Quikgene: a gene synthesis method integrated with ligation-free cloning

Gene synthesis is a convenient tool that is widely used to make genes for a variety of purposes. All current protocols essentially take inside-out approaches to assemble complete genes using DNA oligonucleotides or intermediate fragments. Here we present an efficient method that integrates gene synthesis and cloning into one step. Our method, which is evolved from QuikChange mutagenesis, can modify, extend, or even de novo synthesize relatively large genes. The genes are inserted directly into vectors without ligations or subcloning. We de novo synthesized a 600-bp gene through multiple steps of polymerase chain reaction (PCR) directly into a bacterial expression vector. This outside-in gene synthesis method is called Quikgene. Furthermore, we have defined an overlap region of a minimum of nine nucleotides in insertion primers that is sufficient enough to circularize PCR products for efficient transformation, allowing one to significantly reduce the lengths of primers. Taken together, our protocol greatly extends the current length limit for QuikChange insertion. More importantly, it combines gene synthesis and cloning into one step. It has potential applications for high-throughput structural genomics.     

A PCR-after-ligation method for cloning of multiple DNA inserts

Here we present a novel and simple PCR-after-ligation method for efficient assembly of multiple DNA inserts. After initial ligation of multiple inserts and vector, the ligation mixture is used as template for a PCR using a pair of primers flanking the cloning sites on the vector. The fragment with correct size is gel purified and inserted into the vector by conventional two-way ligation. With this method, a recombinant plasmid containing four DNA inserts was correctly constructed. As a control, all of the constructs obtained directly from DNA ligation were found to be self-ligation of the vector.     

RF cloning: a restriction-free method for inserting target genes into plasmids

Restriction-free (RF) cloning provides a simple, universal method to precisely insert a DNA fragment into any desired location within a circular plasmid, independent of restriction sites, ligation, or alterations in either the vector or the gene of interest. The technique uses a PCR fragment encoding a gene of interest as a pair of primers in a linear amplification reaction around a circular plasmid. In contrast to QuickChange site-directed mutagenesis, which introduces single mutations or small insertions/deletions, RF cloning inserts complete genes without the introduction of unwanted extra residues. The absence of any alterations to the protein as well as the simplicity of both the primer design and the procedure itself makes it suitable for high-throughput expression and ideal for structural genomics.     

QuikChange shuffling: a convenient and robust method for site-directed mutagenesis and random recombination of homologous genes

Here we describe a robust method, termed QuikChange shuffling, for efficient site-directed mutagenesis and random recombination of homologous genes. The homologous genes are fragmented, and the random fragments are reassembled in a self-priming polymerase reaction to obtain chimeric genes. The product is then mixed with linearized vector and two pairs of complementary mutagenic primers, followed by assembly of the chimeric genes and linearized vector through QuikChange-like amplification to introduce recombinant plasmids with a site-directed mutation. The method, which can yield 100% chimeric genes after library construction, is more convenient and efficient than current DNA shuffling methods.     

Efficient site-directed saturation mutagenesis using degenerate oligonucleotides.

We describe a reliable protocol for constructing single-site saturation mutagenesis libraries consisting of all 20 naturally occurring amino acids at a specific site within a protein. Such libraries are useful for structure-function studies and directed evolution. This protocol extends the utility of Stratagene's QuikChange Site-Directed Mutagenesis Kit, which is primarily recommended for single amino acid substitutions. Two complementary primers are synthesized, containing a degenerate mixture of the four bases at the three positions of the selected codon. These primers are added to starting plasmid template and thermal cycled to produce mutant DNA molecules, which are subsequently transformed into competent bacteria. The protocol does not require purification of mutagenic oligonucleotides or PCR products. This reduces both the cost and turnaround time in high-throughput directed evolution applications. We have utilized this protocol to generate over 200 site-saturation libraries in a DNA polymerase, with a success rate of greater than 95%.     

Vector PCR.

A strategy employing PCR technology to facilitate the amplification of DNA segments inserted in plasmid vectors is described. Nine oligonucleotide primers specific for vector sequences bracketing cloning sites in seven commonly used vectors were designed. We used these primers for the amplification of 25 different inserts ranging in size from 0.4-4.8 kb. Vector PCR-generated products used as radiolabeled DNA probes in Southern hybridization compared favorably with conventionally prepared probes. This strategy was successfully applied to single colonies of bacteria containing recombinant plasmids for direct amplification of the plasmids insert from the bacterial lysate. Vector PCR enabled the production of microgram quantities of DNA from limited amounts of starting material without the time-consuming steps required for bacterial culture and purification of plasmid DNA. The amplification reaction is independent of the DNA segment to be amplified, rendering the method universally applicable.     

A simple,rapid, efficient and inexpensive strategy for sequencing clones from cDNA libraries

In this report, we describe a simple, rapid, efficient and inexpensive strategy for sequencing inserted DNAs from clones of cDNA or gDNA libraries. This strategy uses PCR products directly amplified from transformed bacterial colonies, with universal primers within the vector. The method can be applied for sequencing cDNA or gDNA libraries with up to 4 ∼ 5 kb insert sizes, without overnight liquid culture or plasmid DNA preparation steps. We successfully used this method to analyze clones from full-length, enriched cDNA libraries. Although simple, following this strategy will significantly help researchers to avoid unnecessary steps in the analysis of a cDNA library.     

用改进的重叠延伸PCR技术构建三位点突变载体

目的:改进传统重叠延伸PCR方法,实现引入3个不同DNA突变位点的简便的多位点定点突变。方法:根据前期构建的包含人线粒体12S rRNA(NC 01290)3个热点突变位点的野生型质粒序列,利用Muta Primer 2.0软件设计针对3个热点突变位点的3对互补的定点突变引物,以野生型质粒为模板,结合重叠延伸PCR反应和冷冻析出法,产生同时包含3个突变位点的突变目的片段,酶切后克隆到载体中,测序确证是否突变成功。结果:DNA测序证实3个不同突变位点同时成功引入,定点突变载体构建成功。结论:用改进的重叠延伸PCR技术能简便、高效地获得多位点定点突变载体,在分子生物学领域有较高的使用价值。     

Creating randomized amino acid libraries with the QuikChange Multi Site-Directed Mutagenesis Kit

The QuikChange Multi Site-Directed Mutagenesis Kit is a simple and efficient method for introducing point mutations at up to five sites simultaneously in plasmid DNA templates. Here we used the QuikChange Multi kit with degenerate (one codon) primers to introduce all possible amino acids at selected sites in the lacZ gene. In reactions employing two or three degenerate primers, diverse libraries (10(4)-10(5) mutants/reaction) are created consisting of random combinations of mutations at two or three different sites. This method provides a one-day procedure for performing site-directed saturation mutagenesis and, when coupled with a suitable screening assay, should greatly facilitate the process of evaluating alternative amino acid chain substitutions at key residues and evolving protein function.     

A PCR-based method for isolation of genomic DNA flanking a known DNA sequence

We describe a simple PCR-based method for the isolation of genomic DNA that lies adjacent to a known DNA sequence. The method is based on the directional cloning of digested genomic DNA into the multiple cloning site of a pUC-based plasmid to generate a limited genomic library. The library is plated onto a number of selective LA plates which are incubated overnight, and recombinant plasmid DNA is then isolated from resistant colonies pooled from each plate. PCR amplification is performed on the pooled recombinant plasmid DNAs using primers specific for the pUC vector and the known genomic sequence. The combination of efficient directional cloning and bacterial transformation gives relative enrichment for the genomic sequence of interest and generates a simple DNA template, enabling easy amplification by PCR.     

Direct cloning of cDNA inserts from lambda gt11 phage DNA into a plasmid vector by a novel and simple method

Bacteriophage lambda gt11 has been used quite extensively for producing cDNA libraries. The cDNA inserts are usually subcloned into a plasmid vector for large scale production and analysis. However, isolating the recombinant DNA of interest from the phage clones can be a tedious task. Since the E. coli strain Y1088 used for lambda gt11 phage infection carries a pBR322-derived plasmid endogenously, we reasoned that this endogenous plasmid could be used directly for cloning the cDNA phage insert. In this report, we describe a method in which cDNA inserts from lambda gt11 phage were cloned directly into the pBR322 plasmid vector, bypassing the time-consuming procedures of preparing plasmid DNA as a subcloning vector. This method is likely to be extended to the cloning of DNA inserts derived from other phage lambda vectors when bacteria containing endogenous pBR322 are used as host cells.     

Transfer of P1 inserts into a yeast-bacteria shuttle vector by co-transformation mediated homologous recombination.

Manipulation of genomic inserts cloned into the bacteriophage P1 vector is hindered by the large size of the inserts. We have used co-transformation mediated recombination between the yeast-bacteria shuttle vector, pClasper, and various P1 clones to transfer the entire insert from the P1 into pClasper. This results in the insert being stably maintained in yeast, facilitating mutagenesis by homologous recombination. The recombinant plasmid can subsequently be transferred to and stably maintained in bacteria for efficient plasmid preparation. This method can also be applied to inserts from P1 artificial chromosome or bacterial artificial chromosome vectors.     

Direct cloning of cDNA inserts from λgt11 phage DNA into a plasmid vector by a novel and simple method

Bacteriophage λgt11 has been used quite extensively for producing cDNA libraries. The cDNA inserts are usually subcloned into a plasmid vector for large scale production and analysis. However, isolating the recombinant DNA of interest from the phage clones can be a tedious task. Since the E. coli strain Y1088 used for λgt11 phage infection carries a pBR322-derived plasmid endogenously, we reasoned that this endogenous plasmid could be used directly for cloning the cDNA phage insert. In this report, we describe a method in which cDNA inserts from λgt11 phage were cloned directly into the pBR322 plasmid vector, by-passing the time-consuming procedures of preparing plasmid DNA as a subcloning vector. This method is likely to be extended to the cloning of DNA inserts derived from other phage λ vectors when bacteria containing endogenous pBR322 are used as host cells.     

A rapid, simple, and effective method of constructing a randomly mutagenized plasmid library free from ligation

The QuikChange site-directed mutagenesis methodology was applied to constructing a randomly mutagenized plasmid library simply by adding manganese to the reaction mixture. This method is superior to the normally employed Pol I-type polymerase-based error-prone PCR in that (i) it does not require a subsequent ligation reaction, and (ii) there is no accumulation of mutations at the same site. alpha-Complementation analysis and subsequent sequence analyses of the lacZ alpha genes in the mutated library revealed that the mutations occurred randomly within the target gene and involved all possible base substitutions.     

基于PCR的质粒快速定点诱变方法建立与评价

基因突变对生命的进化具有重要意义,针对质粒的DNA定点诱变技术也是基因工程、蛋白质工程研究中的重要手段之一。为了提高质粒定点诱变的效率,本研究利用引物部分重叠的设计方案,使用Tm值相对固定的引物设计模式,将同一引物分为重叠区（Tm=50±2℃）和非重叠区（Tm=60±2℃）,并在严格控制模板用量（2 pg/kb）的基础上,通过20个PCR循环对目标质粒进行定点诱变扩增,随后取0.5 μL产物直接用于转化。在FastPfu Fly酶系中,利用此法构建了6个含碱基替换、缺失和插入的质粒,均获得成功,突变效率可达96%以上,阳性克隆获得数达70个以上。此外,利用4种不同PCR酶系对该法的适用性进行了评价,结果表明突变效率均可达93%以上,阳性克隆获得数均在10个以上。通过适当增加PCR模板用量（10 pg/kb）并使用纯化后的PCR产物进行转化,该法可适用于转化效率大于106（cfu/μg）的任意感受态细胞,对应的突变效率可大于91%,阳性克隆获得数大于20。根据本法的作用原理,该方案适合质粒中10～20 bp（因重叠区GC含量及碱基序列的不同而改变）以内的任意碱基替换和插入,以及任意长度的DNA片段缺失。且具有通用性强、耗时少、诱变成功率高、成本低、对感受态及转化效率无特殊要求等优点,适合各实验室的日常研究使用。     

Directed evolution of green fluorescent protein by a new versatile PCR strategy for site-directed and semi-random mutagenesis

To develop a simple, speedy, economical and widely applicable method for multiple-site mutagenesis, we have substantially modified the Quik-Change™ Site-Directed Mutagenesis Kit protocol (Stratagene, La Jolla, CA). Our new protocol consists of (i) a PCR reaction using an in vitro technique, LDA (ligation-during-amplification), (ii) a DpnI treatment to digest parental DNA and to make megaprimers and (iii) a synthesis of double-stranded plasmid DNA for bacterial transformation. While the Quik Change™ Kit protocol introduces mutations at a single site, requiring two complementary mutagenic oligonucleotides, our new protocol requires only one mutagenic oligonucleotide for a mutation site, and can introduce mutations in a plasmid at multiple sites simultaneously. A targeting efficiency >70% was consistently achieved for multiple-site mutagenesis. Furthermore, the new protocol allows random mutagenesis with degenerative primers, because it does not use two complementary primers. Our mutagenesis strategy was successfully used to alter the fluorescence properties of green fluorescent protein (GFP), creating a new-color GFP mutant, cyan-green fluorescent protein (CGFP). An eminent feature of CGFP is its remarkable stability in a wide pH range (pH 4–12). The use of CGFP would allow us to monitor protein localization quantitatively in acidic organelles in secretory pathways.     

A recombination based method to rapidly assess specificity of two-hybrid clones in yeast.

The yeast two-hybrid system is frequently used to identify protein-protein interactions. Confirming the specificity of candidate clones requires separation and isolation of yeast plasmids, propagation in bacteria and testing combinations of DNA-binding and activation domain hybrids in yeast. In order to simplify this procedure, we developed a rapid method based on PCR amplification of library insert DNAs and in vivo cloning into the activation domain hybrid vector. Reporter gene activity is assayed in parallel for combinations with different DNA-binding domain hybrids. Further characterization of inserts does not require plasmid isolation and intermediate hosts.     

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.     

Rapid and efficient cosmid cloning

We present a procedure for cosmid cloning that allows rapid and efficient cloning of individual DNA fragments of between 32kb and 45kb. By appropriate treatment of the cloning vector, pJb8, we make left-hand and right-hand vector ends that are incapable of self-ligation but which accept dephosporylated insert DNA fragments. The inserted fragments are generated by partial digestion with MboI or Sau3A and are dephosphorylated to prevent ligation and insertion of non-contiguous fragments. The method eliminates the need to size the insert DNA fragments and prevents formation of clones containing short or multiple inserts. 1 microgram of target Drosophila DNA gives about 5 x 10(5) clones, with an average insert size of 38kb. We also describe a rapid and efficient method for preparing plasmid and cosmid DNA.     

A PCR-based method for high stringency screening of DNA libraries.

A rapid method for cloning genomic DNA utilizing a PCR-based screening protocol is described. A murine genomic library in lambda phage was subdivided into 64 wells, each containing 1000 clones, and propagated in bacteria. Amplified phage from each of 8 wells across columns, and each of 8 wells down rows, were pooled. The pooled phage were screened for the presence of murine M-CSF DNA by PCR using specific oligonucleotide primers. A single well that contained an M-CSF genomic clone was identified by the synthesis of a PCR product of the correct size that hybridized to an internal M-CSF oligonucleotide probe. This well was subdivided into 64 wells, each containing approximately 30 individual phage, reamplified, and rescreened utilizing the same protocol. A positive well was then subdivided and amplified a third time starting with an average of 2 phage per well, and rescreened for M-CSF DNA by PCR. Phage from a PCR-positive well, now highly enriched for M-CSF DNA, were grown as individual plaques. PCR-screening of randomly picked plaques demonstrated that the majority contained an M-CSF genomic insert. This method obviates the more labor and time intensive method of plaque hybridization screening of DNA libraries, and is more stringent since three oligonucleotides (the two PCR primers, and the hybridization probe) are required to give a true positive signal. Similar methodology has also been used to clone a cDNA gene contained within a plasmid library.