Directional cloning of native PCR products with preformed sticky ends (Autosticky PCR)

A novel method for the directional cloning of native PCR products was developed. Abasic sites in DNA templates make DNA polymerases stall at the site during synthesis of the complementary strand. Since the 5′ ends of PCR product strands contain built-in amplification primers, abasic sites within the primers result in the formation of 5′ single-stranded overhangs at the ends of the PCR product, enabling its direct ligation to a suitably cleaved cloning vector without any further modification. This “autosticky PCR” (AS-PCR) overcomes the problems caused by end sensitivity of restriction enzymes, or internal restriction sites within the amplified sequences, and enables the generation of essentially any desired 5′ overhang. Received: 11 August 1998 / Accepted: 2 October 1998     

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.     

Creating seamless junctions independent of restriction sites in PCR cloning

A method is described for the efficient cloning of any given DNA sequence into any desired location without the limitation of naturally occurring restriction sites. The technique employs the polymerase chain reaction (PCR) combined with the capacity of the type-IIS restriction endonuclease (ENase) Eam1104I to cut outside its recognition sequence. Primers that contain the Eam1104I recognition site (5′-CTCTTC) are used to amplify the DNA fragments being manipulated. Because the ENase is inhibited by site-specific methylation in the recognition sequence, all internal Eam1104I sites present in the DNA can be protected by performing the PCR amplification in the presence of 5-methyl-deoxycytosine (^m5dCTP). The primer-encoded Eam1104I sites are not affected by the modified nucleotides (nt) since the newly synthesized strand does not contain any cytosine residues in the recognition sequence. In addition, the ENase's ability to cleave several bases downstream from its recognition site allows the removal of superfluous, terminal sequences from the amplified DNA fragments, resulting in 5′ overhangs that are defined by the nt present within the cleavage site. Thus, the elimination of extraneous nt and the generation of unique, non-palindromic sticky ends permits the formation of seamless junctions in a directional fashion during the subsequent ligation event.     

Changes of 5＇ Terminal Nucleotides of PCR Primers Causing Variable T-A Cloning Efficiency

T-A cloning takes advantage of the unpaired adenosyl residue added to the 3＇ terminus of amplified DNAs by Taq and other thermostable DNA polymerase and uses a Ilnearlzed plasmld vector with a protruding 3＇ thymldylate residue at each of Its 3＇ termini to clone polymerase chain reaction （PCR）-derived DNA fragments. It Is a simple, reliable, and efficient Ilgatlon-dependent cloning method for PCR products, but the drawback of variable cloning efficiency occurs during application. In the present work, the relationship between variable T-A cloning efficiency and the different 5＇ end nucleotlde base of primers used In PCR amplification was studied. The results showed that different cloning efficiency was obtained with different primer pairs containing A, T, C and G at the 5＇ terminus respectively. The data shows that when the 5＇ end base of primer pair was adenosyl, more white colonies could be obtained In cloning the corresponding PCR product In comparison with other bases. And the least white colonies were formed when using the primer pair with 5＇ cytldylate end. The gluanylate end primers resulted In almost the same cloning efficiency In the white colonies amount as the thymldylate end primer did, and this efficiency was much lower than that of adenosyl end primers. This presumably is a consequence of variability In 3＇dA addition to PCR products mediated by Taq polymerase. Our results offer instructions for primer design for researchers who choose T-A cloning to clone PCR products.     

Cloning genomic sequences using long-range PCR

Protocols are presented for preparing DNA from a genomic library in λ phage and for synthesizing genomic fragments using PCR with nested vector- and gene-specific primers and linker-primers. Library DNA, isolated fromE. coli liquid lysates by a simple protocol, is used as template in PCR following a commercial protocol. The method produces library DNA sufficient for several hundred PCRs, incorporates nested primers to reduce nonspecific product formation, and enables the synthesis of linker-containing DNA fragments containing selected restriction sites to simplify subsequent cloning. The isolation of 5′ upstream sequences of three different arabidopsis genes by this methodod is described.     

Rapid amplification and cloning of Tn5 flanking fragments by inverse PCR

A simple approach is described to efficiently amplify DNA sequences flanking transposon Tn5 insertions. The method involves: (i) digestion with a restriction enzyme that cuts within Tn5; (ii) self-ligation under conditions favouring the production of monomeric circles; (iii) four parallel PCR reactions using primers designed to amplify left or right flanking sequences, and to distinguish target amplicons from non-specific products. This reveals the number of Tn5 insertions and the size of flanking genomic restriction fragments, without Southern blot analysis. The amplified product contains restriction sites that facilitate cohesive-end cloning. This rapid method is demonstrated using Tn5 and Tn5-Mob tagged DNA sequences involved in albicidin biosynthesis in Xanthomonas albilineans. It is generally applicable for efficient recovery of DNA sequences flanking transposon Tn5 derivatives in insertional mutagenesis studies.     

PCR fragmentation of DNA

A method has been developed to prepare random DNA fragments using PCR. First, two cycles are carried out at 16 degrees C with the Klenow's fragment and oligonucleotides (random primers) with random 3'-sequences and the 5'-constant part containing the site for cloning with the site-specific endonuclease. The random primers can link to any DNA site, and random DNA fragments are formed during DNA synthesis. During the second cycle, after denaturation of the DNA and addition of the Klenow's fragment, the random primers can link to newly synthesized DNA strands, and after DNA synthesis single-stranded DNA fragments are produced which have a constant primer sequence at the 5'-end and a complementary to it sequence at the 3'-end. During the third cycle, the constant primer is added and double-stranded fragments with the constant primer sequences at both ends are formed during DNA synthesis. Incubation for 1 h at 37 degrees C degrades the oligonucleotides used at the first stage due to endonuclease activity of the Klenow's fragment. Then routine PCR amplification is carried out using the constant primer. This method is more advantageous than hydrodynamic methods of DNA fragmentation widely used for "shotgun" cloning.     

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.     

Ligation-independent cloning of PCR products (LIC-PCR).

A new procedure has been developed for the efficient cloning of complex PCR mixtures, resulting in libraries exclusively consisting of recombinant clones. Recombinants are generated between PCR products and a PCR-amplified plasmid vector. The procedure does not require the use of restriction enzymes, T4 DNA ligase or alkaline phosphatase. The 5'-ends of the primers used to generate the cloneable PCR fragments contain an additional 12 nucleotide (nt) sequence lacking dCMP. As a result, the amplification products include 12-nt sequences lacking dGMP at their 3'-ends. The 3'-terminal sequence can be removed by the action of the (3'----5') exonuclease activity of T4 DNA polymerase in the presence of dGTP, leading to fragments with 5'-extending single-stranded (ss) tails of a defined sequence and length. Similarly, the entire plasmid vector is amplified with primers homologous to sequences in the multiple cloning site. The vector oligos have additional 12-nt tails complementary to the tails used for fragment amplification, permitting the creation of ss-ends with T4 DNA polymerase in the presence of dCTP. Circularization can occur between vector molecules and PCR fragments as mediated by the 12-nt cohesive ends, but not in mixtures lacking insert fragments. The resulting circular recombinant molecules do not require in vitro ligation for efficient bacterial transformation. We have applied the procedure for the cloning of inter-ALU fragments from hybrid cell-lines and human cosmid clones.     

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.     

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.     

Restriction site-free insertion of PCR products directionally into vectors

A restriction site-free cloning method has been developed for inserting a PCR product into a vector flexibly and precisely at any desired location with high efficiency. The method uses a pair of DNA integration primers with two portions. The 3' portion isolates the inserts by PCR, and the 5' portion integrates the PCR products into the homologous region of the vector. For mutagenesis, a third portion of mutation-generating sequences can be placed in between the 3' and 5' portions. This method has been used to clone the E. coli gene that codes for peptidyl-tRNA hydrolase, expressing it as a native protein and as a glutathione S-transferase fusion protein. It was also applied to convert a construct of the E. coli fatty acid biosynthesis protein with an N-terminal hexa-histidine tag into a construct with a C-terminal hexa-histidine tag.     

Direct Cloning and Sequencing of Bacterial Artificial Chromosome (BAC) Insert Ends Based on Double Digestion

Conventional digestion and ligation was developed into a novel and efficient approach for directly cloning and sequencing the two ends of bacterial artificial chromosome (BAC) clone inserts. Most BAC vectors have two Not I sites. This end isolation method is based on double digestion of the BAC clone DNA with Not I and any blunt-end restriction enzyme for which there is not a restriction site located within the small fragment (containing the cloning site) between the two Not I sites on the BAC vector. Digestion is followed by ligation of the double-digested mixture with a suitable plasmid vector. The pBeloBAC11 and pBlueScriptII SK vectors were used in the present study. The two ends of the BAC insert can be amplified and sequenced with three specific primers, i.e., amplification of the left end with the pBeloBAC11 LF1 and pBlueScriptII KS primers, and the right end with the pBeloBAC11 RR4 and KS primers. They may be directly recovered by transformation if the end fragments are used as probes. More significantly, this simple strategy generally can be applied to any BAC vector with any cloning site.     

Rapid amplification of genomic ends (RAGE) as a simple method to clone flanking genomic DNA

This report describes the amplification of upstream genomic sequences using the polymerase chain reaction (PCR) based solely on downstream DNA information from a cDNA clone. In this novel and rapid technique, genomic DNA (gDNA) is first incubated with a restriction enzyme that recognizes a site within the 5′ end of a gene, followed by denaturation and polyadenylation of its free 3′ ends with terminal transferase. The modified gDNA is then used as template for PCR using a gene-specific primer complementary to a sequence in the 3′ end of its cDNA and an anchored deoxyoligothymidine primer. A second round of PCR is then performed with a second, nested gene-specific primer and the anchor sequence primer. The resulting PCR product is cloned and its sequence determined. Three independent plant genomic clones were isolated using this method that exhibited complete sequence identity to their cDNAs and to the primers used in the amplification.     

Universal TA cloning

TA cloning is one of the simplest and most efficient methods for the cloning of PCR products. The procedure exploits the terminal transferase activity of certain thermophilic DNA polymerases, including Thermus aquaticus (Taq) polymerase. Taq polymerase has non-template dependent activity which preferentially adds a single adenosine to the 3'-ends of a double stranded DNA molecule, and thus most of the molecules PCR amplified by Taq polymerase possess single 3'-A overhangs. The use of a linearized "T-vector" which has single 3'-T overhangs on both ends allows direct, high-efficiency cloning of PCR products, facilitated by complementarity between the PCR product 3'-A overhangs and vector 3'-T overhangs. The TA cloning method can be easily modified so that the same T-vector can be used to clone any double-stranded DNA fragment, including PCR products amplified by any DNA polymerase, as well as all blunt- and sticky-ended DNA species. This technique is especially useful when compatible restriction sites are not available for the subcloning of DNA fragments from one vector to another. Directional cloning is made possible by appropriate hemi-phosphorylation of both the T-vectors and the inserts. With a single T-vector at hand, any DNA fragment can be cloned without compromising the cloning efficiency. The universal TA cloning method is thus both convenient and labor-saving.     

DNA cloning without restriction enzyme and ligase

One common problem in using the traditional DNA cloning procedure is that suitable natural restriction sites are often unavailable for a given task. Creating new restriction sites is often time consuming. Here, I describe a simple technique of producing "customized cohesive ends" by a combination of PCR primer design and lambda exonuclease digestion. These complementary cohesive ends can form hybrids to link two sequences. Because the overhangs created by lambda exonuclease are slightly longer than the complementary sequence, after hybrid formation, a stretch of single-strand gap remains, which then is repaired by Klenow (3'-->5' exo-) enzyme. The repair process also stabilizes the linkage. Because of the independence from natural or artificial restriction sites, this method allows rapid and precise insertion of one DNA fragment into another at virtually any position. It also simplifies the planning of a cloning strategy, increases recombinant frequency and is suitable for automation.     

Rapid Restriction Enzyme-Free Cloning of PCR Products: A High-Throughput Method Applicable for Library Construction

Herein, we describe a novel cloning strategy for PCR-amplified DNA which employs the type IIs restriction endonuclease BsaI to create a linearized vector with four base-long 5′-overhangs, and T4 DNA polymerase treatment of the insert in presence of a single dNTP to create vector-compatible four base-long overhangs. Notably, the insert preparation does not require any restriction enzyme treatment. The BsaI sites in the vector are oriented in such a manner that upon digestion with BsaI, a stuffer sequence along with both BsaI recognition sequences is removed. The sequence of the four base-long overhangs produced by BsaI cleavage were designed to be non-palindromic, non-compatible to each other. Therefore, only ligation of an insert carrying compatible ends allows directional cloning of the insert to the vector to generate a recombinant without recreating the BsaI sites. We also developed rapid protocols for insert preparation and cloning, by which the entire process from PCR to transformation can be completed in 6–8 h and DNA fragments ranging in size from 200 to 2200 bp can be cloned with equal efficiencies. One protocol uses a single tube for insert preparation if amplification is performed using polymerases with low 3′-exonuclease activity. The other protocol is compatible with any thermostable polymerase, including those with high 3′-exonuclease activity, and does not significantly increase the time required for cloning. The suitability of this method for high-throughput cloning was demonstrated by cloning batches of 24 PCR products with nearly 100% efficiency. The cloning strategy is also suitable for high efficiency cloning and was used to construct large libraries comprising more than 10⁸ clones/µg vector. Additionally, based on this strategy, a variety of vectors were constructed for the expression of proteins in E. coli, enabling large number of different clones to be rapidly generated.