Bidirectional sequencing of supercoiled plasmid DNA

In this paper we show that restriction DNA fragments can prime DNA synthesis of a homologous supercoiled plasmid DNA. Using the dideoxyribonucleotide chain terminator method, newly synthesized truncated chains can be detached from the primers by restriction enzyme digestion. Therefore, by choosing DNA fragments flanked by two different restriction enzymes sites, nucleotide sequence information can be simultaneously obtained on both regions of the DNA surrounding the restriction fragment. The advantage of this sequencing approach over current methods is that no prior knowledge of the primary sequence is needed to find the nucleotide sequence of a given DNA fragment. Thus, synthetic primers are not required and internal sequences of a given clone can be easily accessed without the need of fragmenting the original construct. The method has been used with rapid plasmid preparations, thus considerable time and effort can be saved in the gathering of nucleotide sequence information.     

Mutation detection by pyrosequencing: sequencing of exons 5-8 of the p53 tumor suppressor gene

The ability to sequence a large number of DNA samples rapidly and accurately for detection of all possible mutations is a critical goal for the future application of DNA sequencing in routine medical diagnostics. Pyrosequencing() is a non-electrophoretic real-time DNA sequencing method that uses the luciferase-luciferin light release as the detection signal for nucleotide incorporation into target DNA. For pyrosequencing of the human p53 gene, a nested multiplex PCR method for amplification of exons 5-8 was prepared. In order to investigate the use of pyrosequencing in mutation detection, DNA samples from skin-cancer patients were used. Two forms of nucleotide dispensation strategy were used, cyclic and programmed. Bi-directional pyrosequencing was performed and the overlapping sequence data produced were assembled to determine the sequence of the gene. Reliable sequencing data were obtained with both dispensation strategies, but some advantages were obtained using the programmed nucleotide dispensation approach, such as longer and faster reads, and fewer out-of-phase problems. The accuracy of pyrosequencing for detection of p53 mutations and allele distribution was demonstrated.     

Use of a chemically modified T7 DNA polymerase for manual and automated sequencing of supercoiled DNA

Procedures are presented for reliable and accurate nucleotide sequence analysis using as template supercoiled DNA prepared by a modified rapid boiling minipreparation protocol. This method yields DNA templates suitable for sequencing within 1 h of bacterial harvest. We describe optimal reaction conditions for supercoiled miniprep DNA sequencing using a modified T7 DNA polymerase (Sequenase) in dideoxynucleotide chain termination reactions. We demonstrate that under these conditions, the sequencing data obtained with miniprep DNA is indistinguishable from that obtained with CsCl purified supercoiled DNA or from that obtained using single stranded DNA templates. We further show that the supercoiled DNA sequencing reactions can be analyzed on a commercially available automated DNA sequencing system that detects 32P labeled DNA during its electrophoretic separation. Taken together, these developments represent a significant improvement in the process of nucleotide sequence analysis.     

Assignment of position-specific error probability to primary DNA sequence data.

DNA sequence predicted from polyacrylamide gel-based technologies is inaccurate because of variations in the quality of the primary data due to limitations of the technology, and to sequence-specific variations due to nucleotide interactions within the DNA molecule and with the gel. The ability to recognize the probability of error in the primary data will be useful in reconstructing the target sequence of a DNA sequencing project, and in estimating the accuracy of the final sequence. This paper describes the use of linear discriminant analysis to assign position-specific probabilities of incorrect, over- and under-prediction of nucleotides for each predicted nucleotide position in primary sequence data generated by a gel-based DNA sequencing technology. Using this method, most of the error potential in primary sequence data can be assigned to a limited number of discrete positions. The use of probability values in the sequence reconstruction process, and in estimating the accuracy of consensus sequence determination is described.     

Optimal reconstruction of a sequence from its probes.

An important combinatorial problem, motivated by DNA sequencing in molecular biology, is the reconstruction of a sequence over a small finite alphabet from the collection of its probes (the sequence spectrum), obtained by sliding a fixed sampling pattern over the sequence. Such construction is required for Sequencing-by-Hybridization (SBH), a novel DNA sequencing technique based on an array (SBH chip) of short nucleotide sequences (probes). Once the sequence spectrum is biochemically obtained, a combinatorial method is used to reconstruct the DNA sequence from its spectrum. Since technology limits the number of probes on the SBH chip, a challenging combinatorial question is the design of a smallest set of probes that can sequence an arbitrary DNA string of a given length. We present in this work a novel probe design, crucially based on the use of universal bases [bases that bind to any nucleotide (Loakes and Brown, 1994)] that drastically improves the performance of the SBH process and asymptotically approaches the information-theoretic bound up to a constant factor. Furthermore, the sequencing algorithm we propose is substantially simpler than the Eulerian path method used in previous solutions of this problem.     

Selective binding of actinomycin D and distamycin A to DNA.

The exact sites at which a number of drugs inhibit the nick translation of DNA by E.coli DNA polymerase-I have been pinpointed. In order to do this, a method has been developed for sequencing double-stranded plasmid DNA from the site of a specifically induced nick. The initial experiments have concentrated on analysis of drug inhibition of nick translation in a 200 nucleotide region near the Eco Rl origin of pBR313. Many drugs were found to inhibit nick translation in a highly sequence specific manner. For actinomycin D, significant inhibition occurred at just four sites in the nucleotide sequence under test and only one sequence (pGpCpGpCpGpGp) gave really strong inhibition. Distamycin A gave a different pattern of inhibition with particularly strong stops in just two of the many A-T rich regions in the DNA. Experiments with caffeine suggest that factors in addition to primary sequence are important in determining where major inhibition occurs.     

Direct sequencing of baculovirus genomic DNA: sequence determination of the engineered respiratory syncytial virus chimeric FG gene.

Primer-directed enzymatic sequencing has proven to be an efficient and effective method for sequencing various size double-stranded DNA templates. We previously developed a primer-directed sequencing procedure for using double-stranded cosmid (50 kb) DNAs as template. We are interested in using this method to directly sequence larger DNA templates. Towards this goal we applied this method to directly sequence an engineered gene that had been transferred and integrated into the 130-kb baculovirus genome. Both crudely prepared and CsCl gradient-banded baculovirus DNAs were tested and reasonable sequencing ladders were obtained for both types of DNA templates. As little as 3 micrograms of gradient-banded baculovirus DNA were found to be sufficient to obtain film exposure times similar to those observed for cosmid size templates, 24 to 48 h. Effectiveness of the described method was demonstrated by obtaining the complete sequence of the engineered respiratory syncytial virus chimeric FG gene (2.5 kb in length) directly from the recombinant baculovirus "Baculo-FG" genome. Thus, our results demonstrate first, that double-stranded DNA templates as large as 130 kb can be sequenced directly and second, that the nucleotide sequence of engineered genes integrated within the baculovirus genome can be determined without the use of any intermediate steps of procedures.     

Novel approach for the effective determination of DNA scission site using the Sanger method

This paper describes the effective determination of DNA scission site using a novel approach that is based on the Sanger method of nucleotide sequencing. The DNA scission site is determined by contrast with the nucleotide sequence of the DNA. Here, instead of the traditional Maxam-Gilbert method for the determination of the DNA sequence, we utilized the Sanger method and studied its effectiveness in the determination of DNA scission sites. Using this method, the determination of DNA scission site becomes more facile and exact. And the total time for the determination is reduced nearly by half in comparison to the Maxam-Gilbert method. Further advantages of this novel approach include the reduced risks of radiation exposure for researchers and contamination of the apparatus.     

Alternative dideoxy sequencing of double-stranded DNA by cyclic reactions using Taq polymerase.

The polymerase chain reaction (PCR) is a technique to amplify a specific DNA sequence millions of times. The thermostable enzyme Taq polymerase allows this procedure to take place under conditions of high specificity and automatization. By combining the techniques of PCR and dideoxy sequencing, it is possible to perform DNA sequencing independently of their structures. The cyclic sequencing reaction is carried out in the presence of an excess amount of sequencing primer and a radioactive nucleotide ([alpha-35S]dATP) using a DNA thermal cycler. Different reaction conditions were investigated and optimized including nucleotide ratios in each termination mix, primer/template ratios, amount of a radioactive nucleotide, and the program of the reaction. This method allows the detection of single base substitutions in heterozygous alleles, and the detection of homozygous deletions. A new RFLP of the human porphobilinogen deaminase (PBGD) gene was identified using this technique. This RFLP is created by one base difference (cytosine or adenine) that changes the restriction site for Apa LI. The alternative sequencing method described in this study is a simple and time-saving procedure that can also be used for large sequencing projects.     

A rapid enzymatic DNA sequencing technique: determination of sequence alterations in early simian virus 40 temperature sensitive and deletion mutants.

We have adapted a rapid sequencing technique from the enzymatic nick-translation method of Maat and Smith. The Forward-Backward procedure employs both synthetic and 3' to 5' exonucleolytic activities of E. coli DNA polymerase I to achieve greater reliability, especially in reading stretches of the same nucleotide. The technique has been employed to determine sequence alterations in four early SV40 temperature-sensitive (tsA) point mutants and five early SV40 viable deletion mutants. The nucleotide sequence of these mutants provides an insight into their biological properties.     

Strategy and methods for directly sequencing cosmid clones

The primer-directed enzymatic sequencing method for sequencing double-stranded DNA templates has made possible the development of new strategies for directly sequencing large DNA molecules. Toward this goal, we have developed a strategy and the necessary techniques to obtain the complete sequence of cosmid clones (double-stranded DNA molecules in the size range of 50 kb). Our present strategy uses the chemical sequencing method to obtain sequence initiation points internal to a cosmid insert and the primer-directed enzymatic DNA sequencing method to extend these sequence contigs. As part of this development we added a nucleotide "chase" solution to the standard T7 sequencing protocol and included the use of both [alpha-32P]-dATP and -dCTP for labeling. With these modifications our double-stranded cosmid DNA sequencing reactions routinely extend well beyond 1000 bp, and film exposure times are kept to a minimum (24 to 48 h). We can routinely separate sequenced DNA fragments, using a 1-m gel system, which can be accurately read (with less than 0.5% error) to distances of 800 bp or more, from the oligomer primer. The strategy and procedures presented here allow the complete sequence of a cosmid clone to be obtained without subcloning.     

Direct DNA sequence determination from total genomic DNA.

It is possible to perform a combined amplification and sequencing reaction ('DEXAS') directly from complex DNA mixtures by using two thermostable DNA polymerases, one that favours the incorporation of deoxynucleotides over dideoxynucleotides, and one which has a decreased ability to discriminate between these two nucleotide forms. During cycles of thermal denaturation, annealing and extension, the former enzyme primarily amplifies the target sequence whereas the latter enzyme primarily performs a sequencing reaction. This method allows the determination of single-copy nuclear DNA sequences from amounts of human genomic DNA comparable to those used to amplify nucleotide sequences by the polymerase chain reaction. Thus, DNA sequences can be easily determined directly from total genomic DNA.     

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.     

Genotyping HapSTR loci: phase determination from direct sequencing of PCR products

HapSTRs combine information from a microsatellite (or simple tandem repeat, STR) with one or more single nucleotide polymorphisms in the DNA sequence immediately flanking the STR. These loci may offer increased power for the estimation of demographic parameters, but also present some challenges for data collection and analysis. We describe a process for inferring HapSTR alleles, including the flanking haplotypes, STR alleles and their phase relative to each other, directly from DNA sequence electropherograms of PCR products from heterozygous individuals. Our approach eliminates the need for more costly and time-consuming processes, such as cloning or acrylamide gel electrophoresis to separate alleles prior to sequencing.     

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.     

Recent patents of nanopore DNA sequencing technology: progress and challenges

DNA sequencing techniques witnessed fast development in the last decades, primarily driven by the Human Genome Project. Among the proposed new techniques, Nanopore was considered as a suitable candidate for the single DNA sequencing with ultrahigh speed and very low cost. Several fabrication and modification techniques have been developed to produce robust and well-defined nanopore devices. Many efforts have also been done to apply nanopore to analyze the properties of DNA molecules. By comparing with traditional sequencing techniques, nanopore has demonstrated its distinctive superiorities in main practical issues, such as sample preparation, sequencing speed, cost-effective and read-length. Although challenges still remain, recent researches in improving the capabilities of nanopore have shed a light to achieve its ultimate goal: Sequence individual DNA strand at single nucleotide level. This patent review briefly highlights recent developments and technological achievements for DNA analysis and sequencing at single molecule level, focusing on nanopore based methods.     

DNA sequencing with direct blotting electrophoresis.

A method for transferring the DNA molecules of sequencing reaction mixtures onto an immobilizing matrix during electrophoresis has been developed. A blotting membrane moves with constant speed across the end of a very short, denaturing gel and collects the molecules according to size. A constant distance between bands for molecules differing in length by one nucleotide is obtained over a large range (approximately 600 nucleotides with a 5% gel), simplifying the determination of DNA sequences considerably. Reliable sequences of 500 nucleotides can be read and sequence features up to greater than 1000 nucleotides are revealed in a single experiment. The sequencing of a potential Z-DNA-forming fragment from Escherichia coli DNA is given as an example and possible further developments are discussed.     

Measurement of the sequence specificity of covalent DNA modification by antineoplastic agents using Taq DNA polymerase.

A polymerase stop assay has been developed to determine the DNA nucleotide sequence specificity of covalent modification by antineoplastic agents using the thermostable DNA polymerase from Thermus aquaticus and synthetic labelled primers. The products of linear amplification are run on sequencing gels to reveal the sites of covalent drug binding. The method has been studied in detail for a number of agents including nitrogen mustards, platinum analogues and mitomycin C, and the sequence specificities obtained accord with those obtained by other procedures. The assay is advantageous in that it is not limited to a single type of DNA lesion (as in the piperidine cleavage assay for guanine-N7 alkylation), does not require a strand breakage step, and is more sensitive than other primer extension procedures which have only one cycle of polymerization. In particular the method has considerable potential for examining the sequence selectivity of damage and repair in single copy gene sequences in genomic DNA from cells.