site suppressor mutations have been found that increase the specific catalytic activity of the starting isomerase. This approach provides a more complete library than a method using chemical mutagenic reagents.     

Quantitative detection of single nucleotide polymorphisms for a pooled sample by a bioluminometric assay coupled with modified primer extension reactions (BAMPER)

A new method for SNP analysis based on the detection of pyrophosphate (PPi) is demonstrated, which is capable of detecting small allele frequency differences between two DNA pools for genetic association studies other than SNP typing. The method is based on specific primer extension reactions coupled with PPi detection. As the specificity of the primer-directed extension is not enough for quantitative SNP analysis, artificial mismatched bases are introduced into the 3′-terminal regions of the specific primers as a way of improving the switching characteristics of the primer extension reactions. The best position in the primer for such artificial mismatched bases is the third position from the primer 3′-terminus. Contamination with endogenous PPi, which produces a large background signal level in SNP analysis, was removed using PPase to degrade the PPi during the sample preparation process. It is possible to accurately and quantitatively analyze SNPs using a set of primers that correspond to the wild-type and mutant DNA segments. The termini of these primers are at the mutation positions. Various types of SNPs were successfully analyzed. It was possible to very accurately determine SNPs with frequencies as low 0.02. It is very reproducible and the allele frequency difference can be determined. It is accurate enough to detect meaningful genetic differences among pooled DNA samples. The method is sensitive enough to detect 14 amol ssM13 DNA. The proposed method seems very promising in terms of realizing a cost-effective, large-scale human genetic testing system.     

一种改进的快速PCR定点突变技术

在基因工程与蛋白质工程研究中常常用到基因突变技术制备突变体,用于研究基因调控、蛋白质的结构与功能。本项研究在快速PCR定点突变技术的基础上,改进实验方法,简化实验步骤,以适用蛋白质结构改造研究的需要。建立的突变技术仅需一次PCR反应即可完成基因的定点突变,突变效率为79.6%左右。该法对1～3个连续碱基的突变和对间隔4个甚至多达15个碱基的数个密码子突变效果都很好。     

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%.     

Gene splicing and mutagenesis by PCR-driven overlap extension

Extension of overlapping gene segments by PCR is a simple, versatile technique for site-directed mutagenesis and gene splicing. Initial PCRs generate overlapping gene segments that are then used as template DNA for another PCR to create a full-length product. Internal primers generate overlapping, complementary 3' ends on the intermediate segments and introduce nucleotide substitutions, insertions or deletions for site-directed mutagenesis, or for gene splicing, encode the nucleotides found at the junction of adjoining gene segments. Overlapping strands of these intermediate products hybridize at this 3' region in a subsequent PCR and are extended to generate the full-length product amplified by flanking primers that can include restriction enzyme sites for inserting the product into an expression vector for cloning purposes. The highly efficient generation of mutant or chimeric genes by this method can easily be accomplished with standard laboratory reagents in approximately 1 week.     

用DREAM技术纠正人工合成基因中的突变

目的：介绍一种简便、有效的定点突变技术。方法：根据突变位点附近的DNA序列推导出氨基酸序列,再以此氨基酸序列进行逆翻译,这样在不改变氨基酸序列的前提下可以得到数目巨大的隐性突变体（silent mutants）,这些突变体中包含大量的限制性内切酶位点,选择合适的酶切位点设计引物用PCR技术扩增两侧DNA片段,然后以相应酶切融合这两个片段即可完成定点突变。结果：用该方法成功地在人工合成的含有缺失的可溶性组织因子基因的472位插入C,T两个碱基,校正了阅读框架,获得了预期的目的基因。结论：该方法简便、有效, 避免了多轮PCR和合成长引物导致突变的可能性,这种改进的PCR 定点诱变技术我们称之为“设计限制酶辅助突变”（Designed Restriction Enzyme Assisted Mutagenesis, DREAM）。此技术简单方便, 诱变的成功率高, 适于实验室常规应用。     

Efficient and erroneous incorporation of oxidized DNA precursors by human DNA polymerase eta

Altered oxidative metabolism is a property of many tumor cells. Oxidation of DNA precursors, i.e., dNTP pool, as well as DNA is a major source of mutagenesis and carcinogenesis. Here, we report the remarkable nature of human DNA polymerase eta that incorporates oxidized dNTPs into a nascent DNA strand in an efficient and erroneous manner. The polymerase almost exclusively incorporated 8-hydroxy-dGTP (8-OH-dGTP) opposite template adenine (A) at 60% efficiency of normal dTTP incorporation, and incorporated 2-hydroxy-dATP (2-OH-dATP) opposite template thymine (T), guanine (G), or cytosine (C) at substantial rates. The synthetic primers having 8-hydroxy-G paired with template A or 2-hydroxy-A paired with template T, G, or C at the termini were efficiently extended. In contrast, human DNA polymerase iota incorporated 8-OH-dGTP opposite template A with much lower efficiency and did not incorporate 2-OH-dATP opposite any of the template bases. It did not extend the primers having the oxidized bases at the termini either. We propose that human DNA polymerase eta may participate in oxidative mutagenesis through the efficient and erroneous incorporation of oxidized dNTPs during DNA synthesis.     

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.     

一步法定点突变技术快速构建bsh基因突变启动子

目的：建立一种高效便捷的定点突变方法,为基因表达调控以及蛋白质结构和功能的研究提供技术支撑。方法：以构建单核细胞增生李斯特菌（Listeria monocytogenes）中编码胆碱水解酶（bile salt hydrolase,BSH）的bsh基因突变启动子为例,采用一对完全互补并带有突变位点的引物扩增携带bsh基因启动子的重组质粒DNA全序列,通过DpnⅠ消化PCR产物中剩余的甲基化的模板DNA,酶切后的PCR产物直接转化大肠杆菌,从而获得含有突变启动子的重组质粒。结果：通过一步法定点突变技术成功构建了bsh基因的三种突变启动子。结论：该方法简单高效,只要把握好对引物设计,高保真的DNA聚合酶、模板DNA的浓度以及PCR扩增程序的选择,突变成功率可以达到100%。     

Construction of a deletion library using a mixture of 5'-truncated primers for inverse PCR (IPCR).

A quick in vitro mutagenesis method for the construction of nested deletion libraries was developed. Many deletions can be obtained in a single inverse PCR (IPCR) by replacing one of the two primers with a mixture of 5'-truncated oligodeoxynucleotides. Since chemical DNA synthesis proceeds from the 3'to the 5'end, such a mixture of 5'-truncated oligodeoxynucleotides can easily be obtained in a single automated DNA synthesis under reduced coupling efficiency. This deletion mutagenesis method yields many different deletions in a defined short DNA segment and is, therefore, best suited for a deletion analysis at base pair level. Applications might include functional analysis of regulatory DNA segments and protein engineering work that requires libraries for the expression of N-terminal, C-terminal or internal truncated proteins as well as fusion proteins having different splice sites.     

Amplification of closed circular DNA in vitro.

The polymerase chain reaction is a powerful technique used to amplify nucleic acids in vitro . The reaction produces linear products, and as of yet, closed circular products have not been possible. Since the replicatively competent form of many DNA molecules is the closed circular form, it would be adventitious to amplify closed circular DNA as closed circular molecules. Until now, these molecules could only be amplified in vivo in appropriate host cells. Here, we describe an in vitro procedure, ligation-during-amplification (LDA), for selective amplification of closed circular DNA using sequence-specific primers. LDA is useful for site-directed mutagenesis, mutation detection, DNA modification, DNA library screening and circular DNA production.     

A rapid method for site-specific mutagenesis and directional subcloning by using the polymerase chain reaction to generate recombinant circles

Site-specific mutagenesis and directional subcloning were accomplished by using the polymerase chain reaction to generate products that can recombine to form circular DNA. This DNA was transfected into E. coli without phosphorylation of primers, restriction enzyme digestion or ligation. Specifically, the polymerase chain reaction was used to generate products that when combined, denatured and reannealed, form double-stranded DNA with discrete, cohesive single-stranded ends. The generation of these cohesive ends of DNA permits the formation of precise, directional DNA joints without dependence on enzyme restriction sites. The primers were designed such that these cohesive single-stranded ends annealed to form circular DNA. The recombinant of interest was generated following only 14 amplification cycles. These recombinant circles of DNA were directly transfected into E. coli. In the mutagenesis protocol, the desired mutant was obtained at 83%-100% efficiency. Unwanted mutations were not detected, indicating a less than 0.025% nucleotide misincorporation frequency. In the directional subcloning protocol, inserts were positioned precisely in the recipient plasmid and were in the correct orientation. One unwanted mutation was detected after sequencing 900 bases, indicating a 0.11% nucleotide misincorporation frequency. Each manipulation, from setting up for the DNA amplification to transfection into E. coli. can easily be accomplished in one day.     

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.     

SOS and UVM pathways have lesion-specific additive and competing effects on mutation fixation at replication-blocking DNA lesions

Escherichia coli cells have multiple mutagenic pathways that are induced in response to environmental and physiological stimuli. Unlike the well-investigated classical SOS response, little is known about newly recognized pathways such as the UVM (UV modulation of mutagenesis) response. In this study, we compared the contributions of the SOS and UVM pathways on mutation fixation at two representative noninstructive DNA lesions: 3,N4-ethenocytosine (epsilonC) and abasic (AP) sites. Because both SOS and UVM responses are induced by DNA damage, and defined UVM-defective E. coli strains are not yet available, we first constructed strains in which expression of the SOS mutagenesis proteins UmuD' and UmuC (and also RecA in some cases) is uncoupled from DNA damage by being placed under the control of a heterologous lac-derived promoter. M13 single-stranded viral DNA bearing site-specific lesions was transfected into cells induced for the SOS or UVM pathway. Survival effects were determined from transfection efficiency, and mutation fixation at the lesion was analyzed by a quantitative multiplex sequence analysis procedure. Our results suggest that induction of the SOS pathway can independently elevate mutagenesis at both lesions, whereas the UVM pathway significantly elevates mutagenesis at epsilonC in an SOS-independent fashion and at AP sites in an SOS-dependent fashion. Although mutagenesis at epsilonC appears to be elevated by the induction of either the SOS or the UVM pathway, the mutational specificity profiles for epsilonC under SOS and UVM pathways are distinct. Interestingly, when both pathways are active, the UVM effect appears to predominate over the SOS effect on mutagenesis at epsilonC, but the total mutation frequency is significantly increased over that observed when each pathway is individually induced. These observations suggest that the UVM response affects mutagenesis not only at class 2 noninstructive lesions (epsilonC) but also at classical SOS-dependent (class 1) lesions such as AP sites. Our results add new layers of complexity to inducible mutagenic phenomena: DNA damage activates multiple pathways that have lesion-specific additive as well as suppressive effects on mutation fixation, and some of these pathways are not directly regulated by the SOS genetic network.     

Degenerate oligonucleotide gene shuffling (DOGS): a method for enhancing the frequency of recombination with family shuffling.

Improvement of the biochemical characteristics of enzymes has been aided by misincorporation mutagenesis and DNA shuffling. Shuffling techniques can be used on a collection of mutants of the same gene, or related families of genes can be shuffled to produce mutants encoding chimeric gene products. One difficulty with current shuffling procedures is the predominance of unshuffled ("parental") molecules in the pool of mutants. We describe a procedure for gene shuffling using degenerate primers that allows control of the relative levels of recombination between the genes that are shuffled and reduces the regeneration of unshuffled parental genes. This procedure has the advantage of avoiding the use of endonucleases for gene fragmentation prior to shuffling and allows the use of random mutagenesis of selected segments of the gene as part of the procedure. We illustrate the use of the technique with a diverse family of beta-xylanase genes that possess widely different G+C contents.     

Multiple site-directed mutagenesis of more than 10 sites simultaneously and in a single round

Site-directed mutagenesis is a powerful tool to explore the structure-function relationship of proteins, but most traditional methods rely on the mutation of only one site at a time and efficiencies drop drastically when more than three sites are targeted simultaneously. Many applications in functional proteomics and genetic engineering, including codon optimization for heterologous expression, generation of cysteine-less proteins, and alanine-scanning mutagenesis, would greatly benefit from a multiple-site mutagenesis method with high efficiency. Here we describe the development of a simple and rapid method for site-directed mutagenesis of more than 10 sites simultaneously with up to 100% efficiency. The method uses two terminal tailed primers with a unique 25-nucleotide tail each that are simultaneously annealed to template DNA together with the set of mutagenic primers in between. Following synthesis of the mutant strand by primer extension and ligation with T4 DNA polymerase and ligase, the unique mutant strand-specific tails of the terminal primers are used as anchors to specifically amplify the mutant strand by high-fidelity polymerase chain reaction. We have employed this novel method to mutate simultaneously all 9 and 11 CUG leucine codons of the Hyg and Neo resistance genes, respectively, to the Candida albicans-friendly UUG leucine codon at 100% efficiency.     

APEX disease gene resequencing: mutations in exon 7 of the p53 tumor suppressor gene.

Detection of mutations in disease genes will be a significant application of genomic research. Methods for detecting mutations at the single nucleotide level are required in highly mutated genes such as the tumor suppressor p53. Resequencing of an individual patient's DNA by conventional Sanger methods is impractical, calling for novel methods for sequence analysis. Toward this end, an arrayed primer extension (APEX) method for identifying sequence alterations in primary DNA structure was developed. A two-dimensional array of immobilized primers (DNA chip) was fabricated to scan p53 exon 7 by single bases. Primers were immobilized with 200 microm spacing on a glass support. Oligonucleotide templates of length 72 were used to study individual APEX resequencing reactions. A template-dependent DNA polymerase extension was performed on the chip using fluorescein-labeled dideoxynucleotides (ddNTPs). Labeled primers were evanescently excited and the induced fluorescence was imaged by CCD. The average signal-to-noise ratio (S/N) observed was 30:1. Software was developed to analyze high-density DNA chips for sequence alterations. Deletion, insertion, and substitution mutations were detected. APEX can be used to scan for any mutation (up to two-base insertions) in a known region of DNA by fabricating a DNA chip comprising complementary primers addressing each nucleotide in the wild-type sequence. Since APEX is a parallel method for determining DNA sequence, the time required to assay a region is independent of its length. APEX has a high level of accuracy, is sequence-based, and can be miniaturized to analyze a large DNA region with minimal reagents.