Integration of PCR fragments at any specific site within cloning vectors without the use of restriction enzymes and DNA ligase

Here, we describe a method that offers a unique way to engineer plasmids with precision but without digestion using restriction enzymes for the insertion of DNA. The method allows the insertion of PCR fragments in between any two nucleotides within a target plasmid. The only requirement is that the amplified fragments must be embedded between DNA sequences homologous to the site in which the integration is planned. This method is an adaptation of the QuikChange Site-Directed Mutagenesis protocol. It is simpler than the existing cloning strategies and is suitable for multiparallel constructions of new plasmids. We have demonstrated its utility by constructing plasmids in which we have successfully integrated PCR fragments up to 1117 bp.     

In-fusion assembly: seamless engineering of multidomain fusion proteins, modular vectors, and mutations

In-Fusion can join any two pieces of DNA that have a 15-bp overlap at their ends. The result is equivalent to a recombination event at the ends of the DNAs. The 15-bp overlap may be engineered by inclusion in primers used to PCR amplify a segment of DNA. Originally described for inserting one piece of DNA into a restriction enzyme-digested plasmid, we have found In-Fusion can join four or more pieces of DNA in a single reaction. We used this insight to construct seamless fusion proteins, modular vectors with readily interchangeable segments, and novel mutagenesis strategies. Replacement In-Fusion can be used to delete any desired DNA segment in a plasmid and replace it with any desired new DNA segment without limitations on position or size.     

A novel method for producing partial restriction digestion of DNA fragments by PCR with 5-methyl-CTP.

Partial digestion of DNA fragments is a standard procedure for subcloning analysis and for generating restriction maps. We have developed a novel method to generate a partial digestion for any DNA fragment that can be amplified by PCR. The method involves the incorporation of 5-methyl-dCTP into the PCR product to protect most of the restriction sites. As a result, complete digestion of the modified PCR products with a 5-methyl-dCTP-sensitive enzyme will produce an array of restriction fragments equivalent to a partial restriction enzyme digestion reaction done on unmethylated PCR products. This method reduces the time and material needed to produce partially-digested DNA fragments by traditional methods. Furthermore, using fluorescein-labeled primers in the reaction, we were able to detect the fluorescein-labeled end fragments resulting from the enzyme digestion using a fluorimager or anti-fluorescein-AP antibody and thus determine the restriction maps.     

几种新型植物基因表达载体的构建方法

利用基因工程技术手段研究基因功能过程中,构建基因表达载体处于转基因植物的主导地位,采用合适的构建方法会使实验效果事半功倍。植物基因表达载体的构建方法除了传统构建法、Gateway技术、三段T-DNA法、一步克隆法等,还有近年来出现的几种新型的载体构建方法:基于竞争性连接原理快速构建小片段基因表达载体;MicroRNA前体PCR置换法适用于构建小分子RNA表达载体;重组融合PCR法特别适用于插入片段中含有较多限制性酶切位点的载体构建;利用In-Fusion试剂盒可以将任何目的片段插入一个线性化载体的某个区域;构建多片段复杂载体可采用不依赖序列和连接的克隆方法(Sequence and ligation-independent cloning,SLIC)法;Gibson等温拼接法;Golden Gate拼接法。本文将在总结分析前人工作的基础上,结合自己工作的体会和经验分析这7种新方法的特点,期望通过这几种新的方法给植物基因工程表达载体的构建提供新的思路。     

A convenient and robust method for construction of combinatorial and random mutant libraries

Here we describe a convenient and robust ligase-independent method for construction of combinatorial and random mutant libraries. The homologous genes flanked by plasmid-derived DNA sequences 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 flanking primers, followed by assembly of the chimeric genes and linearized vector by PCR to introduce recombinant plasmids of a combinatorial library. Commonly, it is difficult to find proper restriction sites during the construction of recombinant plasmids after DNA shuffling with multiple homologous genes. However, this disadvantage can be overcome by using the ligase-independent method because the steps of DNA digestion and ligation can be avoided during library construction. Similarly, DNA sequences with random mutations introduced by error-prone PCR can be used to construct recombinant plasmids of a random mutant library with this method. Additionally, this method can meet the needs of large and comprehensive DNA library construction.     

USER friendly DNA engineering and cloning method by uracil excision

Here we report a PCR-based DNA engineering technique for seamless assembly of recombinant molecules from multiple components. We create cloning vector and target molecules flanked with compatible single-stranded (ss) extensions. The vector contains a cassette with two inversely oriented nicking endonuclease sites separated by restriction endonuclease site(s). The spacer sequences between the nicking and restriction sites are tailored to create ss extensions of custom sequence. The vector is then linearized by digestion with nicking and restriction endonucleases. To generate target molecules, a single deoxyuridine (dU) residue is placed 6–10nt away from the 5′-end of each PCR primer. 5′ of dU the primer sequence is compatible either with an ss extension on the vector or with the ss extension of the next-in-line PCR product. After amplification, the dU is excised from the PCR products with the USER enzyme leaving PCR products flanked by 3′ ss extensions. When mixed together, the linearized vector and PCR products directionally assemble into a recombinant molecule through complementary ss extensions. By varying the design of the PCR primers, the protocol is easily adapted to perform one or more simultaneous DNA manipulations such as directional cloning, site-specific mutagenesis, sequence insertion or deletion and sequence assembly.     

Seamless gene engineering using RNA- and DNA-overhang cloning

Here we describe two methods for generating DNA fragments with single-stranded overhangs, like those generated by the activity of many restriction enzymes, by simple methods that do not involve DNA digestion. The methods, RNA-overhang cloning (ROC) and DNA-overhang cloning (DOC), generate polymerase chain reaction (PCR) products composed of double-stranded (ds) DNA flanked by single-stranded (ss) RNA or DNA overhangs. The overhangs can be used to recombine DNA fragments at any sequence location, creating "perfect" chimeric genes composed of DNA fragments that have been joined without the insertion, deletion, or alteration of even a single base pair. The ROC method entails using PCR primers that contain regions of RNA sequence that cannot be copied by certain thermostable DNA polymerases. Using such a chimeric primer in PCR would yield a product with a 5' overhang identical to the sequence of the RNA component of the primer, which can be used for directional ligation of the amplified product to other preselected DNA molecules. This method provides complete control over both the length and sequence of the overhangs, and eliminates the need for restriction enzymes as tools for gene engineering.     

Tn5cos: a transposon for restriction mapping of large plasmids using phage lambda terminase.

A method for the rapid restriction mapping of large plasmids has been developed. A 400-bp fragment of phage lambda DNA containing the cos region has been inserted into Tn5. After in vivo transposition of this Tn5cos element into the plasmid of choice, the plasmid is isolated and linearized at its cos site with phage lambda terminase (Ter). Such Ter linearization was about 70% efficient. After partial digestion of the linear molecules with the appropriate restriction enzyme, the products are selectively labelled at the right or left cohesive phage lambda DNA termini by hybridization with digoxygenin (DIG)-11-dUTP-labelled (using terminal transferase) oligodeoxyribonucleotides complementary to the single-stranded cos ends. After pulsed field gel electrophoresis, the labelled fragments are visualized in the dried gel using a DIG-detection kit. The restriction map can be directly determined from the 'ladder' of partial digestion products.     

Restriction enzyme site-directed amplification PCR: a tool to identify regions flanking a marker DNA

An innovative combination of various recently described molecular methods was set up to efficiently identify regions flanking a marker DNA in insertional mutants of Chlamydomonas. The technique is named restriction enzyme site-directed amplification PCR (RESDA-PCR) and is based on the random distribution of frequent restriction sites in a genome and on a special design of primers. The primer design is based on the presence of a restriction site included in a low degenerated sequence at the 3' end and of a specific adapter sequence at the 5' end, with the two ends being linked by a polyinosine bridge. Specific primers of the marker DNA combined with the degenerated primers allow amplification of DNA fragments adjacent to the marker insertion by using two rounds of either short or long cycling procedures. Amplified fragments from 0.3 to 2 kb or more are routinely obtained at sufficient purity and quantity for direct sequencing. This method is fast, is reliable (87% success rate), and can be easily extrapolated to any organism and marker DNA by designing the appropriate primers. A procedure involving the PCR over enzyme digest fragments is also proposed for when, exceptionally, positive results are not obtained.     

Molecular cloning of PCR fragments with cohesive ends

Use of the polymerase chain reaction (PCR) provides a convenient means of generating DNA fragments for insertion into plasmids. Large quantities of the desired insert, bounded by convenient restriction sites, may be synthesized. The primers are chosen to span a known region of interest, and extended at their 5′-ends to include the desired restriction sites. Amplification of the target sequence is followed by precipitation of the product with ammonium acetate and ethanol to remove the primers. A small amount of product is analyzed by gel electrophoresis to ensure correct amplification, the remainder is digested with the appropriate restriction enzyme(s). Restricted insert DNA is added to similarly restricted plasmid DNA in several ratios and incubated with DNA ligase to recircularize. Ligation products are used to transform competent bacteria. Clones containing inserts are identified by restriction digestion of plasmid minipreps from bacterial colonies.     

A general method to cleave a known DNA sequence at any site.

We describe a new method for obtaining DNA fragments starting at a desired point where there is no recognition sequence for any known restriction endonuclease. A single-stranded DNA containing the fragment of interest is annealed to a synthetic oligonucleotide hybridizing at the 5' end of the required fragment. Then, a partially double-stranded DNA is synthesized using the Klenow fragment of DNA polymerase I in the presence of the four deoxynucleoside triphosphates. The remaining single-stranded regions are removed by digestion with a single-strand nuclease, and the resulting 5' blunt-ended fragment is finally released by digestion with a restriction endonuclease at any site downstream its 3' end. The usefulness of the method was exemplified here by insertion of an epidermal growth factor-like African swine fever virus gene immediately downstream of the ribosome binding site of an expression vector.     

Parallel assembly for multiple site-directed mutagenesis of plasmids

A parallel assembly method for multiple site-directed mutagenesis of plasmids was developed here based on Golden Gate cloning. It takes advantage of type IIs restriction enzymes and T4 DNA ligase to assemble multiple DNA fragments into a plasmid by a defined order. This method can accommodate multiple plasmid mutagenesis at any desired position with all three sequence modification types (substitution, deletion, and insertion) simultaneously. Furthermore, it can be used to create otherwise difficult-to-make mutants-larger deletions and insertions and mutagenesis on larger plasmids. The processes of mutagenesis can be completed quickly by a single restriction-ligation reaction.     

Enzymatic inverse PCR: a restriction site independent, single-fragment method for high-efficiency, site-directed mutagenesis.

A new method is described for rapid site-directed mutagenesis of plasmid DNA. The new method, termed enzymatic inverse polymerase chain reaction (EIPCR), uses inverse PCR to amplify the entire plasmid. The key step to EIPCR is the incorporation of identical class 2s restriction sites in both primers. Class 2s restriction enzymes have a recognition site that is located 5' of the cut site (e.g., BsaI: GGTCTCN'NNNN,). Thus, after completing PCR, the ends of the full-length linearized plasmid are digested with the class 2s enzyme incorporated into the primers. The enzyme cuts off its entire recognition site and leaves the plasmid with compatible overhangs on both ends. Thus, in the ligation the only part that becomes part of the plasmid is the NNNN overhang, which can be made to be the native sequence. We have used the method for many plasmids and several class 2s enzymes. As an example, we report here the use of EIPCR for an insertion into pUC19 containing an inactive lacZ alpha-peptide, causing a frameshift that restores lacZ alpha-activity. Of 300 colonies evaluated, greater than 95% had the expected blue phenotype. The BsaI overhangs were correctly combined in all of the 35 blue colonies analyzed by restriction digestion and in all four clones that were sequenced. EIPCR is compared with four related PCR-based mutagenesis techniques. The major advantage of EIPCR over the other methods is the combination of greater than 95% correctly mutated clones with the need for only two PCR primers.     

Large scale purification of linear plasmid DNA for efficient high throughput cloning

In this report we describe a rapid, simple, and efficient method for large-scale purification of linear plasmid DNA to answer demand from high-throughput gene cloning. The process is based on the separation of the linear vector from small DNA fragments by anion exchange chromatography. Gene cloning experiments by restriction/ligation or the In-Fusion(tm) technique confirmed the high quality of the linearized vector as 100% of the genes were successfully cloned.     

Twin PCRs: a simple and efficient method for directional cloning of PCR products

A simple and efficient method was developed for directional cloning of PCR products without any restriction enzyme digestion of the amplified sequence. Two pairs of primers were designed in which parts of two restriction enzyme recognition sequences were integrated, and the primers were used for two parallel PCRs. The PCR products were mixed, heat denatured and re-annealed to generate hybridized DNA fragments bearing sticky ends compatible with restriction enzymes. This method is particularly useful when it is necessary to use a restriction enzyme but there is an additional internal restriction site within the amplified sequence, or when there are problems caused by end sensitivity of restriction enzymes.     

Rapid mapping of transposon insertion and deletion mutations in the large Ti-plasmids of Agrobacterium tumefaciens.

A procedure is presented, that has allowed the rapid assignment of transposon Tn1 and Tn7 insertion sites in the large (130 Md) nopaline Ti-plasmid pTiC58, to specific restriction enzyme fragments. Total bacterial DNA is isolated from Agrobacterium tumefaciens strain C58 mutants that carry a transposon in their Ti-plasmid, and digested with an appropriate restriction endonuclease. The fragments are separated on an agarose gel, denatured and transferred to nitrocellulose filters. These are hybridized against purified wild type pTiC58, or against segments of PTiC58, cloned in E. coli using pBR322 as a vector plasmid. DNA sequences homologous to the probe are detected by autoradiography, thus generating a restriction enzyme pattern of the plasmid from a digest of total bacterial DNA. Mutant fragments can be readily identified by their different position compared to a wild type reference. This protocol eliminates the need to separate the large plasmid from chromosomal DNA for every mutant. In principle, it can be applied to the restriction enzyme analysis of insertion or deletion mutants in any plasmid that has no extensive homology with the chromosome.     

A protocol for DNA fragment extraction from polyacrylamide gels

A simple and efficient method of purifying linear plasmid DNA from contaminating DNA fragments is described. Both vector and insert containing plasmids may be used without extensive purification, in particular without cesium chloride centrifugation. Careful deproteinization with phenol-chloroform allows efficient restriction enzyme digestion. Fragment separation can be performed immediately after restriction endonuclease digestion in a single 6% polyacrylamide gel. Extraction of DNA fragments from the gel is easy and gives a good yield. The DNA may be used for ligation and transformation without further purification.     

Simple,fast and high‐efficiency transformation system for directed evolution of cellulase in Bacillus subtilis

Bacillus subtilis can serve as a powerful platform for directed evolution, especially for secretory enzymes. However, cloning and transformation of a DNA mutant library in B. subtilis are not as easy as they are in Escherichia coli. For direct transformation of B. subtilis, here we developed a new protocol based on supercompetent cells prepared from the recombinant B. subtilis strain SCK6 and multimeric plasmids. This new protocol is simple (restriction enzyme‐, phosphatase‐ and ligase‐free), fast (i.e. 1 day) and of high efficiency (i.e. ～10⁷ or ～10⁴ transformants per µg of multimeric plasmid or ligated plasmid DNA respectively). Supercompetent B. subtilis SCK6 cells were prepared by overexpression of the competence master regulator ComK that was induced by adding xylose. The DNA mutant library was generated through a two‐round PCR: (i) the mutagenized DNA fragments were generated by error‐prone PCR and linearized plasmids were made using high‐fidelity PCR, and (ii) the multimeric plasmids were generated based on these two DNA templates by using overlap PCR. Both protein expression level and specific activity of glycoside hydrolase family 5 endoglucanse on regenerated amorphous cellulose were improved through this new system. To our limited knowledge, this study is the first report for enhancing secretory cellulase performance on insoluble cellulose.     

Efficient DNA subcloning through selective restriction endonuclease digestion

Described here is a selective restriction endonuclease digestion method that eliminates the electrophoresis step that is usually used during the subcloning of new DNA sequences into typical E. coli-based plasmids. The method increases yield while decreasing laboratory resource and time utilization. By using donor and acceptor sequences that contain unique restriction sites found only outside of the intended recombination sequences, the initial digestion products can be directly combined without electrophoresis if the ligation step is followed by a selective digestion using the unique restriction enzymes before transformation. This system is based on the several order of magnitude decrease in transformation efficiency of linearized compared to circular plasmids. As an example, this method was used to obtain recombinants between a 3.6 kb acceptor plasmid and 3.0 kb insert following one ligation reaction after the failure of nine standard reactions using similar amounts of input DNA. It is particularly applicable to situations in which low subcloning efficiencies are expected. The technique can be extended to a large percentage of planned recombinations by using nonidentical compatible cohesive or blunt-ended fragments, or site-directed mutagenesis.     

STRU-Cloning: A Fast,Inexpensive and Efficient Cloning Procedure Applicable to Both Small Scale and Structural Genomics Size Cloning

We have developed a Single-Tube Restriction-based Ultrafiltration (STRU) cloning procedure that updates traditional ligation-dependent cloning to challenge the newer, faster and more efficient ligation-free techniques and could make it the method of choice. STRU-cloning employs centrifugal filter units with membrane of suitable cut off to remove small unwanted DNA fragments created during restriction of plasmids or PCR products. Heat inactivation, of restriction enzymes, followed by DNA ligation is then performed on the filtrate. By removing the agarose gel electrophoresis DNA purification step from the traditional protocol, which is time consuming and is known to be the cause of ligation problems, STRU-cloning becomes fast, very efficient, inexpensive and offers the highest degree of cloning flexibility by using restriction sites and can be performed in a single tube. This novel agarose gel-free cloning procedure provides benefits for both small and large scale cloning projects. Unlike traditional cloning it can be easily implemented as a fully automated process at very low costs.