Elimination of band compression in sequencing gels by the use of N4-methyl-2'-deoxycytidine 5'-triphosphate.

Taq DNA polymerase, Sequenase, and the large fragment of E.coli polymerase I effectively utilize N4-methyl-2'-deoxycytidine 5'-triphosphate (N4-methyl-dCTP) in the place of dCTP in dideoxynucleotide terminator sequencing reactions on single-stranded templates. When the resulting fragment mixtures are resolved on sequencing gels, they are found to be free of band compressions even in cases where such compressions remain unresolved by the substitution of 7-deaza-dGTP for dGTP. Sequencing reactions using N4-methyl-dCTP instead of dCTP are somewhat more prone to false stops than are sequencing reactions using 7-deaza-dGTP instead of dGTP; this difference is more pronounced when sequencing with Sequenase at 37 degrees C than when sequencing with Taq DNA polymerase at 72 degrees C. For the three polymerases investigated, replacement of dCTP by N4-methyl-dCTP does not fundamentally change the characteristic variations in band intensities seen in the C-lane. N4-methyl-dCTP can also be used for sequencing double-stranded DNA and for DNA amplification by the polymerase chain reaction.     

Bst DNA polymerase permits rapid sequence analysis from nanogram amounts of template

A simple, rapid method is presented for the enzymatic sequence analysis of nanogram amounts of single-stranded or double-stranded DNA. This approach employs the thermostable DNA polymerase from Bacillus sterothermophilus and exploits its ability to efficiently extend all of the template-primer complex, even at low substrate concentrations. The procedure requires few pipetting steps, no preannealing step and very short reaction time. This method can significantly reduce the cost associated with DNA polymerase and the amount of template and time required to perform the enzymatic sequencing reactions. As little as a 10-ng aliquot of such sequencing reactions can be analyzed on a fluorescence-based capillary gel electrophoresis instrument recently developed in our laboratory. This highly sensitive detection, in conjunction with the ability to efficiently sequence nanogram amounts of template, strongly suggests the feasibility of direct DNA sequencing of single bacteriophage M13 plaques without prior amplification.     

Optimization of asymmetric polymerase chain reaction for rapid fluorescent DNA sequencing

A high-throughput method for the preparation of single-stranded template DNA, which is suitable for sequence analysis using fluorescent labeling chemistry, is described here. In this procedure, the asymmetric polymerase chain reaction is employed to amplify recombinant plasmid or bacteriophage DNA directly from colonies or plaques. The use of amplification primers located at least 200 base pairs 5' to the site of sequencing primer annealing removes the need for extensive purification of the asymmetric polymerase chain reaction product. Instead, the single-stranded product DNA is purified by a simple isopropanol precipitation step and then directly sequenced using fluorescent dye-labeled oligonucleotides. This method significantly reduces the time and labor required for template preparation and improves fluorescent DNA sequencing strategies by providing a much more uniform yield of single-stranded DNA.     

Polymerase chain reaction amplification of single-stranded DNA containing a base analog, 2-chloradenine.

By utilization of polymerase chain reaction techniques, single-stranded DNA of defined length and sequence containing a purine analog, 2-chloroadenine, in place of adenine was synthesized. This was accomplished by a combination of standard polymerase chain amplification reactions with Thermus aquaticus DNA polymerase in the presence of four normal deoxynucleoside triphosphates, M13 duplex DNA as template, and two primers to generate double-stranded DNA 118 bases in length. An asymmetric polymerase chain reaction, which produced an excess of single-stranded 98-base DNA, was then conducted with 2-chloro-2'-deoxy-adenosine 5'-triphosphate in place of dATP and with only one primer that annealed internal to the original two primers. Standard polymerase chain reaction techniques alone conducted in the presence of the analog as the fourth nucleotide did not produce duplex DNA that was modified within both strands. This asymmetric technique allows the incorporation of an altered nucleotide at specific sites into large quantities of single-stranded DNA without using chemical phosphoramidite synthesis procedures and circumvents the apparent inability of DNA polymerase to synthesize fully substituted double-stranded DNA during standard amplification reactions. The described method will permit the study of the effects of modified bases in template DNA on a variety of protein-DNA interactions and enzymes.     

Efficient production of single-stranded DNA as long as 2 kb for sequencing of PCR-amplified DNA.

A modification of the asymmetric PCR method is described, which reliably facilitates sequencing of PCR-amplified DNA. This procedure produces single-stranded DNA fragments as long as two kilobases that are suitable for dideoxy DNA sequencing. First, a PCR for double-stranded DNA is preformed under optimal conditions (double-stranded PCR). Then, a 5-10-microliters fraction of the double-stranded PCR and a single primer are used to generate single-stranded DNA in a separate PCR (single-stranded PCR). The concentration of the single primer are used to generate single-stranded DNA in a separate PCR (single-stranded PCR). The concentration of the single primer is approximately 0.4 microM. Usually 15 to 25 cycles of single-stranded PCR are optimal to produce single-stranded DNA for four to eight sequencing reactions. The single-stranded DNA is purified by centrifugal ultrafiltration and used directly in dideoxy sequencing. This method was employed to produce high-quality single-stranded DNA templates from a variety of organisms for efficient DNA sequencing of PCR-amplified DNA.     

TempliPhi,phi29 DNA polymerase based rolling circle amplification of templates for DNA sequencing

We have developed a novel, isothermal DNA amplification strategy that employs phi29 DNA polymerase and rolling circle amplification to generate high-quality templates for DNA sequencing reactions. The TempliPhi DNA amplification kits take advantage of the fact that cloned DNA is typically obtained in circular vectors, which are readily replicated in vitro using phi29 DNA polymerase by a rolling circle mechanism. This single subunit, proofreading DNA polymerase has excellent processivity and strand displacement properties for generation of multiple, tandem double-stranded copies of the circular DNA, generating as much as 10(7)-fold amplification. Large amounts of product (1-3 microg) can be obtained in as little as 4 hours. Input DNA can be as little as 0.01 ng of purified plasmid DNA, a single bacterial colony, or a 1 microL of a saturated overnight culture. Additionally, the presence of an associated proof reading function within the phi29 DNA polymerase ensures high-fidelity amplification. Once completed, the product DNA can be used directly in sequencing reactions. Additionally, the properties of phi29 DNA polymerase and its use in applications such as amplification ofhuman genomic DNA for genotyping studies is discussed.     

Formation of Template-Switching Artifacts by Linear Amplification

Linear amplification is a method of synthesizing single-stranded DNA from either a single-stranded DNA or one strand of a double-stranded DNA. In this protocol, molecules of a single primer DNA are extended by multiple rounds of DNA synthesis at high temperature using thermostable DNA polymerases. Although linear amplification generates the intended full-length single-stranded product, it is more efficient over single-stranded templates than double-stranded templates. We analyzed linear amplification over single- or double-stranded mouse H-ras DNA (exon 1–2 region). The single-stranded H-ras template yielded only the intended product. However, when the double-stranded template was used, additional artifact products were observed. Increasing the concentration of the double-stranded template produced relatively higher amounts of these artifact products. One of the artifact DNA bands could be mapped and analyzed by sequencing. It contained three template-switching products. These DNAs were formed by incomplete DNA strand extension over the template strand, followed by switching to the complementary strand at a specific Ade nucleotide within a putative hairpin sequence, from which DNA synthesis continued over the complementary strand.     

Monoplex/multiplex linear-after-the-exponential-PCR assays combined with PrimeSafe and Dilute-'N'-Go sequencing

This protocol describes the design and execution of monoplex and multiplex linear-after-the-exponential (LATE)-PCR assays using a novel reagent, PrimeSafe, that suppresses all forms of mispriming. LATE-PCR is an advanced form of asymmetric amplification that uses a limiting primer and an excess primer for efficient exponential amplification of double-stranded DNA, followed by linear amplification of one strand. Each single-stranded amplicon can be quantitatively detected in real time or at end point. By separating primer annealing from product detection, LATE-PCR enables product analysis at low temperatures. Alternatively, each single strand can be sequenced by a convenient Dilute-'N'-Go procedure. Amplified samples are diluted with individual sequencing primers without the use of columns or spins. We have amplified and then sequenced 15 different single-stranded products generated in a single multiplexed LATE-PCR comprised of 15 pairs of unrelated primers. Dilute-'N'-Go dideoxy sequencing is more convenient, faster and less expensive than sequencing double-stranded amplicons generated via conventional symmetric PCR. The preparation of LATE-PCR products for Dilute-'N'-Go sequencing takes only 30 seconds.     

Production of single-stranded DNA for sequencing: an alternative approach.

We describe a simple procedure for the direct sequencing of single-stranded, PCR-amplified, target regions of human genomic DNA. At variance with previously reported procedures, purification of the desired double-stranded DNA was introduced. This additional step allowed the single-stranded amplification and sequencing of the target gene. This step is required for direct sequencing of some amplified regions of human genomic DNA. However, no individual technique seems suitable to generate and sequence all single-stranded DNA.     

Sequencing of double-stranded PCR products

Very often the experimental step following PCR is sequencing of the amplified fragment. Two protocols that allow direct sequencing of a double-stranded PCR product are described. The first involves removal of one strand of the PCR product using an Ml3 single-stranded DNA clone, allowing the second strand to be sequenced. The second protocol involves Maxam-Gilbert chemical sequencing after PCR amplification with one labeled primer. The advantages and disadvantages of the two protocols are compared, but both yield DNA sequence without cloning of the PCR product.     

Deletion mutagenesis in M13 by polymerase chain reaction using universal sequencing primers

A simple procedure is described for the efficient deletion of large DNA sequences. The method involves a combination of oligonucleotide-directed mutagenesis in bacteriophage M13 and amplification of the mutagenized product by polymerase chain reaction. In contrast to other protocols employing polymerase chain reaction, synthesis of only one specific primer is required. The efficiency of heteroduplex formation between mutagenic primers directing large deletions and single-stranded template is discussed.     

Enhancing PCR amplification and sequencing using DNA-binding proteins

The polymerase chain reaction (PCR) is a powerful core molecular biology technique, which when coupled to chain termination sequencing allows gene and DNA sequence information to be derived rapidly. A number of modifications to the basic PCR format have been developed in an attempt to increase amplification efficiency and the specificity of the reaction. We have applied the use of DNA-binding protein, gene 32 protein from bacteriophage T4 (T4gp32) to increase amplification efficiency with a number of diverse templates. In addition, we have found that using single-stranded DNA-binding protein (SSB) or recA protein in DNA sequencing reactions dramatically increases the resolution of sequencing runs. The use of DNA-binding proteins in amplification and sequencing may prove to be generally applicable in improving the yield and quality of a number of templates from various sources.     

Rapid generation of subclones for DNA sequencing using the reverse cloning procedure

A fast and reliable procedure for generating subclones necessary for sequencing long stretches of DNA has been developed. The reverse cloning procedure involves cloning a fragment of DNA into a single-stranded plasmid or phage vector containing a polycloning region; synthesizing variable lengths of double-stranded DNA using a "Universal Primer"; isolating the double-stranded DNA; and force cloning the double-stranded DNA fragments into a complementary vector with the polycloning region in the reverse orientation. The resulting clones can be sequenced, using the same Universal Primer and T7 DNA polymerase, to provide overlapping DNA sequences. The reverse cloning procedure can be used to construct deletion mutations.     

A directed nucleotide-sequencing approach for single-stranded vectors based on recloning intermediates of a progressive DNA synthesis reaction

A simple method for site-directed nucleotide sequencing is presented that uses a novel procedure for generating nested 'deletions' within inserts of single-stranded clones. In this method, single-stranded template, sequencing primer, and the Klenow fragment of Escherichia coli DNA polymerase I are used to initiate progressive DNA synthesis of the entire insert of the clone. By time-dependent sampling and pooling of intermediates from the synthesis reaction a series of nested double-stranded DNA subfragments of the insert can be created. Nested subclones are then produced by S1-endonuclease treatment and oriented subcloning methods. First, smaller quantities of template DNA can be used, equivalent to a fraction of a small DNA sequencing prep. Second, it works with single-stranded M13 phage DNA rather than requiring the preparation of double-stranded replicative form DNA as in ExoIII-based methods. Third, the 'deletions' it generates can span areas of simple nucleotide sequence or secondary structure that often halt digestion in the single-stranded exonuclease-based method. Last, the method is adaptable to a larger variety of insert cloning sites than the ExoIII-based method. The main disadvantage of the method is that, due to the lower efficiency of subcloning larger DNA fragments, subclone inserts larger than 3 kb are generated only infrequently.     

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.     

Rapid and reliable fluorescent cycle sequencing of double-stranded templates.

Automated DNA sequencing is an extremely valuable technique which requires very high quality DNA templates to be carried out successfully. While it has been possible to readily produce large numbers of such templates from M13 or other single-stranded vectors for several years, the sequencing of double-stranded DNA templates using the ABI 373 DNA Sequencer has had a considerably lower success rate. We describe how the combination of a new fluorescent, dideoxy sequencing method, called cycle-sequencing, coupled with modifications to template isolation procedures based on Qiagen columns, makes fluorescent sequencing of double-stranded templates a reliable procedure. From a single five milliliter culture enough DNA can be isolated (up to 20 micrograms) to do 4-8 sequencing reactions, each of which yields 400-500 bases of high quality sequence data. These procedures make the routine use of double-stranded DNA templates a viable strategy in automated DNA sequencing projects.     

Thermal cycle dideoxy DNA sequencing

Thermal cycle dideoxy DNA sequencing eliminates the requirements for independent primer annealing and double-stranded DNA denaturation steps. The method enables sequencing from nanogram amounts of DNA from double-stranded and single-stranded PCR products, and plasmid or phage DNA templates. Thermal cycle sequencing also enables direct sequencing from bacterial colonies or phage plaques. Protocols using the Vent exo⁻ DNA polymerase, helpful suggestions, and a troubleshooting guide are also presented.     

A method for sequencing polymerase chain reaction products can be used to sequence Bacillus subtilis "miniprep" plasmid DNA

Several methods for sequencing double-stranded plasmid DNA isolated from E. coli have been described. These methods are usually not effective when used to sequence plasmid DNA isolated from Bacillus subtilis. In the course of developing a simplified version of a previously published protocol for polymerase chain reaction product sequencing, it was found that this protocol could be used for sequencing plasmid DNA isolated from Bacillus subtilis.     

Isothermal strand-displacement amplification applications for high-throughput genomics

Amplification of source DNA is a nearly universal requirement for molecular biology applications. The primary methods currently available to researchers are limited to in vivo amplification in Escherichia coli hosts and the polymerase chain reaction. Rolling-circle DNA replication is a well-known method for synthesis of phage genomes and recently has been applied as rolling circle amplification (RCA) of specific target sequences as well as circular vectors used in cloning. Here, we demonstrate that RCA using random hexamer primers with 29 DNA polymerase can be used for strand-displacement amplification of different vector constructs containing a variety of insert sizes to produce consistently uniform template for end-sequencing reactions. We show this procedure to be especially effective in a high-throughput plasmid production sequencing process. In addition, we demonstrate that whole bacterial genomes can be effectively amplified from cells or small amounts of purified genomic DNA without apparent bias for use in downstream applications, including whole genome shotgun sequencing.