Optimal chips for megabase DNA sequencing

The SHOM method (Sequencing by Hybridization with Oligonucleotide Matrix) developed in 1988 is a new approach to nucleic acid sequencing by hybridization to a octanucleotide matrix composed of an array of immobilized oligonucleotides. The original matrix proposed for sequencing by SHOM had to contain at least 65,536 octanucleotides. The present work describes a new family of matrices for sequencing, which allows one to reduce the number of synthesized oligonucleotides 5-15 times without essentially decreasing the resolving power of the method.     

DNA Sequencing by Hybridization to Oligonucleotide Matrix. Calculation of Continuous Stacking Hybridization Efficiency

Abstract

In this paper we consider the efficiency of additional rounds of “continuous stacking” hybridization in DNA sequence reconstruction by hybridization with oligonucleotide matrix (SHOM). After the initial hybridization of target DNA with the matrix of oligonucleotides of fixed length L some additional hybridizations should be carried out in the presence of fluorescently labeled oligonucleotides of another length l. These additional oligonucleotides can hybridize in tandem with matrix tuples (continuous stacking hybridization) thus forming an extended duplex with the target DNA strand. The additional data obtained allows resolutions of branching points arising in the reconstruction procedure. Multiple rounds of continuous stacking hybridization considerably increase the efficiency of the sequencing method, eventually approaching the power of (L+l)-matrix. We develop here an algorithm that allows us to minimize the number of additional hybridization steps, by assembling sets of l-tuples to be added together in each round of continuous stacking hybridization. For SHOM using a matrix of octanucleotides, continuous stacking hybridization with pen- tanucleotides increases the length of unambiguously sequenced DNA from 200 to several thousands of base pairs.     

A method for DNA sequencing by hybridization with oligonucleotide matrix.

A new technique of DNA sequencing by hybridization with oligonucleotide matrix (SHOM) which could also be applied for DNA mapping and fingerprinting, mutant diagnostics, etc., has been tested in model experiments. A dot matrix was prepared which contained 9 overlapping octanucleotides (8-mers) complementary to a common 17-mer. Each of the 8-mers was immobilized as individual dot in thin layer of polyacrylamide gel fixed on a glass plate. The matrix was hybridized with the 32P-labeled 17-mer and three other 17-mers differing from the first one by a single base change. The hybridization enabled us to distinguish perfect duplexes from those containing mismatches in 32 out of 35 cases. These results are discussed with respect to the applicability of the approach for sequencing. It was shown that hybridization of DNA with an immobilized 8-mer in the presence of a labeled 5-mer led to the formation of a stable duplex with the 5-mer only if the 5- and the 8-mers were in continuous stacking making a perfect nicked duplex 13 (5+8) base pairs long. These experiments and computer simulations suggest that continuous stacking hybridization may increase the efficiency of sequencing so that random or natural coding DNA fragments about 1000 bases long could be sequenced in more than 97% of cases. Miniaturized matrices or sequencing chips were designed, where oligonucleotides were immobilized within 100 x 100 micron dots disposed at 100 micron intervals. Hybridization of fluorescently labeled DNA fragments with microchips may simplify sequencing and ensure sensitivity of at least 10 attomoles per dot. The perspectives and limitations of SHOM are discussed.     

New strategies for DNA sequencing and determining protein location in genomic DNA]

A new technique of DNA sequencing by hybridization with oligonucleotide matrix (SHOM) has been tested in model experiments. The paper also describes a number of new approaches to protein identification and their mapping on any particular region of genomic DNA.     

Reducing the number of microlocations in oligonucleotide microchip matrices by the application of degenerate oligonucleotides

The application of degenerate oligonucleotides to DNA Sequencing by Hybridisation with Oligonucleotide Matrix (SHOM) is proposed. The use of degenerate oligonucleotides is regarded as an example of pooling methods that are suitable for various laboratory procedures requiring numerous samples to be assayed. As each DNA sequence coded by four letters (A, G, C, T) may be defined by two sequences: a sequence coded by W and S (W-weak-A or T, S-strong-G or C) and a sequence coded by R and Y (R-purine-A or G, Y-pirymidine-T or C), n4n -nucleotide sequences may be defined with the help of 2xn2sequences. In the place of the originally described microchip matrix composed of all possible unambiguous octanucleotides (4(8)=65 536) attached to the equal number of 65 536 microlocations a matrix composed of 512 microlocations containing 256 2(8)-degenerate octanucleotides is proposed. The matrix contains all 256 possible octanucleotides coded by W and S variations and all 256 possible octanucleotides coded by R and Y variations. The 512 256-degenerate octanucleotides allows to retrieve the same information as 65 536 unambiguous octanucleotides. A variant of the DNA sequence reconstruction method applicable to this system is presented. The use of degenerate oligonucleotides also gives the possibility to apply matrices composed of longer oligonucleotides without increasing the number of microlocations in matrices, which would enable increasing the length of unambiguously reconstructed sequence, e.g. a matrix comprising 131 072 16-mer oligonucleotides i.e. 65 536 65 536-fold degenerate oligonucleotide coded by W and S variations and 65 536 65 536-fold degenerate oligonucleotide coded by R and Y variations could replace one matrix comprising all possible unambiguous 16-mer oligonucleotides (ca. 4.3x10(9)).     

An oligonucleotide hybridization approach to DNA sequencing

We have proposed a DNA sequencing method based on hybridization of a DNA fragment to be sequenced with the complete set of fixed-length oligonucleotides (e.g., 4(8) = 65,536 possible 8-mers) immobilized individually as dots of a 2-D matrix [(1989) Dokl. Akad. Nauk SSSR 303, 1508-1511]. It was shown that the list of hybridizing octanucleotides is sufficient for the computer-assisted reconstruction of the structures for 80% of random-sequence fragments up to 200 bases long, based on the analysis of the octanucleotide overlapping. Here a refinement of the method and some experimental data are presented. We have performed hybridizations with oligonucleotides immobilized on a glass plate, and obtained their dissociation curves down to heptanucleotides. Other approaches, e.g., an additional hybridization of short oligonucleotides which continuously extend duplexes formed between the fragment and immobilized oligonucleotides, should considerably increase either the probability of unambiguous reconstruction, or the length of reconstructed sequences, or decrease the size of immobilized oligonucleotides.     

DNA sequencing by hybridization with an oligonucleotide matrix (SHOM). The theory of DNA elution after hybridization]

The theoretical treatment of the process of washing out of a single stranded DNA fragment after hybridization with short oligonucleotides immobilized within the polyacrylamide gel layer is presented. The theory describes satisfactorily the main body of experimental findings, obtained earlier in connection with the elaboration of a new DNA sequencing method based on hybridization with the matrix of immobilized oligonucleotides [K.R. Khrapko et al.@J. DNA Sequencing Mapp. 1991. V. 1. P. 373-388]. In particular the theory explains and describes well quantitatively the observed dependence of the "washing off temperature" Tw on the concentration of the immobilized oligonucleotides. The Tw dependence on inherent physico-chemical parameters such as the enthalpy and the entropy of duplex formation and on those selected by the experimenter (washing time duration, the gel thickness etc.) is also considered. A simple approximate expression for the calculation of "washing off temperature" is given. Some inconsistencies between calculated and observed washing curves are discussed.     

Solid-phase methods for sequencing of nucleic acids I. Simultaneous sequencing of different oligodeoxyribonucleotides using a new, mechanically stable anion-exchange paper.

A solid-phase method for simultaneous sequencing of large numbers of oligodeoxyribonucleotides has been developed using a new, mechanically stable anion-exchange paper. The excellent mechanical properties of the polymer allow the processing of several paper segments in one reaction vessel or to carry out all necessary operations on a larger area of the paper. In addition, DNA material can be chemically eluted from the new carrier during the piperidine reaction, thus avoiding salt elution of DNA and subsequent ethanol precipitation steps - a prerequisite for sequencing oligonucleotides. The approach involves 7 operations including: i) immobilization; ii) washing; iii) modification; iv) washing; v) sorting of the papers; vi) piperidine reaction and chemical elution and vii) lyophilization. All steps can be carried out in 4 to 5 hours independently of the number of oligonucleotides to be sequenced. It is also possible to sequence small oligonucleotides with 3 to 4 base pairs. The method can be fully automated.     

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.     

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.     

Sequencing of pools of nucleic acids on oligonucleotide arrays

In sequencing-by-hybridization methods, the nucleotide sequence of a nucleic acid is reconstructed by overlapping oligonucleotides capable of hybridizing with the nucleic acid. In their present form, the methods are hardly suitable for sequencing of long nucleic acid molecules because of the occurrence of non-unique overlaps between the oligonucleotides, and similarly to the conventional sequencing methods, it is necessary to obtain an individual molecule. In the method described here, most ambiguities in reconstruction of a sequence from the constituent oligonucleotides are eliminated by preparing on oligonucleotide arrays and separate surveying of the nucleic acid nested partials. This enables longer nucleic acids to be sequenced, and results in a high redundancy of the input data allowing most hybridization errors to be eliminated by algorithmic means. Furthermore, large pools of nucleic acid strands can be sequenced directly, without isolating individual strands.     

Rapid purification of synthetic oligonucleotides: a convenient alternative to high-performance liquid chromatography and polyacrylamide gel electrophoresis

A new method has been developed to purify and detritylate milligram amounts of synthetic oligonucleotides. Dimethoxytrityl oligonucleotides from 15 to 100 nucleotides in length are applied in triethylammonium acetate or concentrated ammonium hydroxide to a disposable chromatographic cartridge, the NENSORB PREP Nucleic Acid Purification Cartridge. Salts, failure sequences and synthetic by-products are washed away while the desired, full-length, dimethoxytrityl oligonucleotide remains bound to the cartridge. The trityl group is hydrolyzed from the 5'-end of the oligonucleotide with an acid wash and then the purified oligonucleotide is eluted with 35% methanol. Oligonucleotides are recovered salt-free with purities greater than 95%. NENSORB PREP-purified primers provide superior sequence data compared to similar primers used without purification and equivalent data to primers purified by polyacrylamide gel electrophoresis when used in manual radiometric Sanger sequencing.     

Octamer-primed cycle sequencing using dye-terminator chemistry.

Octamer Sequencing Technology, OST, is a method of DNA sequencing using single octamer oligonucleotides to prime cycle sequencing reactions. This sequencing strategy is faster than a traditional primer-walking strategy, since access to this optimized octamer library eliminates delays associated with designing and synthesizing gene specific primers. In this report, OST has been optimized for fluorescent, dye-terminator cycle sequencing reactions to facilitate parallel processing of samples. The successful adaptation of OST to an automated sequencing platform and the design of and access to an octamer library are critical steps towards developing an efficient 'closed-loop' DNA sequencing system.     

Another side of genomics: synthetic biology as a means for the exploitation of whole-genome sequence information

The successful completion of the Human Genome Project and other sequencing projects opened the door for another quantum jump in science advancement. The most important public sequence databases are doubling in size every 18 months. By revealing the genetic program of many organisms, these efforts endow biologists with the ability to study the basic information of life in toto as an initial step toward a comprehensive understanding of the complexity of entire organisms. We review the area of synthetic biology, defined as the making and use of biosystems founded on the chemical synthesis of the coding DNA (and potentially RNA). The recent developments discussed here introduce a rich source of oligonucleotides to the field: in situ synthesised microarrays, which in fact represent nothing else but matrix nucleic acid synthesisers. With this new way of producing the oligonucleotides used in the making of synthetic genes in a very cost-effective manner, the field of synthetic biology can be expected to change dramatically in the next decade. Synthetic genes will then be the tools of choice to obtain any sequence at any time in any laboratory.     

Direct sequencing and bidirectional allele specific polymerase chain reaction of the bovine beta-casein B variant.

We have used the polymerase chain reaction (PCR) to amplify exon VII of the bovine beta-casein gene. The mutations responsible for the B variant were identified by direct sequencing of the amplification products. A bidirectional allele-specific PCR method (BAS-PCR) has been developed using oligonucleotides overlapping the mutation site at their 3' ends. This new procedure allows a rapid and reliable discrimination between the B and non-B alleles of beta-casein.     

Modifications of guanine bases during oligonucleotide synthesis.

Guanine bases are sensitive to modification during automated DNA synthesis and processing reactions. Methods for the detection of two types of guanine modifications are described. The first method uses the higher reactivity of the modified G base to KMn04 oxidation than T bases, and thus allows detection by chemical DNA sequencing. The second method makes use of the Escherichia coli nucleotide excision repair enzyme UvrABC endonuclease which can detect "bulky" base modifications at each nucleotide in the synthetic DNA. Though the chemical structures of the two modifications are not known, they may be related. Both types of G modifications are often found in oligonucleotides synthesized by the methoxy-diisopropyl-phosphoramidite (MEDP) chemistry but non-detectable in the products of the beta-cyanoethyl-diisopropyl-phosphoramidite (CEDP) chemistry. The Rubin and Schmid pyrimidine-specific chemical DNA sequencing procedure (Rubin, C.M., and Schmid, C.W. (1980) Nucleic Acids Res. 8, 4613-4619) was found to be applicable to oligonucleotides synthesized by the CEDP chemistry, and to oligonucleotides synthesized by the MEDP chemistry if precautionary measures are taken to destroy the signals produced by the highly KMnO4 sensitive modified guanine bases. We also show how chemical DNA sequencing might be useful for diagnosing other chemical modifications in synthetic oligonucleotides.     

A method for cloning mixtures of long,synthetic oligodeoxynucleotides

A method is described for cloning synthetic oligodeoxynucleotides, which can theoretically be of any length. The method requires only a single oligodeoxynucleotide strand and a vector with two unique restriction sites, one of which is for an enzyme that generates 3′ protruding ends. A mixture of unpurified oligonucleotides containing a wild-type genetic regulatory sequence of the Escherichia coli gnd gene and two mutations of it was cloned into a plasmid carrying a gnd-lacZ protein fusion. Individual cloned oligonucleotides were readily identified by direct DNA sequencing of plasmid templates. The method is rapid, efficient, and has application to gene synthesis and site-directed mutagenesis.     

Oligonucleotide analysis by gel capillary electrophoresis

Several million oligonucleotides are synthesized each year for a broad variety of molecular biology applications. Steady improvements in the synthesis chemistry efficiency and the automated DNA synthesizers have made production of oligonucleotides routine and reliable. Many applications, such as PCR and sequencing, are often successful when the primers have not been rigorously purified. To ensure an adequate level of quality and purity, rapid and convenient analytical methods are necessary for the dozens of oligonucleotides produced each day by a DNA synthesis laboratory. Traditional methods of analysis have been HPLC and polyacrylamide slab tel electrophoresis (PAGE). Gel capillary electrophoresis is a new option, combining the advantages of the HPLC and PAGE, with unprecedented resolution and speed.     

Rapid removal of unincorporated label and proteins from DNA sequencing reactions

This article presents a simple and rapid method for removal of unincorporated label and proteins from DNA sequencing reactions by using Wizard purification resin. This method can be successfully applied for preparation of end-labeled oligonucleotides free of unincorporated label, which is important in experiments (including DNA sequencing) when the level of background should be as low as possible. Also, this method is effective in removal of proteins from DNA sequencing reactions.