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.     

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.     

Direct sequencing of PCR-amplified DNA

This article describes the direct sequencing of PCR-amplified DNA, a technique that bypasses the problem of replication errors sometimes associated with other PCR procedures. The direct sequencing procedure produces an “average sequence” of all the copies of the target. Any miscopied molecule usually represents only a small proportion of the total. The technique described here is based on the “traditional” ddNTP sequencing method of Sanger et al.     

Single-base resolution analysis of DNA epigenome via high-throughput sequencing

Epigenetic changes caused by DNA methylation and histone modifications play important roles in the regulation of various cellular processes and development. Recent discoveries of 5-methylcytosine (5mC) oxidation derivatives including 5-hydroxymethylcytosine (5hmC), 5-formylcytsine (5fC) and 5-carboxycytosine (5caC) in mammalian genome further expand our understanding of the epigenetic regulation. Analysis of DNA modification patterns relies increasingly on sequencing-based profiling methods. A number of different approaches have been established to map the DNA epigenomes with single-base resolution, as represented by the bisulfite-based methods, such as classical bisulfite sequencing (BS-seq), TAB-seq (TET-assisted bisulfite sequencing), oxBS-seq (oxidative bisulfite sequencing) and etc. These methods have been used to generate base-resolution maps of 5mC and its oxidation derivatives in genomic samples. The focus of this review will be to discuss the chemical methodologies that have been developed to detect the cytosine derivatives in the genomic DNA.     

Commercial high-throughput sequencing and its applications in DNA analysis

DNA sequences can be used for the analysis of genetic variation and gene function. The high-throughput sequencing techniques that have been developed over the past three years can read as many as one billion bases per run, and are far less expensive than the traditional Sanger sequencing method. Therefore, the high-throughput sequencing has been applied extensively to genomic analyses, such as screening for mutations, construction of genomic methylation maps, and the study of DNA-protein interactions. Although they have only been available for a short period, high-throughput sequencing techniques are profoundly affecting many of the life sciences, and are opening out new potential avenues of research. With the highly-developed commercial high-throughput sequencing platforms, each laboratory has the opportunity to explore this research field. Therefore, in this paper, we have focused on commercially-popular high-throughput sequencing techniques and the ways in which they have been applied over the past three years.     

Direct sequencing of bacteriophage T4 DNA with a thermostable DNA polymerase

We present a simple and convenient protocol for the direct sequencing of bacteriophage T4 genomic DNA. The method utilizes the thermostable DNA polymerase from Thermus aquaticus (Taq) and 32P-end-labeled oligodeoxyribonucleotide primers to produce extension products that allow the analysis of at least 200 nucleotides (nt) on a single sequencing gel. Single-nt changes in the template were easily detectable following an overnight exposure of the autoradiograms. Comparison of sequences from fully modified T4 DNA containing glucosylated hydroxymethyldeoxycytosine or from templates containing cytosine showed little difference in sequence clarity. These techniques considerably simplify the molecular analysis of T-even bacteriophages and should be compatible with automated sequencing methods which employ 5'-end-labeled primers.     

THetA: inferring intra-tumor heterogeneity from high-throughput DNA sequencing data

Tumor samples are typically heterogeneous, containing admixture by normal, non-cancerous cells and one or more subpopulations of cancerous cells. Whole-genome sequencing of a tumor sample yields reads from this mixture, but does not directly reveal the cell of origin for each read. We introduce THetA (Tumor Heterogeneity Analysis), an algorithm that infers the most likely collection of genomes and their proportions in a sample, for the case where copy number aberrations distinguish subpopulations. THetA successfully estimates normal admixture and recovers clonal and subclonal copy number aberrations in real and simulated sequencing data. THetA is available at http://compbio.cs.brown.edu/software/.     

SUGAR: graphical user interface-based data refiner for high-throughput DNA sequencing

Background

Next-generation sequencers (NGSs) have become one of the main tools for current biology. To obtain useful insights from the NGS data, it is essential to control low-quality portions of the data affected by technical errors such as air bubbles in sequencing fluidics.

Results

We develop a software SUGAR (subtile-based GUI-assisted refiner) which can handle ultra-high-throughput data with user-friendly graphical user interface (GUI) and interactive analysis capability. The SUGAR generates high-resolution quality heatmaps of the flowcell, enabling users to find possible signals of technical errors during the sequencing. The sequencing data generated from the error-affected regions of a flowcell can be selectively removed by automated analysis or GUI-assisted operations implemented in the SUGAR. The automated data-cleaning function based on sequence read quality (Phred) scores was applied to a public whole human genome sequencing data and we proved the overall mapping quality was improved.

Conclusion

The detailed data evaluation and cleaning enabled by SUGAR would reduce technical problems in sequence read mapping, improving subsequent variant analysis that require high-quality sequence data and mapping results. Therefore, the software will be especially useful to control the quality of variant calls to the low population cells, e.g., cancers, in a sample with technical errors of sequencing procedures.     

Magnetic bead purification of labeled DNA fragments for high-throughput capillary electrophoresis sequencing

We have developed an automated purification method for dye-terminator-based DNA sequencing products using a magnetic bead approach. This 384-well protocol generates sequence fragments that are essentially free of template DNA, salt, and excess dye-terminator products. In comparison with traditional ethanol precipitation protocols, this method uses no centrifugation, is rapid, completely automated, and increases the phred-20 read length by an average of 40 bases. To date, we have processed over 4 million samples with 94% averaging 641 phred-20 bases on the MegaBACE 1000 and 4000 and the ABI PRISM 3700 capillary instruments.     

Direct sequencing of deleted mitochondrial DNA in myopathic patients

To investigate the mechanism of mitochondrial DNA deletion in human diseases, we amplified the deleted mitochondrial DNA of five patients with mitochondrial myopathy by using the polymerase chain reaction, and directly sequenced the crossover regions of the deleted mitochondrial DNA without cloning. In Patient 1, a 7-bp directly repeated sequence of 5'-ATCCCCA-3' was found at the boundaries of deleted segment spanning 7,039 bp between the ATPase 6 and the cytochrome b genes. In Patients 2, 3, and 4, a 13-bp sequence of 5'-ACCTCCCTCACCA-3' was found in the boundaries of deleted segment spanning 4,977 bp between the ATPase 8 and the ND5 genes. In Patient 5, a 3-bp sequence of 5'-CCT-3' was found in the boundaries of deleted segment spanning 3,717 bp between the ATPase 6 and the ND5 genes. Similar directly repeated sequences may contribute to mitochondrial DNA deletions in human degenerative diseases.     

Direct sequencing of unpurified PCR-amplified DNA by semi-exponential cycle sequencing (SECS)

A simple technique for direct sequencing of PCR-amplified templates without purification of the PCR reaction product is presented. This method does not require an additional synthesis step after template amplification, and can generate sequence information form as little as 0.1 fmol of unpurified template.     

An automated instrument for the performance of enzymatic DNA sequencing reactions

An instrument has been developed for the automation of enzymatic DNA sequencing reactions. Up to 96 DNA templates contained in a microtiter plate can be processed for either radioactive or fluorescence-based sequence analysis in a three-hour period. The quality of the resultant data is comparable to that obtained manually. The system is simple, flexible and is readily adapted to the use of new polymerases or modified experimental protocols.     

Direct mutation analysis by high-throughput sequencing: from germline to low-abundant, somatic variants

DNA mutations are the source of genetic variation within populations. The majority of mutations with observable effects are deleterious. In humans mutations in the germ line can cause genetic disease. In somatic cells multiple rounds of mutations and selection lead to cancer. The study of genetic variation has progressed rapidly since the completion of the draft sequence of the human genome. Recent advances in sequencing technology, most importantly the introduction of massively parallel sequencing (MPS), have resulted in more than a hundred-fold reduction in the time and cost required for sequencing nucleic acids. These improvements have greatly expanded the use of sequencing as a practical tool for mutation analysis. While in the past the high cost of sequencing limited mutation analysis to selectable markers or small forward mutation targets assumed to be representative for the genome overall, current platforms allow whole genome sequencing for less than $5000. This has already given rise to direct estimates of germline mutation rates in multiple organisms including humans by comparing whole genome sequences between parents and offspring. Here we present a brief history of the field of mutation research, with a focus on classical tools for the measurement of mutation rates. We then review MPS, how it is currently applied and the new insight into human and animal mutation frequencies and spectra that has been obtained from whole genome sequencing. While great progress has been made, we note that the single most important limitation of current MPS approaches for mutation analysis is the inability to address low-abundance mutations that turn somatic tissues into mosaics of cells. Such mutations are at the basis of intra-tumor heterogeneity, with important implications for clinical diagnosis, and could also contribute to somatic diseases other than cancer, including aging. Some possible approaches to gain access to low-abundance mutations are discussed, with a brief overview of new sequencing platforms that are currently waiting in the wings to advance this exploding field even further.     

Direct DNA sequencing of PCR amplified genomic DNA by the Maxam-Gilbert method

We present a method to directly sequence PCR amplification products utilizing the chemical method of Maxam and Gilbert. This procedure yields clearly readable DNA sequences of 100-400 base pairs in length derived from human genomic DNA in four days' time.     

DNA sequencing using rolling circle amplification and precision glass syringes in a high-throughput liquid handling system

An automated high-throughput method that employs rolling circle amplification (RCA) to generate template for large-scale DNA sequencing has been developed using liquid handling systems equipped with precision glass syringes. A protocol was designed to perform the sequencing analysis from template preparation to thermal cycle sequencing within the same vessel, thus minimizing the amount of liquid handling and transfer. The amplified DNA was directly used for cycle sequencing with no need for any purification procedures. Total RCA reaction volumes as low as 500 nL generated sufficient templates for successful sequencing. Reducing the RCA total reaction volumes by a 40-fold factor, from a total of 20 microL to 500 nL, resulted in a significant reduction in cost, from $1.25/reaction to less than $0.04/reaction. Additionally, the volume of the sequencing reactions was reduced from a total of 20 to 10 microL, thus generating a further cost advantage. This high-throughput DNA sequencing protocol maximizes the speed and precision of processing while significantly reducing the cost of amplification.