Yu. P. Lysov

An oligonucleotide hybridization approach to DNA sequencing

DNA sequencing; Oligonucleotide hybridization, immobilized

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.

Improved Chips for Sequencing by Hybridization

The SHOM method (Sequencing by Hybridization with Oligonucleotide Matrix) developed in 1988 is a new approach to nucleic acid sequencing by hybridization to an oligonucleotide 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, which allows one to reduce the number of synthesized oligonucleotides 5-15 times without essentially decreasing the resolving power of the method.

Biological Microchips with Hydrogel-Immobilized Nucleic Acids, Proteins, and Other Compounds: Properties and Applications in Genomics

The MAGIChip (MicroArrays of Gel-Immobilized Compounds on a chip) consists of an array of hydrophilic gel pads fixed on a hydrophobic glass surface. These pads of several picoliters to several nanoliters in volume contain gel-immobilized nucleic acids, proteins, and other compounds, as well as live cells. They are used to conduct chemical and enzymatic reactions with the immobilized compounds or samples bound to them. In the latter case, nucleic acid fragments can be hybridized, modified, and fractionated within the gel pads. The main procedures required to analyze nucleic acid sequences (PCR, detachment of primers and PCR-amplified products from a substrate, hybridization, ligation, and others) can be also performed within the microchip pads. A flexible, multipurpose, and inexpensive system has been developed to register the processes on a microchip. The system provides unique possibilities for research and biomedical applications, allowing one to register both equilibrium states and the course of reaction in real time. The system is applied to analyze both kinetic and thermodynamic characteristics of molecular interaction in the duplexes formed between nucleic acids and the probes immobilized within the microchip gel pads. Owing to the effect of stacking interaction of nucleic acids, the use of short oligonucleotides extends the possibilities of microchips for analysis of nucleic acid sequences, allowing one to employ the MALDI-TOF mass spectrometry to analyze the hybridization data. The specialized MAGIChips has been successfully applied to reveal single-nucleotide polymorphism of many biologically significant genes, to identify bacteria and viruses, to detect toxins and characterize the genes of pathogenic bacteria responsible for drug resistance, and to study translocations in the human genome. On the basis of the MAGIChip, protein microchips have been created, containing immobilized antibodies, antigens, enzymes, and many other substances, as well as microchips with gel-immobilized live cells.

Parallel stranded DNA with AT base pairing

The concentration and temperature dependences of the UV and CD spectra of the oligonucleotide 3′‐d(ApTpApTpApTpApTpApTp)‐O(CH2)6O‐5′‐d(pApTpApTpApTpApTpApT) (eicosamer) in aqueous solution at pH 7 in the presence of 0.5 M NACl were studied. At less than 10−6 M, the eicosamer was shown to form in solution a hairpin with parallel orientation of chains (parallel hairpin). From thermal denaturation profiles [A 260(T)] the thermodynamic parameters, ΔH°, ΔS° and T m for parallel hairpin formation were calculated to be −90±8 kJ/mol. −300±20 J · mol−1 · K−1 and 40.5°C, respectively. The CD spectra of the parallel double helix differed from those of B‐form DNA and had characteristic features: decreasing magnitude of the positive maximum at 265 nm and a negative peak at 285 nm.

Substrate properties of C' -methyl UTP derivatives in T7 RNA polymerase reactions. Evidence for N-type NTP conformation

The number of synthetic UTP analogues containing methyl groups in different positions of the ribose moiety were tested as substrates for T7 RNA polymerase (T7 RNAP). Two of these compounds (containing substituents in the 5′ position) were shown to be weak substrates of T7 RNAP. 3′Me‐UTP was neither substrate nor inhibitor of T7 RNAP while 2′Me‐UTP was shown to terminate RNA chain synthesis. Conformational analysis of the analogues and parent nucleotide using the force‐field method indicates that the allowed conformation of UTP during its incorporation into the growing RNA chain by T7 RNAP is limited to the χ angle range of 192–256° of N‐type conformation.

Determination of the nucleotide conformation in the productive enzyme-substrate complexes of RNA-depolymerases

© 1997 Federation of European Biochemical Societies.

Gel-Based Microchips: History and Prospects

The review describes the history of formation and development of the microchip technology and its role in the human genome project in Russia. The main accent was done on the three-dimensional gel-based microchips developed at the Center of Biological Microchips headed by A.D. Mirzabekov since 1988. The gel-based chips of the last generation, IMAGE chips (Immobilized Micro Array of Gel Elements), have a number of advantages over the previous models. The microchips are manufactured by photoinitiated copolymerization of gel components and immobilized molecules (DNA, proteins, and ligands). This ensures an even distribution of the immobilized probe throughout the microchip gel element with a high yield (about 50% for oligonucleotides). The use of methacrylamide as a main component of the polymerization mixture resulted in a substantial increase of gel porosity without affecting its mechanical properties and stability; this allowed one to work with the DNA fragments of up to 500 nt in length, as well as with quite large protein molecules. At present, the gel-based microchips are widely applied to solve different problems. The generic microchips containing a complete set of possible hexanucleotides are used to reveal the DNA motifs binding with different proteins and to study the DNA–protein interactions. The oligonucleotide microchips are a cheap and reliable diagnostic tool designed for mass application. Biochips have been developed for identification of the tuberculosis pathogen and its antibiotic-resistant forms; of orthopoxviruses, including the smallpox virus; of the anthrax pathogen; and chromosomal rearrangements in leukemia patients. The protein microchips can be adapted for further use in proteo-mics. Bacterial and yeast cells were also immobilized in the gel, maintaining their viability, which opens a wide potential for creating biosensors on the basis of microchips.

Four-Stranded DNA Helices: Conformational Analysis of Regular Poly(dT) · Poly(dA) · Poly(dA) · Poly(dT) Helices with Various Types of Base Binding

The paper presents results obtained in conformational analysis of homopolymeric four-stranded poly(dT).poly(dA).poly(dA).poly(dT) DNA helices in which the pairs of strands with identical bases are parallel and have a two-fold symmetry axis. All possible models of base binding to yield a symmetric complex have been considered. The dihedral angles of sugar-phosphate backbones and helix parameters, which are consistent with the minima of conformational energy for four-stranded DNAs, have been determined using the results of optimization of conformational energy calculated at atom-atom approximation. Potential energy is shown to depend on the structure of base complexes and on the mutual orientation of unlike strands. Possible biological functions of four-stranded helices are discussed.

A System for Distributed Storage and Analysis of Genome Information

A distributed computing system is developed to search and analyze genetic databases using parallel computing technologies. Queries are processed by a local network PC cluster. A universal task and data exchange format is developed for effective query processing. A multilevel hierarchic task batching procedure is elaborated to generate multiple subtasks and distribute them over cluster units under dynamic priority levels and with dynamic distribution of replicated source data subbases. Primary source data preparation and generation of annotation word indices are used to significantly reduce query processing time.