An efficient, automatable template preparation for high throughput sequencing

We have developed a 96-well format for DNA template isolation that can be readily automatable. The template isolation protocol involves simple alkaline lysis chemistry and reversible capture on a silica solid phase. After the cells are lysed, no centrifugation is necessary, as lysate purification, DNA binding, washing, and release occur in 96-well filter plates. Large numbers of templates prepared using the silica purification method have been sequenced and analyzed. The quality of sequence resulting from our method has been compared with that generated from several commercial plasmid preparation protocols. We found sequence quality of the silica bead preparations to be equivalent to or, in some cases, better than those prepared by other methods. This method offers many advantages over other protocols we have used. First, the silica purifications have allowed us to more than double overall laboratory throughput while decreasing our template isolation materials cost at least five-fold. Second, because we have eliminated all centrifugation steps in the protocol, automation has been much simpler. The protocol has also been adapted to purify PCR products for use as templates in subsequent sequencing reactions.     

Capillary DNA Sequencing: Maximizing the Sequence Output

Like most other DNA sequencing core facilities, one of our continuing goals is to improve our sequence output without substantially adding to cost. To minimize sample-to-sample variability in template DNA concentration, we implemented the rolling circle amplification (RCA) procedure for preparing our DNA templates. In addition to saving time and reducing the number of steps in template DNA preparation, the RCA method has the potential to normalize the DNA concentration in samples that can be sequenced directly without additional purification. In the present study, we used RCA-generated templates to test a recently reported procedure that increased sequence quality by resuspending the sequenced products in low concentrations of agarose before capillary electrophoresis (CE) on a MegaBACE 1000 platform. Although we did not obtain the expected result using the specified procedure, a modification resulted in up to 60% increase in total sequence yield per sample plate. A combination of agarose and formamide-EDTA in the resuspension solution enabled us to generate long-read and high-quality sequences for more than 38,000 templates with minimal additional cost.     

Resuspension of DNA sequencing reaction products in agarose increases sequence quality on an automated sequencer

We are investigating approaches to increase DNA sequencing quality. Since a majorfactor in sequence generation is the cost of reagents and sample preparations, we have developed and optimized methods to sequence directly plasmid DNA isolated from alkaline lysis preparations. These methods remove the costly PCR and post-sequencing purification steps but can result in low sequence quality when using standard resuspension protocols on some sequencing platforms. This work outlines a simple, robust, and inexpensive resuspension protocol for DNA sequencing to correct this shortcoming. Resuspending the sequenced products in agarose before electrophoresis results in a substantial and reproducible increase in sequence quality and read length over resuspension in deionized water and has allowed us to use the aforementioned sample preparation methods to cut considerably the overall sequencing costs without sacrificing sequence quality. We demonstrate that resuspension of unpurified sequence products generated from template DNA isolated by a modified alkaline lysis technique in low concentrations of agarose yields a 384% improvement in sequence quality compared to resuspension in deionized water. Utilizing this protocol, we have produced more than 74,000 high-quality, long-read-length sequences from plasmid DNA template on the MegaBACET 1000 platform.     

Microcapillary reactors using solid-phase DNA sequencing for direct sample introduction into slab gels

Solid-phase micro-reactors have been prepared in glass capillaries for DNA sequencing applications using slab gel electrophoresis, which consisted of a fused silica capillary (i.d. = 100 microns; o.d. = 365 microns; length = 15 cm; volume = 1.2 microL) that contained a covalently bound biotin molecule. With the addition of streptavidin to the capillary, an anchoring site was produced for the tethering of biotinylated DNA sequencing templates to the wall of the capillary. Using a four-lane, single dye primer chemistry sequencing strategy, the individual tracts were prepared in the capillaries using cycle sequencing (20 thermal cycles) on a PCR-generated lambda-bacteriophage template (about 1000 bp). The dye label in this case was a fluorescent tag that displayed emission properties in the near-IR and could be processed on an automated sequencer. The read length was found to be 589 bases, which was determined primarily by the fractionating power of the gel. It was also found that the tethering system was very stable to typical cycle sequencing conditions, with the amount of tethered DNA lost amounting to 40% after 120 thermal cycles. The ability to use dye terminator chemistry was also investigated by using a near-IR dye-labeled terminator (ddGTP). It was found that the quality of the ladder that was generated was comparable to that obtained in a conventional sample preparation format. However, ethanol precipitation was required before gel loading to remove excess terminator.     

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.     

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.     

CircumVent thermal cycle sequencing and alternative manual and automated DNA sequencing protocols using the highly thermostable VentR (exo-) DNA polymerase.

CircumVent thermal cycle and standard DNA sequencing protocols utilizing the cloned and highly thermostable VentR (exo-) DNA polymerase are described. The thermal cycle sequencing procedures are advantageous because they allow fast and simple semiautomation of the sequencing reaction; make possible the direct DNA sequencing of PCR products, bacterial colonies and phage plaques; require only femtomoles of template DNA; eliminate the requirement of an independent primer annealing step; remove the requirement of denatured plasmids for sequencing double-stranded templates; and use a highly thermostable DNA polymerase for sequencing through potential recalcitrant secondary structure domains and large linear double-stranded DNA templates such as lambda derivatives. More standard methods of DNA sequencing (i.e., a one-step protocol and a labeling-termination protocol) are also presented. For each protocol, alternatives for choice of label and method of labeling are presented, including the use of 5' biotinylated primers for chemiluminescent DNA sequencing and fluorinated primers for automated sequencing using the BaseStation Automated DNA Sequencer.     

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.     

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.     

Automated template quantification for DNA sequencing facilities.

The quantification of plasmid DNA by the PicoGreen dye binding assay has been automated, and the effect of quantification of user-submitted templates on DNA sequence quality in a core laboratory has been assessed. The protocol pipets, mixes and reads standards, blanks and up to 88 unknowns, generates a standard curve, and calculates template concentrations. For pUC19 replicates at five concentrations, coefficients of variance were 0.1, and percent errors were from 1% to 7% (n=198). Standard curves with pUC19 DNA were nonlinear over the 1 to 1733 ng/microL concentration range required to assay the majority (98.7%) of user-submitted templates. Over 35,000 templates have been quantified using the protocol. For 1350 user-submitted plasmids, 87% deviated by >or=20% from the requested concentration (500 ng/microL). Based on data from 418 sequencing reactions, quantification of user-submitted templates was shown to significantly improve DNA sequence quality. The protocol is applicable to all types of double-stranded DNA, is unaffected by primer (1 pmol/microL), and is user modifiable. The protocol takes 30 min, saves 1 h of technical time, and costs approximately $0.20 per unknown.     

Direct sequencing of terminal regions of genomic P1 clones: A general strategy for the design of sequence-tagged site markers

A method for the preparation of P1 DNA is presented, which allows the direct sequencing of ends of inserts in genomic P1 clones using the Applied Biosystems 373A DNA Sequencer and the Dye Terminator sequencing methodology. We surveyed several common methods of DNA preparation including alkaline lysis, Triton-lysozyme lysis, CsCl density-gradient purification, and a commercial column matrix DNA purification kit manufactured by Qiagen. We found that a modified alkaline lysis preparation of P1 DNA was most successful for generating P1 DNA that could be sequenced directly. We also noted that the host bacterial strain from which the P1 DNA was purified dramatically affected the quality of sequencing templates. The bacterial strains NS3145 and NS3529, in which the Drosophila melanogaster and human P1 genomic libraries are harbored, routinely yielded poor-quality sequencing templates. However, the bacterial strain DH10B routinely yielded P1 DNA that was sequenced successfully. A bacterial mating scheme is presented that exploits γδ transposition events to allow the transfer of P1 clones from the library host strain to DH10B. Using either an SP6 or a T7 primer, an average of 350 base pairs of DNA sequence was obtained with an uncalled base frequency of ∼2%. About 4% of P1 end sequences generated corresponded to unique Drosophila loci present in the Genbank database. These single-pass DNA sequences were used to design sequence-tagged site markers for physical mapping studies in both humans and Drosophila.     

Rapid and reliable fluorescent cycle sequencing of double-stranded templates.

Automated DNA sequencing is an extremely valuable technique which requires very high quality DNA templates to be carried out successfully. While it has been possible to readily produce large numbers of such templates from M13 or other single-stranded vectors for several years, the sequencing of double-stranded DNA templates using the ABI 373 DNA Sequencer has had a considerably lower success rate. We describe how the combination of a new fluorescent, dideoxy sequencing method, called cycle-sequencing, coupled with modifications to template isolation procedures based on Qiagen columns, makes fluorescent sequencing of double-stranded templates a reliable procedure. From a single five milliliter culture enough DNA can be isolated (up to 20 micrograms) to do 4-8 sequencing reactions, each of which yields 400-500 bases of high quality sequence data. These procedures make the routine use of double-stranded DNA templates a viable strategy in automated DNA sequencing projects.     

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.     

On-line integration of PCR and cycle sequencing in capillaries: from human genomic DNA directly to called bases

A fully integrated system has been developed for genetic analysis based on direct sequencing of polymerase chain reaction (PCR) products. The instrument is based on a serially connected fused-silica capillary assembly. The technique involves the use of microreactors for small-volume PCR and for dye-terminator cycle-sequencing reaction, purification of the sequencing fragments, and separation of the purified DNA ladder. Four modifications to the normal PCR protocol allow the elimination of post-reaction purification. The use of capillaries as reaction vessels significantly reduced the required reaction time. True reduction in reagent cost is achieved by a novel sample preparation procedure where nanoliter volumes of templates and sequencing reaction reagent are mixed using a micro- syringe pump. The remaining stock solution of sequencing reaction reagent can be reused without contamination. The performance of the whole system is demonstrated by one-step sequencing of a specific 257-bp region in human chromosome DNA. Base calling for the smaller fragments is limited only by the resolving power of the gel. The system is simple, reliable and fast. The entire process from PCR to DNA separation is completed in ~4 h. Feasibilities for development of a fully automated sequencing system in the high-throughput format and future adaptation of this concept to a microchip are discussed.     

Formation of Template-Switching Artifacts by Linear Amplification

Linear amplification is a method of synthesizing single-stranded DNA from either a single-stranded DNA or one strand of a double-stranded DNA. In this protocol, molecules of a single primer DNA are extended by multiple rounds of DNA synthesis at high temperature using thermostable DNA polymerases. Although linear amplification generates the intended full-length single-stranded product, it is more efficient over single-stranded templates than double-stranded templates. We analyzed linear amplification over single- or double-stranded mouse H-ras DNA (exon 1–2 region). The single-stranded H-ras template yielded only the intended product. However, when the double-stranded template was used, additional artifact products were observed. Increasing the concentration of the double-stranded template produced relatively higher amounts of these artifact products. One of the artifact DNA bands could be mapped and analyzed by sequencing. It contained three template-switching products. These DNAs were formed by incomplete DNA strand extension over the template strand, followed by switching to the complementary strand at a specific Ade nucleotide within a putative hairpin sequence, from which DNA synthesis continued over the complementary strand.     

Overcoming a barrier for DNA polymerization in triplex-forming sequences.

Folded structures in the DNA template, such as hairpins and multi-stranded structures, often serve as pause and arrest sites for DNA polymerases. DNA polymerization is particularly difficult on mirror-repeated homopurine.homopyrimidine templates where triple-stranded (triplex) structures may form between the nascent and folded template strands. In order to use a linear PCR amplification approach for the structural analysis of DNA in mirror-repeated sequences we modified a conventional protocol. The barrier for DNA synthesis can be eliminated using an oligonucleotide that hybridizes with the template to prevent its folding and is subsequently displaced by the progressing polymerase. The described approach is potentially useful for sequencing and analysis of chemical adducts and point mutations in a variety of sequences prone to the formation of folded structures, such as long hairpins and quadruplexes.     

Large scale sequencing projects using rapidly prepared double-stranded plasmid DNA.

We have developed a simple rapid plasmid DNA mini-preparation method which yields DNA of sufficient quality to be used in large scale sequencing projects. The method, which is a modification of the alkaline method of Birnboim and Doly (1979), requires less than two hours. We have eliminated the use of organic extractions, RNase digestion and alkaline denaturation of the DNA for annealing of the primer. The proportion of supercoiled plasmid DNA obtained is close to 100%. Greater than 80% of the clones yield at least 500 bp of sequence information per primer. The sequencing reactions from these double-stranded templates can be done on both strands using the universal and reverse sequence primers with the usual two reactions per primer, one to read close to the primer and one to read far from it. Thus, each clone yields at least 1 kb of sequence information. The preparation of the templates and the sequencing reactions can be done in less than three hours so that the sequencing gel can be run the same day.     

Chitosan functionalized magnetic particle-assisted detection of genetically modified soybeans based on polymerase chain reaction and capillary electrophoresis

The high quality of DNA template is one of the key factors to ensure the successful execution of polymerase chain reaction (PCR). Therefore, development of DNA extraction methods is very important. In this work, chitosan modified magnetic particles (MPs) were synthesized and employed for extraction of genomic DNA from genetically modified (GM) soybeans. The extraction protocol used aqueous buffers for DNA binding to and releasing from the surface of the MPs based on the pH inducing the charge switch of amino groups in chitosan modified MPs. The extracted DNA was pure enough (A(260)/A(280)=1.85) to be directly used as templates for PCR amplification. In addition, the PCR products were separated by capillary electrophoresis for screening of GM organisms. The developed DNA extraction method using chitosan modified MPs was capable of preparation of DNA templates, which were PCR inhibitor free and ready for downstream analysis. The whole process for DNA extraction and detection was preferable to conventional methods (phenol-chloroform extraction, PCR, and gel electrophoresis) due to its simplicity and rapidity as well as its avoiding the use of toxic reagents and PCR inhibitors.     

Rapid determination of short DNA sequences by the use of MALDI-MS

We have developed a protocol for rapid sequencing of short DNA stretches (15–20 nt) using MALDI-TOF-MS. The protocol is based on the Sanger concept with the modification that double-stranded template DNA is used and all four sequencing reactions are performed in one reaction vial. The sequencing products are separated and detected by MALDI-TOF-MS and the sequence is determined by comparing measured molecular mass differences to expected values. The protocol is optimized for low costs and broad applicability. One reaction typically includes 300 fmol template, 10 pmol primer and 200 pmol each nucleotide monomer. Neither the primer nor any of the nucleotide monomers are labeled. Solid phase purification, concentration and mass spectrometric sample preparation of the sequencing products are accomplished in a few minutes and parallel processing of 96 samples is possible. The mass spectrometric analyses and subsequent sequence read-out require only a few seconds per template.     

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.