A DNA cycle sequencing reaction that minimizes compressions on automated fluorescent sequencers.

We recently demonstrated that most band compressions (>70%) on DNA sequencing gels result from the presence of a single sequence motif, 5'-YGN1-2AR-3', where Y and R indicate base-pairing pyrimidine and purine residues, respectively. This finding raised the possibility that the use of 7-deaza-dATP instead of dATP in chain termination sequencing reactions would resolve most of the band compressions. Thus, we examined the effects of 7-deaza-dATP on DNA sequencing using thermostable DNA polymerases. The results indicate that the replacement of dATP with 7-deaza-dATP in conventional cycle sequencing reactions can successfully eliminate most band compressions without sacrificing sequencing performance.     

Development of an automated procedure for fluorescent DNA sequencing

We describe here the development of a procedure for complete automation of the dideoxynucleotide DNA sequencing chemistry using fluorescent dye-labeled oligonucleotide primers. This procedure combines rapid preparation of template DNA using a modification of the polymerase chain reaction, automation of the DNA sequencing reactions using a robotic laboratory workstation, and subsequent analysis of the fluorescent-labeled reaction products on a commercial automated fluorescent sequencer. Using this procedure, we were able to produce sufficient quantities of template DNA directly from bacterial colonies or bacteriophage plaques, perform the DNA sequencing reactions on these templates, and load the reaction products on the fluorescent DNA sequencer in a single work day. This scheme for automation of the fluorescent DNA sequencing method allows the fluorescent sequencer to be run at its full capacity every day and eliminates much of the labor required to obtain a high level of data output. Currently, we are able to perform and analyze 16 fluorescent-labeled reactions every day, with an average output of over 7000 bp per sequencer run.     

ASAP: an environment for automated preprocessing of sequencing data

Background

Next-generation sequencing (NGS) has yielded an unprecedented amount of data for genetics research. It is a daunting task to process the data from raw sequence reads to variant calls and manually processing this data can significantly delay downstream analysis and increase the possibility for human error. The research community has produced tools to properly prepare sequence data for analysis and established guidelines on how to apply those tools to achieve the best results, however, existing pipeline programs to automate the process through its entirety are either inaccessible to investigators, or web-based and require a certain amount of administrative expertise to set up.

Findings

Advanced Sequence Automated Pipeline (ASAP) was developed to provide a framework for automating the translation of sequencing data into annotated variant calls with the goal of minimizing user involvement without the need for dedicated hardware or administrative rights. ASAP works both on computer clusters and on standalone machines with minimal human involvement and maintains high data integrity, while allowing complete control over the configuration of its component programs. It offers an easy-to-use interface for submitting and tracking jobs as well as resuming failed jobs. It also provides tools for quality checking and for dividing jobs into pieces for maximum throughput.

Conclusions

ASAP provides an environment for building an automated pipeline for NGS data preprocessing. This environment is flexible for use and future development. It is freely available at http://biostat.mc.vanderbilt.edu/ASAP.     

Simple preparation method of PCR fragments for automated DNA sequencing

In an effort to find a simple and inexpensive purification method of polymerase chain reaction (PCR) reaction before cycle sequencing reaction, we compared a commercial system with a precipitation protocol performed in our laboratory. We found that, particularly with small PCR products, our method works with greater success than the method compared. Our precipitation method may be used on a larger PCR fragment before cycle sequencing reaction as well. Furthermore, it has the advantage of being simple as the well-known dilution method; in contrast to the dilution method, the precipitation method removes excess primers as well as possible primer dimers.     

AUDENS: a tool for automated peptide de novo sequencing

We present AUDENS, a new platform-independent open source tool for automated de novo sequencing of peptides from MS/MS data. We implemented a dynamic programming algorithm and combined it with a flexible preprocessing module which is designed to distinguish between signal and other peaks. By applying a user-defined set of heuristics, AUDENS screens through the spectrum and assigns high relevance values to putative signal peaks. The algorithm constructs a sequence path through the MS/MS spectrum using the peak relevances to score each suggested sequence path, i.e., the corresponding amino acid sequence. At present, we consider AUDENS a prototype that unfolds its biggest potential if used in parallel with other de novo sequencing tools. AUDENS is available open source and can be downloaded with further documentation at http://www.ti.inf.ethz.ch/pw/software/audens/ .     

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 cost-effective plasmid purification protocol suitable for fluorescent automated DNA sequencing

A cost-effective, reliable, and reproducible method has been developed to produce good-quality, double-stranded plasmid DNA for automated sequence analysis. The method incorporates modifications to a previously described plasmid-purification protocol used in manual sequencing. The quality of the DNA produced from the present protocol is suitable for automated fluorescent sequencing. Using a dye-terminator sequencing protocol, most runs using plasmid DNA prepared using this protocol produced over 700 bases with greater than 99% base-calling accuracy.     

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.     

A simple method for direct automated sequencing of PCR fragments.

A simple and rapid method for direct sequencing of PCR-generated fragments has been developed for use on Applied Biosystems 373A Automated DNA Sequencer utilizing the DyeDeoxy terminator chemistry. Standard PCR conditions are used to generate a DNA fragment, which is subsequently gel-purified to remove excess primers and unwanted PCR products. The sequencing reactions are carried out in a thermal cycler using the purified product as template DNA and the Dye-Deoxy terminators. The sequence of 500-bp region in the bacteriophage lambda genome and a 320-bp fragment of the human genomic erythropoietin gene were sequenced with greater than 99% accuracy using this method.     

A new, improved technique for automated sequencing of non-polar peptides

A method for the automated sequential degradation of non-polar peptides is reported. Both the polarity and film-forming properties of these peptides are increased by the attachment of 2-amino-1,5 napthalene disulfonic acid to the C-terminal residue via a water-soluble carbodiimide. The sequences of three individual peptides modified by the procedure are reported with high yields while these same peptides could not be successfully sequenced if no modification was made.     

Specific-primer-directed DNA sequencing using automated fluorescence detection.

Automated fluorescence-based DNA sequence analysis offers the possibility to undertake very large scale sequencing projects. Directed strategies, such as the specific-primer-directed sequencing approach ('gene walking'), should prove useful in such projects. Described herein is a study involving the use of this approach in conjunction with automated fluorescence detection on a commercial instrument (ABI 370A DNA sequencer). This includes procedures for the rapid chemical synthesis and purification of labeled primers, the design of primer sequences that are compatible with the commercial analysis software, and automated DNA sequence analysis using such primers. A set of four fluorophore-labeled primers can be reliably synthesized in a twenty-four hour period, and greater than 300 nucleotides of analyzed new sequence obtained using this set in an additional twenty-four hours. Scale-up of these procedures to take advantage of the full capabilities of the sequencer is, at present, too slow and costly to be suitable for routine sequencing, and therefore the use of specific-primers is best suited to the closure of gaps in extended sequence produced using random cloning and sequencing strategies.     

A simple and rapid preparation of M13 sequencing templates for manual and automated dideoxy sequencing.

A simple and rapid procedure for the preparation of M13 single stranded DNA sequencing templates which does not involve phenol extractions and alcohol precipitations is described. Bacteriophages are precipitated from media supernatants with acetic acid and recovered on glass fiber filters. Subsequent dissociation of the phages and removal of contaminants is performed while the DNA is bound to the glass. Finally, the purified DNA is eluted in a small volume of low-salt buffer. The yield is higher than that obtained by standard methods. The simplified procedure takes less than 30 minutes and does not demand special skills or equipment; the sequence resolution is as good as that obtained by standard procedures both with the Klenow fragment and T7 DNA polymerase, with radioactive labelling as well as in automated sequencing with a fluorescent label.     

Non-radioactive automated sequencing of oligonucleotides by chemical degradation

A non-radioactive sequencing of fluorescently labelled oligonucleotides by solid-phase chemical degradation is described. Although non-radioactive methods have been reported for the dideoxy chain termination technique, such a method has not yet been developed for the chemical degradation sequencing of DNA fragments. A 21-mer fluorescein labelled M13 sequencing primer was sequenced in an on-line automated system in about 30 minutes. The fluorescent dye and its bond to the oligonucleotide were stable during the chemical reactions used for the base specific degradations. As the sequence is determined on-line during electrophoresis, reloading and running 10 fragments simultaneously allows us to use one gel for sequencing of about 50 different oligonucleotides.     

An automated system for genome analysis to support microbial whole-genome shotgun sequencing

We developed a semi-automated genome analysis system called GAMBLER in order to support the current whole-genome sequencing project focusing on alkaliphilic Bacillus halodurans C-125. GAMBLER was designed to reduce the human intervention required and to reduce the complications in annotating thousands of ORFs in the microbial genome. GAMBLER automates three major routines: analyzing assembly results provided by genome assembler software, assigning ORFs, and homology searching. GAMBLER is equipped with an interface for convenience of annotation. All processes and options are manipulatable through a WWW browser that enables scientists to share their genome analysis results without choosing computer platforms.     

The use of tailed octamer primers for cycle sequencing.

Studies have been carried out on the use of octamer oligonucleotides tailed with different base analogues as primers in cycle sequencing reactions. 5-Nitroindole tails improved the performance as primers of a number of octamers. A tail length of three or four 5-nitroindole residues significantly increased the sequencing signal intensity for almost all primers. The use of incomplete libraries of tailed octamer primers for primer walking is discussed.     

Multiparametric cell cycle analysis by automated microscopy

Cell cycle analysis using flow cytometry (FC) to measure cellular DNA content is a common procedure in drug mechanism of action studies. Although this technique lends itself readily to cell lines that grow in suspension, adherent cell cultures must be resuspended in a cumbersome and potentially invasive procedure that normally involves trypsinization and mechanical agitation of monolayer cultures. High-content analysis (HCA), an automated microscopy-based technology, is well suited to analysis of monolayer cell cultures but provides intrinsically less accurate determination of cellular DNA content than does FC and thus is not the method of choice for cell cycle analysis. Using Cellomics's ArrayScan reader, the authors have developed a 4-color multiparametric HCA approach for cell cycle analysis of adherent cells based on detection of DNA content (4,6-diamidino-2-phenylindole [DAPI] fluorescence), together with the known cell cycle markers bromo-2-deoxyuridine (BrdU) incorporation, cyclin B1 expression, and histone H3 (Ser28) phosphorylation within a single cell population. Considering all 4 markers together, a reliable and accurate quantification of cell cycle phases was possible, as compared with flow cytometric analysis. Using this assay, specific cell cycle blocks induced by treatment with thymidine, paclitaxel, or nocodazole as test drugs were easily monitored in adherent cultures of U-2 OS osteosarcoma cells.