DNA sequencing by primer walking with strings of contiguous hexamers

Multiplexed Assembly and Annotation of Synthetic Biology Constructs Using Long-Read Nanopore Sequencing

Recombinant DNA is a fundamental tool in biotechnology and medicine. These DNA sequences are often built, replicated, and delivered in the form of plasmids. Validation of these plasmid sequences is a critical and time-consuming step, which has been dominated for the last 35 years by Sanger sequencing. As plasmid sequences grow more complex with new DNA synthesis and cloning techniques, we need new approaches that address the corresponding validation challenges at scale. Here we prototype a high-throughput plasmid sequencing approach using DNA transposition and Oxford Nanopore sequencing. Our method, Circuit-seq, creates robust, full-length, and accurate plasmid assemblies without prior knowledge of the underlying sequence. We demonstrate the power of Circuit-seq across a wide range of plasmid sizes and complexities, generating full-length, contiguous plasmid maps. We then leverage our long-read data to characterize epigenetic marks and estimate plasmid contamination levels. Circuit-seq scales to large numbers of samples at a lower per-sample cost than commercial Sanger sequencing, accelerating a key step in synthetic biology, while low equipment costs make it practical for individual laboratories.

Identification of a new adhesin-like protein from Lactobacillus mucosae ME-340 with specific affinity to the human blood group A and B antigens

AIMS

To identify and characterize a new adhesin-like protein of probiotics that show specific adhesion to human blood group A and B antigens.

METHODS AND RESULTS

Using the BIACORE assay, the adhesion of cell surface components obtained from four lactobacilli strains that adhered to blood group A and B antigens was tested. Their components showed a significant adhesion to A and B antigens when compared to the bovine serum albumin (BSA) control. The 1 mol l(-1) GHCl fraction extracted from Lactobacillus mucosae ME-340 contained a 29-kDa band (Lam29) using SDS-PAGE. The N-terminal amino acid sequence and homology analysis showed that Lam29 was 90% similar to the substrate-binding protein of the ATP-binding cassette (ABC) transporter from Lactobacillus fermentum IFO 3956. The complete nucleotide sequence (858 bp) of Lam29 was determined and encoded a protein of 285 amino acid residues. Phylogenetic analysis and multiple sequence alignments indicated this protein may be related to the cysteine-binding transporter.

CONCLUSIONS

The adhesion of ME-340 strain to blood group A and B antigens was mediated by Lam29 that is a putative component of ABC transporter as an adhesin-like protein.

SIGNIFICANCE AND IMPACT OF THE STUDY

Lactobacillus mucosae ME-340 expressing Lam29 may be useful for competitive exclusion of pathogens via blood group antigen receptors in the human gastrointestinal mucosa and in the development of new probiotic foods.

Primer fabrication using polymerase mediated oligonucleotide synthesis

Background

Custom solid phase oligonucleotide synthesis is an important foundation supporting nearly every aspect of current genomics. In spite of the demand for oligonucleotide primers, their synthesis remains relatively expensive, time consuming and in many circumstances a wasteful process. In this methodology, described as polymerase mediated oligonucleotide synthesis (PMOS), a DNA polymerase is used to increase the hybridization affinity of one oligonucleotide by using another as a template for DNA synthesis. This self-assembly process provides an opportunity to instantly generate a very large number of useful gene-specific primers from a small library of simple precursors. PMOS can be used to generate primers directly in the end-users laboratory within the context of any DNA polymerase chemistry such as in PCR or sequencing reactions

Results

To demonstrate the utility of PMOS, a universal 768-member oligonucleotide library (UniSeq) was designed, fabricated and its performance optimized and evaluated in a range of PCR and DNA sequencing reactions. This methodology used to derive specific 11-mers, performed well in each of these activities and produced the desired amplification or sequencing analysis with results comparable to primers made by time consuming and expensive custom synthesis.

Conclusion

On the basis of these experiments, we believe this novel system would be broadly applicable and could in many circumstances replace the need for conventional oligonucleotide synthesis.

Cell surface Lactobacillus plantarum LA 318 glyceraldehyde-3-phosphate dehydrogenase (GAPDH) adheres to human colonic mucin

AIMS

To characterize the adhesion molecule of Lactobacillus plantarum LA 318 that shows high adhesion to human colonic mucin (HCM).

METHODS AND RESULTS

The adhesion test used the BIACORE assay where PBS-washed bacterial cells showed a significant decrease in adherence to HCM than distilled water-washed cells. A component in the PBS wash fraction adhered to the HCM and a main protein was detected as a c. 40-kDa band using SDS-PAGE. Using homology comparisons of the N-terminal amino acid sequences compared with sequence databases, this protein was identified as glyceraldehyde-3-phosphate dehydrogenase (GAPDH). The DNA sequence of LA 318 GAPDH was 100% identical to the GAPDH (gapB) of L. plantarum WCFS1. The purified GAPDH adhered to HCM.

CONCLUSIONS

We found the adhesin of L. plantarum LA 318 to HCM in its culture PBS wash fraction. The molecule was identified as GAPDH. Because LA 318 possesses the same adhesin as many pathogens, the lactobacilli GAPDH may compete with pathogens infecting the intestine.

SIGNIFICANCE AND IMPACT OF THE STUDY

This is the first report showing GAPDH expressed on the cell surface of lactobacilli adheres to mucin suggesting L. plantarum LA 318 adheres to HCM using GAPDH binding activity to colonize the human intestinal mucosa.

Long PCR Product Sequencing (LoPPS): a shotgun-based approach to sequence long PCR products

Here we describe a practical procedure for sequencing long PCR products. The method relies on ultrasonic shearing of PCR products, resulting in fragments 700-1,000 nt long. Termini are subsequently repaired to obtain blunt ends and 3' A-overhangs are added before TA cloning. A predetermined number of clones are sequenced using an insert-independent primer to obtain an overlapping contig covering the full length of the PCR product. This method is cost effective and enables the complete sequencing of any large PCR product in a high-throughput format. Processing of amplified DNA requires 3 h handling time prior to the ligation step, and the clone library is available 2 d later. The complete sequence information is obtained approximately 5 d after the PCR step, depending on the sequencing procedure adopted.

Lateral flow microarrays: a novel platform for rapid nucleic acid detection based on miniaturized lateral flow chromatography

Widely used nucleic acid assays are poorly suited for field deployment where access to laboratory instrumentation is limited or unavailable. The need for field deployable nucleic acid detection demands inexpensive, facile systems without sacrificing information capacity or sensitivity. Here we describe a novel microarray platform capable of rapid, sensitive nucleic acid detection without specialized instrumentation. The approach is based on a miniaturized lateral flow device that makes use of hybridization-mediated target capture. The miniaturization of lateral flow nucleic acid detection provides multiple advantages over traditional lateral flow devices. Ten-microliter sample volumes reduce reagent consumption and yield analyte detection times, excluding sample preparation and amplification, of <120 s while providing sub-femtomole sensitivity. Moreover, the use of microarray technology increases the potential information capacity of lateral flow. Coupled with a hybridization-based detection scheme, the lateral flow microarray (LFM) enables sequence-specific detection, opening the door to highly multiplexed implementations for broad-range assays well suited for point-of-care and other field applications. The LFM system is demonstrated using an isothermal amplification strategy for detection of Bacillus anthracis, the etiologic agent of anthrax. RNA from as few as two B. anthracis cells was detected without thermocycling hardware or fluorescence detection systems.

Pyrosequencing: history, biochemistry and future

BACKGROUND

Pyrosequencing is a DNA sequencing technology based on the sequencing-by-synthesis principle.

METHODS

The technique is built on a 4-enzyme real-time monitoring of DNA synthesis by bioluminescence using a cascade that upon nucleotide incorporation ends in a detectable light signal (bioluminescence). The detection system is based on the pyrophosphate released when a nucleotide is introduced in the DNA-strand. Thereby, the signal can be quantitatively connected to the number of bases added. Currently, the technique is limited to analysis of short DNA sequences exemplified by single-nucleotide polymorphism analysis and genotyping. Mutation detection and single-nucleotide polymorphism genotyping require screening of large samples of materials and therefore the importance of high-throughput DNA analysis techniques is significant. In order to expand the field for pyrosequencing, the read length needs to be improved.

CONCLUSIONS

Th pyrosequencing system is based on an enzymatic system. There are different current and future applications of this technique.

DNA sequencing by indexer walking

BACKGROUND

There is a need for DNA sequencing methods that are faster, more accurate, and less expensive than existing techniques. Here we present a new method for DNA analysis by means of indexer walking.

METHODS

For DNA sequencing by indexer walking, we ligated double-stranded synthetic oligonucleotides (indexers) to DNA fragments that were produced by type IIS restriction endonucleases, which generate nonidentical 4-nucleotide 5' overhangs. The subsequent amplification (30 thermal cycles) of indexed DNA provided a template for automated DNA sequencing with fluorescent dideoxy terminators. The data gathered in the first sequencing reaction permitted further movement into the unknown nucleotide sequence by digestion of analyzed DNA with selected type IIS restriction endonuclease followed by ligation of the next indexer. A library of presynthesized indexers consisting of 256 oligonucleotides was used for bidirectional analysis of DNA molecules and provided universal primers for sequencing.

RESULTS

The proposed protocol was successfully applied to sequencing of cryptic plasmids isolated from pathogenic strains of Escherichia coli. The overall error rate for base-calling was 0.5%, with a mean read length of 550 nucleotides. Approximately 1000 nucleotides of high-quality sequence could be obtained per day from a single clone.

CONCLUSIONS

Indexer walking can be used as a low-cost procedure for nucleotide sequence determination of DNA molecules, such as natural plasmids, cDNA clones, and longer DNA fragments. It can also serve as an alternative method for gap filling at the final stage of genome sequencing projects.

The Thermodynamics of DNA Structural Motifs

DNA secondary structure plays an important role in biology, genotyping diagnostics, a variety of molecular biology techniques, in vitro-selected DNA catalysts, nanotechnology, and DNA-based computing. Accurate prediction of DNA secondary structure and hybridization using dynamic programming algorithms requires a database of thermodynamic parameters for several motifs including Watson-Crick base pairs, internal mismatches, terminal mismatches, terminal dangling ends, hairpins, bulges, internal loops, and multibranched loops. To make the database useful for predictions under a variety of salt conditions, empirical equations for monovalent and magnesium dependence of thermodynamics have been developed. Bimolecular hybridization is often inhibited by competing unimolecular folding of a target or probe DNA. Powerful numerical methods have been developed to solve multistate-coupled equilibria in bimolecular and higher-order complexes. This review presents the current parameter set available for making accurate DNA structure predictions and also points to future directions for improvement.

Effect of unlabeled helper probes on detection of an RNA target by bead-based sandwich hybridization

Unlabeled helper oligonucleotides assisting a bead-based sandwich hybridization assay were tested for the optimal placement of the capture and detection probes. The target used was a full-length in vitro synthesized mRNA molecule. Helper probes complementary to regions adjacent to the binding site of the 5′ end attached capture probe were found much more effective than helper probes targeting positions adjacent to the detection probe binding site. The difference is believed to be caused by a disruption of the RNA secondary structure in the area where the capture probe binds, thereby reducing structural interference from the bead. The use of additional helpers showed an additive effect. Using helpers at both sides of the capture and detection probes showed a 15- to 40-fold increase in hybridization efficiency depending on the target, thereby increasing the sensitivity of the hybridization assays. Using an electrical chip linked to the detection probe for the detection of p-aminophenol, which is produced by alkaline phosphatase, a detection limit of 2 × 10−13 M mRNA molecules was reached without the use of a nucleic acid amplification step.

LNA-enhanced detection of single nucleotide polymorphisms in the apolipoprotein E

Genotyping of single nucleotide polymorphisms (SNPs) in large populations presents a great challenge, especially if the SNPs are embedded in GC-rich regions, such as the codon 112 SNP in the human apolipoprotein E (apoE). In the present study, we have used immobilized locked nucleic acid (LNA) capture probes combined with LNA-enhancer oligonucleotides to obtain efficient and specific interrogation of SNPs in the apoE codons 112 and 158, respectively. The results demonstrate the usefulness of LNA oligonucleotide capture probes combined with LNA enhancers in mismatch discrimination. The assay was applied to a panel of patient samples with simultaneous genotyping of the patients by DNA sequencing. The apoE genotyping assays for the codons 112 and 158 SNPs resulted in unambiguous results for all patient samples, concurring with those obtained by DNA sequencing.

Escherichia coli single-stranded DNA-binding protein, a molecular tool for improved sequence quality in pyrosequencing

Pyrosequencing is a four-enzyme bioluminometric DNA sequencing technique based on a DNA sequencing by synthesis principle. Currently, the technique is limited to analysis of short DNA sequences exemplified by single-nucleotide polymorphism analysis. In order to expand the field for pyrosequencing, the read length needs to be improved and efforts have been made to purify reaction components as well as add single-stranded DNA-binding protein (SSB) to the pyrosequencing reaction. In this study, we have performed a systematic effort to analyze the effects of SSB by comparing the pyrosequencing result of 103 independent complementary DNA (cDNA) clones. More detailed information about the cause of low quality sequences on templates with different characteristics was achieved by thorough analysis of the pyrograms. Also, real-time biosensor analysis was performed on individual cDNA clones for investigation of primer annealing and SSB binding on these templates. Results from these studies indicate that templates with high performance in pyrosequencing without SSB possess efficient primer annealing and low SSB affinity. Alternative strategies to improve the performance in pyrosequencing by increasing the primer-annealing efficiency have also been evaluated.

Thermodynamic analysis of stacking hybridization of oligonucleotides with DNA template

Contiguous stacking hybridization of oligodeoxyribonucleotides with DNA as template was investigated using three types of complexes: oligonucleotide contiguously stacked with the stem of the preformed minihairpin (complexes I), oligonucleotide tandems containing two (complexes II) or three (complexes III) short oligomers with a common DNA template. Enthalpy Delta H degrees and entropy Delta S degrees of the coaxial stacking of adjacent duplexes were determined for GC/G*pC, GT/A*pC, AC/G*pT, AT/A*pT, CT/A*pG, AG/C*pT, AA/T*pT and TT/A*pA nicked (*) dinucleotide base pairs. The maximal efficiency of co-operative interaction was found for the GC/G*pC interface (Delta G degrees(NN/N*pN)=-2.7 kcal/mol) and the minimal one for the AA/T*pT interface (Delta G degrees(NN/N*pN)=-1.2 kcal/mol) at 37 degrees C. As a whole, the efficiency of the base pairs interaction Delta G degrees(NN/N*pN) in the nick is not lower than that within the intact DNA helix (Delta G degrees(NN/NN)). These observed Delta G degrees(NN/N*pN) values are proposed may include the effect of the partial removal of fraying at the adjacent helix ends additionally to the effect of the direct stacking of the terminal base pairs in the duplex junction (Delta G degrees(NN/NN). The thermodynamic parameters have been found to describe adequately the formation of all tandem complexes of the II and III types with oligonucleotides of various length and hybridization properties. The performed thermodynamic analysis reveals features of stacking oligonucleotide hybridization which allow one to predict the temperature dependence of association of oligonucleotides and the DNA template within tandem complexes as well as to determine optimal concentration for formation of these complexes characterized by high co-operativity level.

Overexpression, rapid isolation, and biochemical characterization of Escherichia coli single-stranded DNA-binding protein

Escherichia coli (E. coli) single-stranded binding protein (SSB) is a valuable protein for various biotechnical applications, such as PCR and DNA sequencing. Here we describe an efficient expression and purification scheme where the tendency of SSB to aggregate at low salt concentration and high protein concentration is avoided. The method contains fewer steps of purification and results in high protein yield, compared to previous published protocols. In our protocol, cells are harvested after cultivation overnight and SSB is isolated by ammonium sulfate precipitation followed by anion-exchange chromatography. The yield from a 2-liter fed-batch fermentor is 2 g protein, which is higher than all production methods for SSB earlier reported. Moreover, the two classical isolation steps combined in the purification scheme are robust, cost-efficient, and suitable for scaling up. The resulting SSB is pure and a correctly folded tetramer with an apparent binding to single-stranded DNA with a K(D) of 10(-8) M, as determined by surface plasmon resonance.

Improved performance of pyrosequencing using single-stranded DNA-binding protein

In modern biology, there is a critical need to develop a high-throughput and inexpensive platform for DNA sequencing. Pyrosequencing is a nonelectrophoretic single-tube DNA sequencing method that takes advantage of cooperativity between four enzymes to monitor DNA synthesis. In these studies, single-stranded DNA-binding protein (SSB) was added to the primed DNA template prior to the Pyrosequencing reaction. The addition of SSB to a Pyrosequencing reaction system resulted in a read length of more than 30 nucleotides. Improvements were observed as: (i) increased efficiency of the enzymes, (ii) reduced mispriming, as measured by nonspecific signals, (iii) an increase in signal intensity during the reaction, (iv) higher accuracy in reading the number of identical adjacent nucleotides in difficult templates, and (v) longer reads. The usefulness of these results for future Pyrosequencing applications is discussed.

Contiguous strings of strongly binding short oligonucleotides as a useful tool for completing sequencing experiments

Large-scale DNA sequencing is currently based mostly on the shotgun approach. Although widely used, it is not free of shortcomings: the total length of randomly sequenced subclones appear to be five to eight times more than the total DNA length; such a high statistical redundancy of random sequences cannot guarantee the absence of unsequenced gaps. We calculated that these problems could be alleviated if the average length of the subcloned random fragments were increased. In this paper we present the primer walking approach based on the use of contiguous modified hexamer strings strongly binding to complementary templates as segmented primers. The approach exhibits the following characteristic features: 1) Single-stranded templates appear to have advantage over double-stranded ones. 2) With single-stranded templates, an overall sequencing success rate is about 80%. 3) A relatively small library of 1400 hexanucleotides selected according to the most frequent occurrence in the human genome is sufficient for sequencing all clones. The approach allows one to reduce the number of templates necessary for the shotgun strategy and also to decrease the number of gaps between sequenced contigs. This should be kept in mind when considering the ways for enhancement of the present strategy of large-scale sequencing.

DENS (differential extension with nucleotide subsets): application to the sequencing of human genomic DNA and cDNA

Here we describe further development of our method of DNA sequencing by Differential Extension with Nucleotide Subsets (DENS) and its application to the sequencing of human genomic DNA and full-insert cDNA. Essentially, DENS is primer walking without custom primer synthesis; instead, DENS uses a presynthesized library of octamer primers degenerate in two positions (4,096 tubes/sequences for a complete library). DENS converts an octamer selected from this library into a long primer on the template, at the intended site only. This is done using a two-step procedure which starts with a limited extension of the octamer (at 20 degrees C) in the presence of only two of the four possible dNTPs. The primer is extended by five bases or more at the intended priming site, which is deliberately selected to maximize the extension length (as are the two-dNTP set and the primer itself). The subsequent termination reaction at 60 degrees C then accepts the primer extended at the intended site, but not at alternative sites, where the initial extension (if any) is generally much shorter. This paper presents a set of rules for selection of DENS priming sites. We also compare different ways of template preparation for DENS sequencing. The data were obtained from primer walking on three human genomic DNA subclones of 3 to 4 kbp and four cDNA clones containing inserts of 1.9, 2.3, 3.8, and 4.9 kbp. Full-length sequences were obtained from both strands of each subclone by automated dye-terminator fluorescent DNA sequencing using DENS with degenerate octamer primers. We compared the following types of DNA templates: single-stranded and double-stranded phagemid DNA, double-stranded PCR products, asymmetric PCR products, and single-stranded DNA produced by digestion with Lambda Exonuclease of double-stranded PCR product phosphorylated at one end (Exo-PCR). While all of the preps were found to work, the best results were obtained with Exo-PCR and phagemid single-stranded DNA. Exo-PCR directly from overnight bacterial culture with no plasmid prep of any kind yielded templates for DENS as good as Exo-PCR from purified DNA. We found that the Tm of the differentially extended octamers is an important factor in the success of DENS. Clustering of successful reactions was clearly distinguished in the Tm range of 50-66 degrees C, with success rates of 70% for Exo-PCR and 65% for ss phagemid templates.

Determining the influence of structure on hybridization using oligonucleotide arrays

We have studied the effects of structure on nucleic acid heteroduplex formation by analyzing hybridization of tRNAphe to a complete set of complementary oligonucleotides, ranging from single nucleotides to dodecanucleotides. The analysis points to features in tRNA that determine heteroduplex yield. All heteroduplexes that give high yield include both double-stranded stems as well as single-stranded regions. Bases in the single-stranded regions are stacked onto the stems, and heteroduplexes terminate at potential interfaces for coaxial stacking. Heteroduplex formation is disfavored by sharp turns or a lack of helical order in single-stranded regions, competition from bases displaced from a stem, and stable tertiary interactions. The study is relevant to duplex formation on oligonucleotide microarrays and to antisense technologies.

Quantitative investigation of the modular primer effect for DNA and peptide nucleic acid hexamers

The effect on oligonucleotide-template duplex stability upon cohybridization of adjacently annealing oligonucleotides, the modular primer effect, was studied with biosensor technology. DNA and peptide nucleic acid (PNA) hexamer modules and sensor chip-immobilized template DNA strands were designed for analysis of nick, overlap, and gap modular hybridization situations. The fast hybridization kinetics for such hexamer modules allowed for the determination of apparent duplex affinities from equilibrium responses. The results showed that the hybridizational stability of modular hexamer pairs is strongly dependent on the positioning, concentration, and inherent affinity of the adjacently annealing hexamer module. Up to 80-fold increases in apparent affinities could be observed for adjacent modular oligonucleotide pairs compared to affinities determined for single hexamer oligonucleotide hybridizations. Interestingly, also for coinjections of different module combinations where DNA hexamer modules were replaced by their PNA counterparts, a modular primer effect was observed. The introduction of a single base gap between two hexamer modules significantly reduced the stabilization effect, whereas a gap of two bases resulted in a complete loss of the effect. The results suggest that the described biosensor-based methodology should be useful for the selection of appropriate modules and working concentrations for use in different modular hybridization applications.

Hybridization of glass-tethered oligonucleotide probes to target strands preannealed with labeled auxiliary oligonucleotides

In this article we introduce a strategy of preannealing labeled auxiliary oligonucleotides to single-stranded target DNA, prior to hybridization of the DNA target to oligonucleotide arrays (genosensors) formed on glass slides for the purpose of mutation analysis. Human genomic DNA samples from normal individuals and cystic fibrosis (CF) patients (including homozygous delta F508 and heterozygous delta F508/wild type (wt) in the region examined) were used. A PCR fragment of length 138 bp (wt) or 135 bp (mutant) was produced from exon 10 in the cystic fibrosis transmembrane conductance regulator (CFTR) gene, using a new pair of polymerase chain reaction (PCR) primers. This fragment contains four of the most frequent mutation sites causing the disease (Q493X, delta I507, delta F508, and V520F). Each of these mutations was tested using a pair of nonamer (9-mer) probes covalently attached to glass slides, representing the normal (wt) and the mutant alleles. Single-stranded target DNA was isolated from the PCR fragment using one PCR primer labeled with biotin and a streptavidin minicolumn to capture the biotin-labeled strand. Prior to hybridization to the 9-mer array on a glass slide, the unlabeled target strand was preannealed with one, three, or four auxiliary oligonucleotides, at least one being labeled with 32P. As observed previously in several laboratories, the discrimination between normal (wt) and mutant alleles at each site using oligonucleotide array hybridization ranged from very good to poor, depending on the number and location of mismatches between probe and target. Terminal mismatches along the probe were difficult to discriminate, internal mismatches were more easily discriminated, and multiple mismatches were very well discriminated. An exceptionally intense hybridization signal was obtained with a 9-mer probe that hybridized contiguously (in tandem) with one auxiliary oligonucleotide preannealed to the target DNA. The increased stability is apparently caused by strong base stacking interactions between the "capture probe" and the auxiliary oligonucleotide. The presence of the delta F508 mutation was detected with this system, including discrimination between homozygous and heterozygous conditions. Base mismatch discrimination using the arrayed 9-mer probes was improved by increasing the temperature of hybridization from 15 to 25 degrees C. Auxiliary oligonucleotides, preannealed to the single-stranded template, may serve several purposes to enable a more robust genosensor-based DNA sequence analysis: 1. A convenient means of introducing label into the target DNA molecule. 2. Disruption of interfering short-range secondary structure in the region of analysis. 3. Covering up of redundant binding sites in the target strand (i.e., where a given probe has more than one complement within the target). 4. Tandem hybridization with the capture probe (providing contiguous stacking) as a means for achieving efficient mismatch discrimination at the terminal position of the capture probe (adjacent to the auxiliary oligonucleotide). By use of multiple auxiliary oligonucleotides, all of the above benefits can be derived simultaneously.

Mutation detection by stacking hybridization on genosensor arrays

A new strategy for analysis of point mutations using oligonucleotide array (genosensor) hybridization was investigated. In the new approach, a single-stranded target strand is preannealed with a labeled "stacking oligonucleotide," and then the partially duplex labeled target molecule is hybridized to an array of glass-tethered oligonucleotide probes, targeted to the region on the target immediately adjacent to the stacking oligomer. In this configuration, the base-stacking interactions between the "capture probe" and the contiguously stacking oligomer stabilize the binding of the target molecule to its complementary probe on the genosensor array. The temperature of hybridization can be adjusted so that the target molecule will bind to the glass-tethered probe only in the presence of the stacking oligomer, and a single mismatch at or near the terminal position ol the capture probe disrupts the stacking interactions and thereby eliminates or greatly reduces the hybridization. This stacking hybridization approach was investigated using a collection of synthetic targets, probes, and stacking oligonucleotides, which permitted identification of conditions for optimal base mismatch discrimination. The oligonucleotide probes were tethered to the glass using a simple, improved attachment chemistry in which a 3'-aminopropanol function introduced into the probe during chemical synthesis binds covalently to silanol groups on clean, underivatized glass. "Operating parameters" examined in the stacking hybridization system included length of capture probe, position, type and number of mismatches between the probe and the target, temperature of hybridization and length of washing, and the presence of terminal phosphate group in the probe, at its junction with the stacking oligomer. The results suggest that in the stacking hybridization configuration: 1. Optimal mismatch discrimination with 9-mer probes occurs at 45 degrees C, after which little or no improvement in mispair rejection occurred on lengthy continued washing at 45 degrees C. 2. At 25 degrees C optimal mismatch discrimination occurred with 7- or 8-mer probes, or with 9-mer probes containing an additional internal mismatch. 3. The presence of a phosphate group on the 5'-end of the glass-tethered probe had no general effect on mismatch discrimination, but influenced the relative stability of different mismatches in the sequence context studied. These results provide a motivation for continued development of the stacking hybridization technique for nucleic acid sequence analysis. This approach offers several advantages over the traditional allele-specific oligonucleotide hybridization technique, and is distinct from the contiguous stacking hybridization sitrategy that the Mirzabekov laboratory has introduced (Yershov et al. (1996) Proc. Natl. Acad. Sci. USA 93, 4913-4918; Parinov et al. (1996) Nucleic Acids Res. 24, 2998-3004).

Genomic DNA sequencing by SPEL-6 primer walking using hexamer ligation

DNA sequencing by SPEL-6 (Sequential Primer Elongation by Ligation of 6-mers) primer walking is based on the rapid assembly of true primers by ligation of several (three to 10) contiguous hexamers complementary to a DNA template saturated with Escherichia coli single-stranded DNA-binding protein. To prove the usefulness and to check the reliability of this method, a 3-kb DNA fragment carrying the genes encoding the EcoVIII restriction-modification (RM) system was sequenced with low redundancy (2.8). The use of both single-stranded (ss) and double-stranded (ds) DNA templates was compared. For this project, 27 primers were assembled by hexamer ligation to form 18-30-nt strings of three to five hexamers. Each primer was designed based on nucleotide sequence determined in a previous run, and was produced in a matter of minutes. The overall length of the easily readable sequencing ladders was about 300-450nt. We found that strong secondary structures in the ss DNA tend to interfere with its template function for the primer assembly by hexamer ligation, especially when they overlap the 3'-end of such a primer. This was easily overcome either by avoiding such hairpin regions or by using longer strings of hexamers, since we show that their ligation is highly cooperative, and ligation efficiency increases with the length of the string (). Some general rules for successful primer assembly and prospects for using the SPEL-6 method for large-scale, fully automated fluorescent sequencing of large genomes are discussed.

DNA secondary structure effects on DNA synthesis catalyzed by HIV-1 reverse transcriptase

The effect of DNA secondary structure on polymerization catalyzed by human immunodeficiency virus (HIV-1) reverse transcriptase (RT) was studied using a synthetic 66-nucleotide DNA template containing a stable hairpin structure. Four RT pause sites were identified within the first half of the hairpin stem. Additionally, five weak pause sites within the second half of the stem and the loop of the hairpin were identified at low temperatures. These weak pause sites were relocated to the site of the first few stem base pairs of two new hairpins formed due to a change in DNA secondary structure. Each pause site was correlated with a high free energy barrier of melting the stem base pair. Pre-steady state kinetic analysis of single nucleotide incorporation showed that polymerization at each pause site occurred by both a fast phase (10-20 s-1) and a slow phase (0. 02-0.07 s-1) during a single binding event. The reaction amplitudes of the fast phase were small (4-10% of enzyme sites), whereas the amplitudes of the slow phase were large (14-40%) at the pause sites. In contrast, only a single phase with a large reaction amplitude (32-50%) and a fast nucleotide incorporation rate (33-87 s-1) was observed at the non-pause sites. DNA substrates at all sites had similar dissociation rates (0.14-0.29 s-1) and overall binding affinity (16-86 nM). These results suggest that the DNA substrates at pause sites were bound in both productive and non-productive states at the polymerase site of RT. The non-productively bound DNA was slowly converted into a productive state upon melting of the next stem base pair without dissociation of the DNA from RT.

Capture of single-stranded DNA assisted by oligonucleotide modules

Real-time biospecific interaction analysis was employed to monitor direct capture of a hepatitis C virus (HCV) derived polymerase chain reaction (PCR) product by nucleic acid hybridization. Different formats for hybridization were used to study the interaction between a single-stranded HCV PCR product and capture oligonucleotides immobilized on a sensor chip via streptavidin-biotin chemistry. By employing a prehybridization step in solution with nonbiotin oligonucleotides complementary to the single-stranded target and adjacent to the immobilized probe, a significant capture was achieved in comparison to the low capture efficiency obtained using single immobilized probes (9-36 mer). High capture efficiencies were also observed when shorter immobilized probes were used in combination with strings of adjacently positioned prehybridized probes (i.e., modules). Interestingly, the introduction of single nucleotide gaps between prehybridized and/or immobilized probes dramatically reduced the capture efficiency. These results suggest that flexible systems for capture could be designed from libraries of short oligonucleotides (9 mers) used in module fashion, taking advantage of stacking interactions between the oligonucleotides. The potential applications of such oligonucleotide-assisted capture systems are discussed.

Surprising fidelity of template-directed chemical ligation of oligonucleotides

BACKGROUND

Nucleic acid replication via oligonucleotide ligation has been shown to be extremely prone to errors. If this is the case, it is difficult to envision how the assembly and replication of short oligonucleotides could have contributed to the origin of life and to the evolution of a putative RNA world. In order to assess the fidelity of oligonucleotide replication more accurately, chemical ligation reactions were performed with constant-sequence DNA templates and random-sequence DNA pools as substrates.

RESULTS

In keeping with earlier results, constant-sequence hairpin templates were not faithfully copied by random-sequence substrates. Linear templates, however, showed exceptional replication fidelity, particularly when random hexamers were ligated at 25 degrees C. Surprisingly, at low temperatures the formation of G.A base pairs was common and sometimes occurred even more readily than the formation of the corresponding Watson-Crick A-T and G-C base pairs.

CONCLUSIONS

The fidelity of ligation reactions increases with temperature and decreases with the length of the random-sequence substrates. Oligonucleotides with a defined sequence can be copied faithfully in the absence of enzymes. Thus, to the extent that short oligonucleotides could readily have been generated by prebiotic mechanisms, it is possible that the earliest self-replicators arose via oligonucleotide ligation.

DNA sequencing using differential extension with nucleotide subsets (DENS)

Here we describe template directed enzymatic synthesis of unique primers, avoiding the chemical synthesis step in primer walking. We have termed this conceptually new technique DENS (differential extension with nucleotide subsets). DENS works by selectively extending a short primer, making it a long one at the intended site only. The procedure starts with a limited initial extension of the primer (at 20-30 degrees C) in the presence of only two out of the four possible dNTPs. The primer is extended by 6-9 bases or longer at the intended priming site, which is deliberately selected, (as is the two-dNTP set), to maximize the extension length. The subsequent termination reaction at 60-65 degrees C then accepts the extended primer at the intended site, but not at alternative sites, where the initial extension (if any) is generally much shorter. DENS allows the use of primers as long as 8mers (degenerate in two positions) which prime much more strongly than modular primers involving 5-7mers and which (unlike the latter) can be used with thermostable polymerases, thus allowing cycle-sequencing with dye-terminators compatible with Taq DNA polymerase, as well as making double-stranded DNA sequencing more robust.

The thermodynamic advantage of DNA oligonucleotide 'stacking hybridization' reactions: energetics of a DNA nick

'Stacking hybridization reactions' wherein two or more short DNA oligomers hybridize in a contiguous tandem orientation onto a longer complementary DNA single strand have been employed to enhance a variety of analytical oligonucleotide hybridization schemes. If the short oligomers anneal in perfect head-to-tail register the resulting duplex contains a nick at every boundary between hybridized oligomers. Alternatively, if the short oligomers do not hybridize precisely in register, i.e. single strand regions on the longer strand are left unbound, gaps are formed between regions where short oligomers bind. The resulting gapped DNA duplexes are considerably less stable than their nicked duplex analogs. Formation of base pair stacking interactions between neighboring oligomers at the nicks that do not occur in gapped duplexes has been proposed as the source of the observed added stability. However, quantitative evidence supporting this hypothesis for DNA has not been reported. Until now, a direct comparison of the thermodynamics of DNA nicks versus DNA gaps has not been performed. In this communication we report such a comparison. Analysis of optical melting experiments in a well defined molecular context enabled quantitative evaluations of the relative thermodynamic difference between nicked and gapped DNA duplexes. Results of the analysis reveal that a nick may be energetically favored over a gap by at least 1.4 kcal/mol and perhaps as much as 2.4 kcal/mol. The presence of a 5'phosphate at a nick or gap fails to significantly affect their stabilities.

Simultaneous shotgun sequencing of multiple cDNA clones

This study describes an efficient method for the rapid sequencing of DNA fragments in the size range 1-5 kb. Individual fragments, here cDNA inserts, are purified by restriction enzyme digestion and gel purification, pooled and concatenated by ligation. The concatamers are sheared and cloned randomly into M13, followed by random sequencing. The sequences of the individual cDNA inserts are obtained at the assembly stage using restriction enzyme sites as "tags' for the ends of each fragment. In this study the sequencing of two libraries containing 7 and 16 cDNA inserts with an average length of 2.5 kb is described. The results show that of the shotgun sequencing of large fragments, and that the method compares favorably to alternative strategies, such as primer walking.

It's the genes! EST access to human genome content

ESTs or 'expressed sequence tags' are DNA sequences read from both ends of expressed gene fragments. The Merck-WashU EST Project and several other public EST projects are being performed to rapidly discover the complement of human genes, and make them easily accessible. These ESTs are widely used to discover novel members of gene families, to map genes to chromosomes as 'sequence-tagged sites' (STSs), and to identify mutations leading to heritable diseases. Informatic strategies for querying the EST databases are discussed, as well as the strengths and weaknesses of the EST data. There is a compelling need to build on the informatic synthesis of human gene data, and to devise facile methods for determining gene functions.

Automated four-color DNA sequencing using primers assembled by hexamer ligation

A procedure based on the assembly of sequencing primers by hexamer ligation and then using them in automated DNA sequencing is described. This method is based on a four-color fluorescent terminator chemistry. Sequencing ladders were analyzed using an ABI 373 DNA sequencer (Applied Biosystems, Foster City, CA, USA). The best results were obtained for primers assembled by ligation of four to ten hexamers. The accuracy of the method was estimated to be 99.5% up to 400 nt of the read sequence, and somewhat lower at 400-600 nt.

DNA sequencing by hybridization to microchip octa-and decanucleotides extended by stacked pentanucleotides

The efficiency of sequencing by hybridization to an oligonucleotide microchip grows with an increase in the number and in the length of the oligonucleotides; however, such increases raise enormously the complexity of the microchip and decrease the accuracy of hybridization. We have been developing the technique of contiguous stacking hybridization (CSH) to circumvent these shortcomings. Stacking interactions between adjacent bases of two oligonucleotides stabilize their contiguous duplex with DNA. The use of such stacking increases the effective length of microchip oligonucleotides, enhances sequencing accuracy and allows the sequencing of longer DNA. The effects of mismatches, base composition, length and other factors on the stacking are evaluated. Contiguous stacking hybridization of DNA with immobilized 8mers and one or two 5mers labeled with two different fluorescent dyes increases the effective length of sequencing oligonucleotides from 8 to 13 and 18 bases, respectively. The incorporation of all four bases or 5-nitroindole as a universal base into different positions of the 5mers permitted a decrease in the number of additional rounds of hybridization. Contiguous stacking hybridization appears to be a promising approach to significantly increasing the efficiency of sequencing by hybridization.

Octamer-primed cycle sequencing: design of an optimized primer library

This paper describes a novel method of primer walking using octamer oligonucleotides to prime DNA sequencing reactions. Octamer sequencing is compatible with isotopic and fluorescent sequencing chemistry, reaction conditions are optimized such that the samples can be processed in parallel, and the procedure has the potential to be automated. This strategy is faster than the traditional primer walking sequencing strategy, as the existence of a primer library allows immediate access to a primer for the next sequencing reaction, eliminating delays associated with designing and synthesizing gene-specific primers. The octamer library is comprised of optimized sequencing primers, such that octamer sequencing yields results equivalent to or better than traditional primer walking. This technology is more economical because gene-specific sequencing primers, the major cost in the reaction, are replaced by an optimized subset of frequently occurring octamers that are able to prime multiple reactions.

N-ras mutations in radiation-induced murine leukemic cells

N-ras mutations were examined in DNA samples extracted from the spleen of CBA/Ca mice that developed myeloid leukemia (ML) following exposure to radiations of different qualities. A total of 17 ML cases, i.e. 5 cases of neutron-induced and 12 cases of photon- (3 gamma-ray and 9 x-ray) induced ML were included in the study along with 12 DNA samples from the bone marrow cells of control mice. Polymerase chain reaction-single strand conformational polymorphisms (PCR-SSCP) and the direct sequencing of PCR products were used to analyze three regions of the N-ras gene: (i) a 120 base-pair (bp) long portion of exon I (codons 2-37); (ii) a 103 bp long portion of exon II (codons 48-82); and (iii) a 107 bp long portion of exon III (codons 118-150). PCR-SSCP mobility shifts indicated mutations within only exon II of the N-ras gene. Such mutations were more prevalent in samples from mice exposed to fast neutrons. The exact type and location of these mutations were then determined by direct DNA sequencing. Silent point mutations, i.e. base transitions at the third base of codons 57 (GAC-->GAT), 62 (CAA-->CAC), or 70 (CAG-->CAA) were present only in mice that developed ML after exposure to fast neutrons. A base transversion at the third base of codon 61 (CAA-->CAC) was also observed in some ML cases. DNA sequencing demonstrated that ML samples contained normal as well as mutated DNA sequences. The higher frequency of N-ras mutations in neutron-induced ML suggested that fast neutrons are more effective in inducing genomic instability at the N-ras region of the genome. More importantly, N-ras mutations are not the initiating event in radiation leukemogenesis. This conclusion was supported by the finding that N-ras mutations were detected only in mice with an overt leukemic phenotype but not in mice with minimal tissue infiltration of leukemic cells, suggesting that the disease may be present prior to the presence of N-ras mutations. Alternatively, N-ras may be present in these mice but a large number of normal spleen cells in these mice interferes with the detection of mutation in a small population of leukemic cells.

Factors affecting the priming efficiency of short contiguous oligonucleotide strings in the primer walking strategy of DNA sequencing

We use modified oligonucleotides with enhanced strength of complementary DNA binding for primer walking DNA sequencing with strings of short contiguous oligonucleotides as primers. Such an approach allows us to reduce the probability of primer failures due to unstable binding of oligos with templates. In this paper the factors affecting the priming efficiency of segmented primers (strings composed of several short oligonucleotides contiguously juxtaposed on the template) used for DNA sequencing were investigated. Modified oligonucleotides were used to discriminate the effects caused by intrinsic properties of the oligonucleotides and by template features. It was shown that the most crucial factor is the stability of the duplex formed by the template with the 3'-outermost oligonucleotide of a string. The data were obtained with a model M13 template and in the process of sequencing the region flanking a long terminal repeat of human endogenous retrovirus HERVK mapped on chromosome 19. The sequencing was done by primer walking with strings of contiguous modified hexanucleotides. The effects revealed should be taken into consideration when choosing oligonucleotide units of segmented primers and for construction of minimised libraries composed of short unit oligonucleotides.

Efficiency of sequencing by hybridization on oligonucleotide matrix supplemented by measurement of the distance between DNA segments

DNA sequencing by hybridization on oligonucleotide microchip (SHOM) allows the determination of a spectrum of overlapping oligonucleotides constituting a DNA fragment that hybridizes to form perfect duplexes with an array of immobilized oligonucleotides and, as a result, enables reconstitution of the nucleotide sequence of the fragment. In longer DNA fragments, unambiguous reconstitution of DNA sequence is often impeded by the presence of repetitive regions and simple sequence repeats. Here it is demonstrated that SHOM supplemented by measurement of the distance between certain sites (for example, restriction sites or priming sites for PCR) within the analyzed DNA enables sequencing of much longer DNA fragments, containing repeats of different complexity.

High-quality automated DNA sequencing primed with hexamer strings

The finishing phase of genome sequencing projects is expensive, in part, because of the cost of de novo synthesis of custom primers and the management burden associated with obtaining and using them for primer walking. One approach to reduce these high costs is the use of a presynthesized library of short oligonucleotides (8-10 bases) rather than long primers. The use of such a library eliminates the need for custom synthesis of oligonucleotides, providing the convenience of priming from any site by combining two to three short oligonucleotides to form a string with the required specificity. The first practical implementation of this strategy presented a robust protocol for using hexamer strings with radioisotopic labelling. Whereas versions of this technique have subsequently been implemented on fluorescent sequencers we felt that there was a need to develop and extensively test a protocol that consistently gave read lengths comparable to dye-terminator sequencing with longer primers. We have developed a new two-cycle fluorescent Sequenase terminator procedure for using hexamer strings. We tested this procedure using a set of 32 different 3 hexamer primer strings, each known to be functional to some degree in radioisotopic sequencing, on single-stranded M13mp18 template and ABI 373 DNA sequencers. The overall success rate of priming with these hexamer primer strings is 97% with the failure of only one string. In this case, the corresponding 18-mer primer also failed to produce usable sequence from M13mp18 template. The average read length from reactions successfully primed with the 31 different hexamer strings was 461 bases with > 99% base-calling accuracy. The current protocol is robust enough to be used in virtually any situation where primer walking on single-stranded templates is used. The success rate and read lengths make it universally applicable to the sequencing of single-stranded templates on automated sequencers. It is also amenable to automation.

How is the Human Genome Project doing, and what have we learned so far?

In this paper, we describe the accomplishments of the initial phase of the Human Genome Project, with particular attention to the progress made toward achieving the defined goals for constructing genetic and physical maps of the human genome and determining the sequence of human DNA, identifying the complete set of human genes, and analyzing the need for adequate policies for using the information about human genetics in ways that maximize the benefits for individuals and society.

A DNA sequencing strategy that requires only five bases of known terminal sequence for priming

We have previously reported an enhanced version of sequencing by hybridization (SBH), termed positional SBH (PSBH). PSBH uses partially duplex probes containing single-stranded 3' overhangs, instead of simple single-stranded probes. Stacking interactions between the duplex probe and a single-stranded target allow us to reduce the probe sizes required to 5-base single-stranded overhangs. Here we demonstrate the use of PSBH to capture relatively long single-stranded DNA targets and perform standard solid-state Sanger sequencing on these primer-template complexes without ligation. Our results indicate that only 5 bases of known terminal sequence are required for priming. In addition, the partially duplex probes have the ability to capture their specific target from a mixture of five single-stranded targets with different 3'-terminal sequences. This indicates the potential utility of the PSBH approach to sequence mixtures of DNA targets without prior purification.

Pressing ahead with human genome sequencing

While waiting for revolutionary techniques to emerge, conventional approaches have been used to generate more than 40 million bases of DNA sequence from large scale projects involving different organisms. About eight megabases are from the human genome. Does this progress signal the time to move ahead for a massive human genomic sequencing effort, or should we bide our time, waiting for more technical developments? The answer is to move ahead now, choosing carefully those strategies that can be easily adapted to future methodologies.

On the mechanism of the modular primer effect

Modular primers are strings of three contiguously annealed unligated oligonucleotides (modules) as short as 5- or 6-mers, selected from a presynthesized library. It was previously found that such strings can prime DNA sequencing reactions specifically, thus eliminating the need for the primer synthesis step in DNA sequencing by primer walking. It has remained largely a mystery why modular primers prime uniquely, while a single module, used alone in the same conditions, often shows alternative priming of comparable strength. In a puzzling way, the single module, even in a large excess over the template, no longer primes at the alternative sites, when modules with which it can form a contiguous string are also present. Here we describe experiments indicating that this phenomenon cannot be explained by cooperative annealing of the modules to the template. Instead, the mechanism seems to involve competition between different primers for the available polymerase. In this competition, the polymerase is preferentially engaged by longer primers, whether modular or conventional, at the expense of shorter primers, even though the latter can otherwise prime with similar or occasionally higher efficiency.

An update and lessons from whole-genome sequencing projects

A number of prokaryotic and eukaryotic genomes are currently being sequenced. Already, the nucleotide sequences of four yeast chromosomes and of 2.2 Mb from Caenorhabditis elegans have been reported. Human genomic sequences have also been used in comparative studies with both mouse and Fugu rubripes.

Optical melting of 128 octamer DNA duplexes. Effects of base pair location and nearest neighbors on thermal stability

The use of short oligonucleotide probes is finding increased application in DNA sequencing and genome characterization techniques, but a lack of knowledge of the hybridization properties of short duplexes hinders their use. Melting data were acquired on 128 DNA duplexes based on the length proposed in sequencing by hybridization procedures and formed from the general sequences 5'-XYZTGGAC-3',5'-GTCCAXYZ-3',5'-GCXYZGAC-3', and 5'-GTCXYZGC-3' where X, Y, and Z are either A, T, G, or C. These molecules were designed to elucidate the effects of location and nearest-neighbor stacking on the stability of base pairing in short DNA duplexes. The type of base pairs present had a major effect on stability, but was insufficient to predict stability without the inclusion of nearest-neighbor terms. Furthermore, the addition of information on position, or distance from the end, of the nearest-neighbor doublets led to statistically better fitting of the melting data. However, the positionally dependent stabilization differences are small compared with the contributions of base pairing and stacking.