A fast and simple method for sequencing DNA cloned in the single-stranded bacteriophage M13.

The chain termination DNA sequencing procedure of Sanger et al. (1977) requires single-stranded DNA as template. M13 phage DNA exists as a single strand and therefore every DNA sequence cloned in M13 can be easily obtained in this form. Here we show that M13 single-stranded DNA pure enough to be used as a template for sequence determination can be prepared by simple centrifugation of the phage particle and extraction with phenol.     

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.     

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.     

Recognition sites of eukaryotic DNA topoisomerase I: DNA nucleotide sequencing analysis of topo I cleavage sites on SV40 DNA.

Eukaryotic DNA topoisomerase I introduces transient single-stranded breaks on double-stranded DNA and spontaneously breaks down single-stranded DNA. The cleavage sites on both single and double-stranded SV40 DNA have been determined by DNA sequencing. Consistent with other reports, the eukaryotic enzymes, in contrast to prokaryotic type I topoisomerases, links to the 3'-end of the cleaved DNA and generates a free 5'-hydroxyl end on the other half of the broken DNA strand. Both human and calf enzymes cleave SV40 DNA at the identical and specific sites. From 827 nucleotides sequenced, 68 cleavage sites were mapped. The majority of the cleavage sites were present on both double and single-stranded DNA at exactly the same nucleotide positions, suggesting that the DNA sequence is essential for enzyme recognition. By analyzing all the cleavage sequences, certain nucleotides are found to be less favored at the cleavage sites. There is a high probability to exclude G from positions -4, -2, -1 and +1, T from position -3, and A from position -1. These five positions (-4 to +1 oriented in the 5' to 3' direction) around the cleavage sites must interact intimately with topo I and thus are essential for enzyme recognition. One topo I cleavage site which shows atypical cleavage sequence maps in the middle of a palindromic sequence near the origin of SV40 DNA replication. It occurs only on single-stranded SV40 DNA, suggesting that the DNA hairpin can alter the cleavage specificity. The strongest cleavage site maps near the origin of SV40 DNA replication at nucleotide 31-32 and has a pentanucleotide sequence of 5'-TGACT-3'.     

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.     

Ordered deletions for DNA sequencing and in vitro mutagenesis by polymerase extension and exonuclease III gapping of circular templates.

A simple method is described for generating nested deletions from any fixed point in a cloned inset. Starting with a single-stranded phagemid template, T4 DNA polymerase is used to extend an annealed primer. This leads to a fully double-stranded circular molecule with a nick or small gap just 5' to the primer. Exonuclease III initiates progressive digestion from the resulting 3' end. Removal of timed aliquots and digestion with a single-strand specific endonuclease leads to a series of linear nested fragments having a common end corresponding to the 5' end of the primer. These molecules are circularized and used to transform cells, providing large numbers of deletion clones with targeted breakpoints. The 6-step procedure involves successive additions to tubes, beginning with a single-stranded template and ending with transformation; no extractions, precipitations or centrifugations are needed. Results are comparable to those obtained with standard Exonuclease III-generated deletion protocols, but there is no requirement for restriction endonuclease digestion or for highly purified double-stranded DNA starting material. This procedure provides a strategy for obtaining nested deletions in either direction both for DNA sequencing and for functional analysis.     

The production of single-stranded DNA suitable for sequencing using the polymerase chain reaction

A simple and reliable procedure for the amplification of single-stranded DNA suitable for sequencing is described. This procedure employs the polymerase chain reaction and implements modifications pertaining to the purification of the double-stranded DNA product prior to single-stranded DNA amplification. The most consistent sequencing reactions are obtained when the double-stranded DNA product is purified by centrifugation with a microconcentrator prior to single-stranded DNA amplification and the overall amount of specific primers and number of cycles used, in both single-stranded and double-stranded DNA polymerase chain reactions, are reduced.     

A versatile and simplified non-random strategy for nucleotide sequencing

We describe a versatile and simplified non-random strategy for nucleotide sequencing. This procedure avoids exposure of the vector DNA to endo- or exonucleases during construction of the subfragment library. The advantages resulting from this strategy are: (1) minimal manipulation in construction of the subfragment library, (2) no need for compatible restriction sites, (3) no insert size limitation, (4) can be used with both chemical and enzymatic sequencing methods. Hence, the procedure provides simplicity, universality and versatility for non-random nucleotide sequencing. We demonstrate the usefulness of this procedure by obtaining the nucleotide sequence of a goat 3.7-kb EcoRI fragment, which is 5' of the epsilon globin gene.     

Neighboring nucleotide interactions during DNA sequencing gel electrophoresis.

Electrophoretic separation of oligonucleotides in denaturing polyacrylamide gels is primarily a function of length-dependent mobility. The 3' terminal nucleotide sequence of the oligonucleotide is a significant, secondary determinant of mobility and separation. Oligomers with 3'-ddT migrate more slowly than expected on the basis of length alone, and thus are better separated from the preceding, shorter oligomers in the sequencing ladder. Oligomers with 3'-ddC are relatively faster than expected, and are therefore less separated. At the 3' penultimate position, -dC- increases and -dT- reduces separation. Purines at the 3' terminal or penultimate positions of oligonucleotides affect separation less than the pyrimidines. These results suggest specific interactions among neighboring nucleotides with important effects on the conformation of oligonucleotides during electrophoresis. These interactions are compared to compression artifacts, which represent more extreme anomalies of length-dependent separation of oligonucleotides. Knowledge of base-specific effects on electrophoretic behavior of DNA oligomers supplements the usual information available for determination of sequences; additionally it provides an avenue to thermodynamic and hydrodynamic investigations of DNA structure.     

Exoquence DNA sequencing.

We have developed a strategy for DNA sequencing based on exonuclease III digestion followed by double strand specific endonuclease digestion and direct dideoxynucleotide sequencing reaction. This strategy eliminates the need for subcloning, oligonucleotide primers, and prior knowledge of the DNA to be sequenced. All template and primer duplexes needed for sequencing a complete insert can be prepared in one day from uncharacterized starting DNA. Sequence information can be obtained from different regions of the DNA simultaneously. The method uses double-stranded DNA to generate single-stranded template and primer, and thus produces high quality sequence results. Commercially available dideoxy-sequencing kits are well suited for this method. The strategy should be applicable for both automatic and routine laboratory DNA sequencing.     

Multicopy single-stranded DNA isolated from a gram-negative bacterium, Myxococcus xanthus

A gram-negative bacterium, Myxococcus xanthus, was found to contain 500 to 700 copies per chromosome of a short single-stranded linear DNA fragment. When this DNA (multicopy single-stranded DNA; msDNA) labeled at the 5' end with kinase was used as a probe against total chromosomal blots, it hybridized to unique high molecular weight bands, which were cloned and sequenced. Labeling of msDNA was also possible using the Klenow fragment of DNA polymerase I as well as terminal deoxynucleotidyl transferase, permitting direct sequencing. The 5' end of msDNA was found to be primed by a short RNA segment. The DNA portion of msDNA consisted of 163 bases. Exact correspondence was seen between the msDNA sequence and the sequence of a chromosomal clone. An elaborate secondary structure is postulated for the msDNA sequence. A similar satellite DNA was also found in another myxobacterium, Stigmatella aurantiaca.     

Specific-primer-directed DNA sequencing

A simple and rapid strategy for DNA sequence analysis based on the Sanger chain-termination method is described. This procedure utilizes full-sized inserts of 1 to 4 kb of DNA cloned into M13 bacteriophage vectors. After the sequence of the first 600-650 bp of the insert DNA has been determined with the commercially available universal vector primer, a specific oligonucleotide is synthesized utilizing the sequence data obtained from the 3' end of the sequence and used as a primer to extend the sequence analysis for another 600-650 nucleotides. Additional primers are synthesized in a similar manner until the nucleotide sequence of the entire insert DNA has been determined. General guidelines for the selection of oligonucleotide length and composition and the use of unpurified primers are discussed. The use of the specific-primer-directed approach to dideoxynucleotide sequence analysis, in association with highly purified single-stranded template DNA, reduces considerably the time required for the analysis of large segments of DNA.     

Rapid identification of clones using the same degenerate oligonucleotide mixture for both screening and sequencing

A simple and rapid strategy for distinguishing between positively hybridizing colonies and false positive-hybridization signals is described. The isolation of a specific DNA sequence depends on the ability to distinguish between a clone that contains the correct sequence and a false hybridization-positive or background signal. This procedure utilizes the same oligonucleotide mixture both as a screening probe and as a sequencing primer. The mixture of oligonucleotides is used as a primer to obtain sequence information directly from double-stranded DNA. Conditions for sequencing with oligonucleotides having up to 64-fold degeneracy are described. Since the sequence information obtained is directly adjacent to the site of oligonucleotide:DNA hybridization, it is necessary to know only a minimal length of DNA or peptide sequence to both design oligonucleotide probes and confirm the authenticity of the hybridization positives. The advantages of the degenerate oligonucleotide sequencing method include the rapid, reliable identification of authentic versus false hybridization positives made directly without subcloning into single-stranded M13 phage, without sequencing large regions of DNA, or without synthesizing sequence-specific primers.     

Nucleotide capacitance calculation for DNA sequencing

Using a first-principles linear response theory, the capacitance of the DNA nucleotides, adenine, cytosine, guanine, and thymine, are calculated. The difference in the capacitance between the nucleotides is studied with respect to conformational distortion. The result suggests that although an alternate current capacitance measurement of a single-stranded DNA chain threaded through a nanogap electrode may not be sufficient to be used as a standalone method for rapid DNA sequencing, the capacitance of the nucleotides should be taken into consideration in any GHz-frequency electric measurements and may also serve as an additional criterion for identifying the DNA sequence.     

Primer-independent RNA sequencing with bacteriophage phi6 RNA polymerase and chain terminators

Here we propose a new general method for directly determining RNA sequence based on the use of the RNA-dependent RNA polymerase from bacteriophage phi6 and the chain terminators (RdRP sequencing). The following properties of the polymerase render it appropriate for this application: (1) the phi6 polymerase can replicate a number of single-stranded RNA templates in vitro. (2) In contrast to the primer-dependent DNA polymerases utilized in the sequencing procedure by Sanger et al. (Proc Natl Acad Sci USA, 1977, 74:5463-5467), it initiates nascent strand synthesis without a primer, starting the polymerization on the very 3'-terminus of the template. (3) The polymerase can incorporate chain-terminating nucleotide analogs into the nascent RNA chain to produce a set of base-specific termination products. Consequently, 3' proximal or even complete sequence of many target RNA molecules can be rapidly deduced without prior sequence information. The new technique proved useful for sequencing several synthetic ssRNA templates. Furthermore, using genomic segments of the bluetongue virus we show that RdRP sequencing can also be applied to naturally occurring dsRNA templates. This suggests possible uses of the method in the RNA virus research and diagnostics.     

Differentiating between monozygotic twins through next-generation mitochondrial genome sequencing

Monozygotic (MZ) twins, considered to be genetically identical, cannot be distinguished from one another by standard forensic DNA testing. A recent study employed whole genome sequencing to identify extremely rare mutations and reported that mutation analysis could be used to differentiate between MZ twins. Compared with nuclear DNA, mitochondrial DNA (mtDNA) has higher mutation rates; therefore, minor differences theoretically exist in MZ twins' mitochondrial genome (mtGenome). However, conventional Sanger-type sequencing (STS) is neither amenable to, nor feasible for, the detection of low-level sequence variants. The recent introduction of massively parallel sequencing (MPS) has the capability to sequence many targeted regions of multiple samples simultaneously with desirable depth of coverage. Thus, the aim of this study was to assess whether full mtGenome sequencing analysis can be used to differentiate between MZ twins. Ten sets of MZ twins provided blood samples that underwent extraction, quantification, mtDNA enrichment, library preparation, and ultra-deep sequencing. Point heteroplasmies were observed in eight sets of MZ twins, and a single nucleotide variant (nt15301) was detected in five sets of MZ twins. Thus, this study demonstrates that ultra-deep mtGenome sequencing could be used to differentiate between MZ twins.     

Application of partial restriction procedure in both shotgun and non-random strategies for nucleotide sequencing

Partial digestion of a target DNA fragment with 4-bp-recognition restriction enzymes followed by a forced ligation to an M13 vector was employed for the construction of a subfragment library. The library can be used for either shotgun or non-random nucleotide sequencing. Application of the partial digests generated with the 4-bp recognition restriction enzymes instead of DNase I in the improved non-random strategy for nucleotide sequencing (Li and Wu, 1987) made the procedure as easy as that of the random strategy. The library can also be used in shotgun nucleotide sequencing directly, and few self-ligated subfragments were found. The usefulness of this procedure was demonstrated by the sequencing of a goat 6.5-kb EcoRI fragment, which is located 5' to the globin gene.