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.     

Mass-spectrometry DNA sequencing

Matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) has been explored widely for DNA sequencing. Compared to gel electrophoresis based sequencing systems, mass spectrometry produces very high resolution of sequencing fragments, rapid separation on microsecond time scales, and completely eliminates compressions associated with gel-based systems. While most of the research efforts have focused on using mass spectrometers to analyze the DNA products from Sanger sequencing or enzymatic digestion reactions, the read lengths attainable are currently insufficient for large-scale de novo sequencing. The advantage of mass-spectrometry sequencing is that one can unambiguously identify frameshift mutations and heterozygous mutations making it an ideal choice for resequencing projects. In these applications, DNA sequencing fragments that are the same length but with different base compositions are generated, which are challenging to consistently distinguish in gel-based sequencing systems. In contrast, MALDI-TOF MS produces mass spectra of these DNA sequencing fragments with nearly digital resolution, allowing accurate determination of the mixed bases. For these reasons mass spectrometry based sequencing has mainly been focused on the detection of frameshift mutations and single nucleotide polymorphisms (SNPs). More recently, assays have been developed to indirectly sequence DNA by first converting it into RNA. These assays take advantage of the increased resolution and detection ability of MALDI-TOF MS for RNA.     

Colorimetric-detected DNA sequencing

A sensitive, colorimetric method for visualizing the band pattern of DNA sequencing reaction is described. The enzymatic incorporation of radioactive nucleotides commonly used for the band detection is replaced by biotin conjugated to the 5'-terminus of a synthetic oligonucleotide by chemical synthesis. The oligonucleotide so labeled is used as a primer for dideoxy DNA sequencing in a primer extension reaction. The products of the sequencing reactions are analyzed on a denaturing polyacrylamide gel using the direct blotting electrophoresis technique. This technique makes it possible to transfer the band pattern during the electrophoresis onto an immobilizing matrix, on which it is made visible by an enzymatic reaction in less than 3 h. This biotin-based detection method is so sensitive that the sequencing reactions can be performed under the same conditions and concentrations as those for the radioactive detection.     

DNA sequencing separations in capillary gels on a modified commercial DNA sequencing instrument

DNA sequencing separations of standard DNA fragments of known sequence have been achieved in small diameter capillary gels electrophoresed and analyzed in parallel in a modified commercial DNA sequencer instrument. DNA sequencing in terms of base-calling accuracy is comparable to conventional slab gels; however, the separations in the capillary were performed somewhat faster and required less sample than those in the slab gel. Advantages of this approach vs. separations on conventional slab gels are discussed.     

Fluorescence photobleaching in DNA sequencing

Advances in DNA-sequencing technology suggest many possibilities using either conventional or unconventional means. Several approaches offer conceivable improvements in running time by one hundred fold or more. A fluorescence photobleaching scheme in combination with ultra-thin gel slab or capillary electrophoresis which proposes to shorten the run time and to increase the resolution of multi-fragment DNA analysis is reviewed. The advantages and some of the yet to be resolved obstacles are discussed.     

Stepping stones in DNA sequencing

In recent years there have been tremendous advances in our ability to rapidly and cost-effectively sequence DNA. This has revolutionized the fields of genetics and biology, leading to a deeper understanding of the molecular events in life processes. The rapid technological advances have enormously expanded sequencing opportunities and applications, but also imposed strains and challenges on steps prior to sequencing and in the downstream process of handling and analysis of these massive amounts of sequence data. Traditionally, sequencing has been limited to small DNA fragments of approximately one thousand bases (derived from the organism's genome) due to issues in maintaining a high sequence quality and accuracy for longer read lengths. Although many technological breakthroughs have been made, currently the commercially available massively parallel sequencing methods have not been able to resolve this issue. However, recent announcements in nanopore sequencing hold the promise of removing this read-length limitation, enabling sequencing of larger intact DNA fragments. The ability to sequence longer intact DNA with high accuracy is a major stepping stone towards greatly simplifying the downstream analysis and increasing the power of sequencing compared to today. This review covers some of the technical advances in sequencing that have opened up new frontiers in genomics.     

Improved chemiluminescent DNA sequencing

A new chemiluminescent 1,2-dioxetane substrate, CSPD, shows improved performance over AMPPD when used in our nonisotopic method for DNA sequencing. CSPD differs from AMPPD by the addition of a chlorine atom to the adamantyl group that limits the amount of aggregation of the dioxetane and its dephosphorylated anion. This results in a shorter time elapsing before reaching steady state light emission when detecting nucleic acids on nylon membrane. An additional advantage of CSPD over AMPPD is that the resolution of imaged DNA bands does not degrade over time. These features of CSPD permit rapid acquisition of high-quality DNA sequence data.     

Direct haplotype-specific DNA sequencing

Determining haplotype-specific DNA sequence information is very important in a wide range of research fields. However, no simple and robust approaches are currently available for determining haplotype-specific sequence information. We have addressed this problem by developing a very simple and robust haplotype-specific sequencing approach. We utilise the fact that DNA sequencing polymerases are sensitive to 3'end mismatches in the sequencing primer. By using two sequencing primers with 3'end corresponding to the two alleles in a given SNP locus, we are able to obtain allele-specific DNA sequences from both alleles. We evaluated this direct haplotype-specific approach by determining haplotypes within the intron 2 sequence of the fructan-6-fructosyltransferase (6-ft) gene in Lolium perenne L. We obtained reliable haplotype-specific sequences for all primers and genotypes evaluated. We conclude that the haplotype-specific sequencing is robust, and that the approach has a potentially very wide application range for any diploid organism.     

Partial-digest DNA sequencing.

A technique called partial-digest sequencing that permits DNA of 4-6 kb in length to be sequenced without subcloning is described. The method exploits the specific cuts introduced by partial digestion with restriction endonucleases that have 4-base recognition sites to produce ordered ladders of PCR-amplified fragments. The staggered ends contain PCR primers and can thus be individually sequenced using conventional methods to yield overlapping sequences covering the entire region. This method should have significant impact on both large and small DNA sequencing projects and find many applications in general manipulations in which ordered sets of deletions need to be produced.     

A DNA sequencing strategy

A modification of Lin's systematic DNA sequencing strategy is described. A method based on the religation of compatible cohesive ends generated by Sau3AI and BamHI was developed. The original procedure has been simplified and the yield of transfectant has been greatly improved. After complete digestion with BamHI and limited cleavage with Sau3AI, the single-cut linear DNA does not have to be separated from the supercoil or the open circular DNA on an agarose gel. After ligation, the DNA is digested with the restriction enzyme between the cloning site and BamHI site again. The original intact DNA is linearized, whereas the deleted subclone is not. Therefore the background is decreased to an undetectable level. This DNA sequencing strategy was tested on a 1.4-kb cDNA fragment containing the haptoglobin-related sequences. It is not necessary to purify large amounts of RF DNA (500 ng is enough) to get enough subclones. A set of subclones was produced in 1 day and the yield of plaques was about sixfold higher than that published.     

PCR and DNA sequencing

Specific DNA segments defined by the sequence of two oligonucleotides can be enzymatically amplified up to a millionfold using the polymerase chain reaction (PCR). One of the most significant uses of this technique is for generation of sequencing templates, either from cloned inserts or directly from genomic DNA. To avoid the problem of reassociation of the linear DNA strands in the sequencing reaction, ssDNA templates can be produced directly in the PCR or generated directly from dsDNA by enzymatic treatment, electrophoretic separation or affinity purification. By combining PCR with direct sequencing, both the amplification and the sequencing reaction can be performed in the same vial. Finally, use of fluorescently labeled terminators or sequencing primers will allow the whole procedure to be amenable to complete automation.     

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.