Reliable fusion PCR using Taq polymerases and pGEM-T easy vectors

We describe a reliable method for the production of fusion PCR products that can be used to transform the wild-type bacteria to replace target genes for mutagenesis studies. The relevant gene fragments and selective cassette are first amplified separately by PCR using primers that produce overlapping ends. As economic Taq DNA polymerase is disappointed in producing overlap ends due to adding an extra 3′-end ‘A’ base which potentially blocks the successful fusion of the amplified fragments, we use a new primer design strategy to overcome this disadvantage by introducing an additional ‘A’ base in the overlap primers. The amplified gene fragments were then separately cloned into a pGEM-T easy vector and re-amplified with the aid of a universal primer T7/SP6. This procedure enables performing nested PCR with the outmost primers in the fusion reaction to reliably splice the gene fragments into a single molecule with all sequences in the desired order.     

Gene splicing by overlap extension: tailor-made genes using the polymerase chain reaction

Gene Splicing by Overlap Extension or "gene SOEing" is a PCR-based method of recombining DNA sequences without reliance on restriction sites and of directly generating mutated DNA fragments in vitro. By modifying the sequences incorporated into the 5'-ends of the primers, any pair of polymerase chain reaction products can be made to share a common sequence at one end. Under polymerase chain reaction conditions, the common sequence allows strands from two different fragments to hybridize to one another, forming an overlap. Extension of this overlap by DNA polymerase yields a recombinant molecule. This powerful and technically simple approach offers many advantages over conventional approaches for manipulating gene sequences.     

PCR- and ligation-mediated synthesis of marker cassettes with long flanking homology regions for gene disruption in Saccharomyces cerevisiae.

We developed a novel method for synthesizing marker-disrupted alleles of yeast genes. The first step is PCR amplification of two sequences located upstream and downstream of the reading frame to be disrupted. Due to the addition of non-specific single A overhangs by Taq DNA polymerase, each PCR product can be ligated with a marker DNA which has T residues at its 3' ends. After amplification of individual ligation products through the second PCR, both products are mixed and annealed, and the single strand is converted to a double strand by an extension reaction. The final step is PCR amplification of the fragment composed of a selectable marker and two flanking sequences with the outermost primers. This method is rapid and needs only short oligonucleotides as primers.     

Ligase-free subcloning: a versatile method to subclone polymerase chain reaction (PCR) products in a single day.

Often, it is convenient to subclone polymerase chain reaction (PCR) products into a plasmid vector for subsequent replication in bacteria, but conventional subcloning methods often fail. We report a rapid and versatile method to subclone PCR products directionally into a specific site of virtually any plasmid vector. The procedure requires only four primers, does not require DNA ligase, and may be accomplished in a single day. Ligase-free subcloning is performed by incorporating into the PCR primers sequences at the 5' ends that result in PCR products whose 3' ends are complementary to the 3' ends of the recipient linearized plasmid. The PCR product and the linearized plasmid are spliced together in a second PCR reaction in which Taq polymerase extends the complementary overlapping 3' ends (ligation by overlap extension). Denaturation followed by heterologous reannealing and cyclization results in a cyclic recombinant plasmid with two nicks that may be used directly to transform competent Escherichia coli. In our hands, ligase-free subcloning is rapid, and offers many advantages over existing strategies.     

Rapid isolation of flanking genomic DNA using biotin-RAGE, a variation of single-sided polymerase chain reaction.

A method is described for quickly and reproducibly isolating genomic DNA contiguous with known DNA sequence by means of the polymerase chain reaction (PCR). Flanking genomic DNA is isolated using a biotinylated sequence-specific primer in combination with a generic hybrid primer that binds to a deoxyoligonucleotide sequence artificially added to the ends of the genomic DNA. Amplified sequences that include the biotinylated primer are purified from nonbiotinylated amplification products by binding to a solid-phase streptavidin matrix. The biotinylated amplification product(s) are subjected to a further round of amplification, after which they can be subcloned and analyzed. This technique was applied to the isolation of three intron-exon junctions. Verification of the identify of these junction sequences was accomplished by designing primers based on the intron sequences isolated by Biotin-RAGE, amplifying across the exon using these intron primers, and sequencing the PCR-generated product.     

A polymerase chain reaction mediated by a single primer: cloning of genomic sequences adjacent to a serotonin receptor protein coding region.

Under appropriate conditions, specific double-stranded DNA product was generated after amplification of genomic DNA sequences in a polymerase chain-like reaction that contained only a single primer. This type of amplification reaction was performed with a variety of primers and substrate DNAs. In addition to nonspecific heterogeneous products, 5 of 11 primers reproducibly directed synthesis of double-stranded DNA that corresponded to the region of the template that contained the authentic primer annealing site. Three of these amplified products were cloned and their ends were sequenced. All three contained a copy of the primer at both 5' ends, and the position of one of the primers represented the authentic primer binding site. In each case, the location of the second copy of the primer indicated that it had initially hybridized to a partially homologous sequence in the template DNA. This single primer reaction makes it possible to amplify and clone a DNA region of unknown sequence that is adjacent to a known DNA sequence. One of the single primer reaction products described here included sequence to the 5' side of the coding region of a serotonin receptor gene that contained a functional promoter.     

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.     

Construction of cDNA libraries for highly efficient DNA sequencing from the 3' end of expressed genes

The majority of expressed sequence tag (EST) sequences available today have been derived from the 5' ends of cDNA clones. Obtaining high-quality DNA sequences from the 3' ends of oligo(dT)-primed cDNA on a large scale has been difficult because of slippage of the DNA polymerase enzyme used in direct PCR and cycle sequencing. With the completion of whole genome sequencing for more and more organisms, mRNA 3'-UTR sequences can be particularly useful for clustering large numbers of ESTs for the effective discrimination of individual genes and gene families. We have identified a flaw in the widely used oligo(dT) primers for cDNA synthesis, and here we describe an improved priming approach to effectively synthesize cDNA devoid of homopolymeric nucleotide stretches from mRNA poly(A) tails to enable highly efficient and reliable DNA sequence determination from 3' mRNA ends. Using this method, we produced a rat lung cDNA library and successfully sequenced the 3' ends of 98% of all attempted clones.     

Rapid gene splicing and multi-sited mutagenesis by one-step overlap extension polymerase chain reaction

Gene splicing and site-directed mutagenesis (SDM) are important to introduce desired sequences in target DNA. However, introducing mutations at multiple sites requires multiple steps of DNA manipulation, which is time-consuming and labor-intensive. Here, we present a rapid efficient gene splicing and multi-sited mutagenesis method that introduces mutations at two distant sites via sequential connection of DNA fragments by one-step overlap extension polymerase chain reaction (OE-PCR). This bottom-up approach for DNA engineering can be broadly used to study protein structure-function, to optimize codon use for protein expression, and to assemble genes of interest.     

A novel method for generating a nested set of unidirectional deletion mutants using mixed oligodeoxynucleotides

A novel method that allows introduction of unidirectional deletions into cloned DNA is described. This method is based on the use of a mixture of oligodeoxynucleotide primers that have fixed 5' ends defining the end point of the deletion and variable 3' ends composed of mixtures of all four nucleotides at six positions. The 5' ends of the oligodeoxynucleotides are hybridized to a fixed location of the M13K11RX templates and the 3' ends are hybridized randomly to the DNA to be analyzed. Such oligodeoxynucleotide primers when extended with DNA polymerase can direct deletions of intervening parts of the single-stranded DNA that by design contains multiple EcoK sites; the deletion products are selected on a host strain with the EcoK restriction system (e.g., using JM101 cells). This method is an efficient way of generating a nested set of deletion mutants useful for dideoxy-sequencing. It can be used for creating a set of deletion mutants with a particular codon at the 5' or 3' end point.     

Chemiluminescence detection of telomere DNA in human cells on a membrane by using fluorescein-5-isothiocyanate-labeled primers

Telomere DNA is related to cell aging and cancer genesis because the telomeric region of DNA sequences at chromosome ends are shortened with cell divisions. Therefore, a sensitive and specific detection method is required for the telomere DNA. Here we propose a chemiluminescence (CL)-based method for the sensitive detection of telomere DNA in human cells. In this study, the telomere DNA was amplified by polymerase chain reaction (PCR) using special forward and reverse primers labeled with fluorescein-5-isothiocyanate (FITC) at the 5′ end, and then the FITC-containing PCR products were detected by CL reaction with 3,4,5-trimethoxyphenylglyoxal (TMPG) after electrophoresis followed by Southern blot onto a nylon membrane. The TMPG reagent specifically reacted with guanine moiety in DNA at room temperature and provided CL intensities. The CL intensities from the PCR products could be enhanced approximately 10-fold using FITC-labeled primers as compared with those using nonlabeled primers. The detection limit of the PCR products with the proposed method was 0.3 ng on the membrane. The developed CL method could quantitatively determine the telomere DNA in a small number of human cells (∼350) and gave approximately 10 times higher sensitivity than a conventional fluorescence-based method.     

DNA splicing by directed ligation (SDL)

Splicing by directed ligation (SDL) is a method of in-phase joining of PCR-generated DNA fragments that is based on a pre-designed combination of class IIS restriction endonuclease recognition and cleavage sites. Since these enzymes cleave outside of their recognition sites, the resulting sticky end can have any desired sequence, and the site itself can be removed and does not appear in the final spliced DNA product. SDL is based on the addition of class IIS recognition sites onto primers used to amplify DNA sequences. Cleavage of the PCR products results in elimination of the recognition site-containing flanking sequences and leaves the DNA fragments crowned with protruding ends. With careful design of the sticky ends, several segments can be ligated together in a predetermined order in a single reaction. SDL requires fewer rounds of amplification than overlap extension methods, and is particularly useful for creating a series of recombinants that differ in one segment.     

Uracil DNA glycosylase-mediated cloning of polymerase chain reaction-amplified DNA: application to genomic and cDNA cloning.

A simple and rapid method for cloning of amplification products directly from the polymerase chain reaction (PCR) has been developed. The method is based on the addition of a 12-base dUMP-containing sequence (CUACUACUACUA) to the 5' end of PCR primers. Incorporation of these primers during PCR results in the selective placement of dUMP residues into the 5' end of amplification products. Selective degradation of the dUMP residues in the PCR products with uracil DNA glycosylase (UDG) disrupts base pairing at the termini and generates 3' overhangs. Annealing of 3' protruding termini to vector DNA containing complementary 3' ends results in chimeric molecules which can be transformed, with high efficiency, without in vitro ligation. Directional cloning of PCR products has also been accomplished by incorporating different dU-containing sequences at the end of each PCR primer. Substitution of all dT residues in PCR primers with dU eliminates cloning of aberrant "primer dimer" products and enriches cloning of genuine PCR products. The method has been applied to cloning of inter-Alu DNA sequences from human placental DNA. Using a single primer, DNA sequences between appropriately oriented Alu sequences were amplified and cloned. Cloning of cDNA for the glyceraldehyde-3'-phosphate dehydrogenase gene from rat brain RNA was also demonstrated. The 3' end region of this gene was amplified by the 3' RACE method and the amplified DNA was cloned after UDG digestion. Characterization of cloned DNAs by sequence analysis showed accurate repair of the cloning junctions. The ligase-free cloning method with UDG should prove to be a widely applicable procedure for rapid cloning of PCR-amplified DNA.     

A simple, rapid, high-fidelity and cost-effective PCR-based two-step DNA synthesis method for long gene sequences

Chemical synthesis of DNA sequences provides a powerful tool for modifying genes and for studying gene function, structure and expression. Here, we report a simple, high-fidelity and cost-effective PCR-based two-step DNA synthesis (PTDS) method for synthesis of long segments of DNA. The method involves two steps. (i) Synthesis of individual fragments of the DNA of interest: ten to twelve 60mer oligonucleotides with 20 bp overlap are mixed and a PCR reaction is carried out with high-fidelity DNA polymerase Pfu to produce DNA fragments that are ~500 bp in length. (ii) Synthesis of the entire sequence of the DNA of interest: five to ten PCR products from the first step are combined and used as the template for a second PCR reaction using high-fidelity DNA polymerase pyrobest, with the two outermost oligonucleotides as primers. Compared with the previously published methods, the PTDS method is rapid (5–7 days) and suitable for synthesizing long segments of DNA (5–6 kb) with high G + C contents, repetitive sequences or complex secondary structures. Thus, the PTDS method provides an alternative tool for synthesizing and assembling long genes with complex structures. Using the newly developed PTDS method, we have successfully obtained several genes of interest with sizes ranging from 1.0 to 5.4 kb.     

A large-subunit mitochondrial ribosomal DNA sequence translocated to the nuclear genome of two stone crabs (Menippe)

Two DNA sequences that appear to be homologous to large-subunit mitochondrial ribosomal RNA genes have been identified in the stone crabs Menippe mercenaria and M. adina. Amplification from whole genomic DNA by polymerase chain reaction (PCR) with oligonucleotide primers based on conserved portions of large-subunit mitochondrial rRNA genes consistently amplified two products of similar length (565 and 567 bp). These products differed at 3% of their nucleotide bases, and could be distinguished by a HindIII site. Only one of these sequences (designated the A sequence) was detected by PCR in purified mitochondrial DNA. The other (designated the B sequence) hybridized to total genomic DNA at a level consistent with a nuclear genome location. It is unlikely that the type B product would have been recognized as a nuclear copy by examination of its sequence alone. This is the first report of a mitochondrial gene sequence translocated into the nuclear genome of a crustacean.      

Site-directed mutagenesis by overlap extension using the polymerase chain reaction

Overlap extension represents a new approach to genetic engineering. Complementary oligodeoxyribonucleotide (oligo) primers and the polymerase chain reaction are used to generate two DNA fragments having overlapping ends. These fragments are combined in a subsequent 'fusion' reaction in which the overlapping ends anneal, allowing the 3' overlap of each strand to serve as a primer for the 3' extension of the complementary strand. The resulting fusion product is amplified further by PCR. Specific alterations in the nucleotide (nt) sequence can be introduced by incorporating nucleotide changes into the overlapping oligo primers. Using this technique of site-directed mutagenesis, three variants of a mouse major histocompatibility complex class-I gene have been generated, cloned and analyzed. Screening of mutant clones revealed at least a 98% efficiency of mutagenesis. All clones sequenced contained the desired mutations, and a low frequency of random substitution estimated to occur at approx. 1 in 4000 nt was detected. This method represents a significant improvement over standard methods of site-directed mutagenesis because it is much faster, simpler and approaches 100% efficiency in the generation of mutant product.     

Cloning of random-sequence oligodeoxynucleotides

Methods are described for cloning random or highly degenerate nucleotide (nt) sequences. The procedures use synthetically derived mixtures of oligodeoxynucleotides (oligos) whose heterogeneous central portions are bounded at their 5' and 3' ends by sequences recognized by restriction endonucleases. Oligo collections of defined length and nt composition are synthesized by utilizing appropriate concentrations of all four nucleotide precursors during each addition step for the central region. Single-stranded oligos with appropriate 5' and 3' ends can be ligated directly, although inefficiently, into double-stranded (ds) DNA molecules with complementary 5' and 3' extensions produced by restriction endonuclease cleavage. A more general and efficient method is to convert the oligo into a ds form by incubating it with the Klenow (large) fragment of Escherichia coli DNA polymerase I. If the 3' ends are palindromic, two oligo molecules will serve as mutual primers for polymerization. The resulting products are ds molecules containing two oligo units separated by the original 3' restriction site and bounded at each end by the original 5' restriction site. After appropriate restriction endonuclease cleavage, oligo units can be cloned by standard procedures. Analysis of 26 recombinant M13 phages indicates that the nt sequences of the cloned oligos are in good accord with what was expected on a random basis.     

Isolation of distantly related members in a multigene family using the polymerase chain reaction technique.

We have designed a strategy to isolate and identify genes (cDNAs) coding for distantly-related members within a large multigene family. We have used limited protein sequence information data to delineate conserved regions where members of a supergene family are related. Comparison of the nucleotide sequences of such conserved areas defined consensus sequences that were used for the synthesis of deoxynucleotide primers. Two forward and two reverse primers were synthesized, and four separate pairs of primer combinations were used under low stringency in polymerase chain reactions (PCR) to generate amplified DNA products. The PCR products were directionally cloned into the phage vector M13mp18. Each of four libraries was screened with radiolabeled PCR product generated using a pair of primers different from those used to generate the library. Using this approach on the supergene family of ligand-gated ion channels, we were able to isolate and identify two novel subunits of neurotransmitter-operated ion channels.