[Detection of single base polymorphism in p53 gene by ligase detection reaction and rolling circle amplification on microarrays].

We combined three modern technologies of single base polymorphism detection in human genome: ligase detection reaction, rolling circle amplification and IMAGE hydro-gel microarrays. Polymorphism in target DNA was tested by selective ligation on microarray. Product of the ligase reaction was determined in microarray gel pads by rolling circle amplification. Two different methods were compared. In first, selective ligation of short oligonucleotides immobilized on microarray was used with subsequent amplification on preformed circle probe ("common circle"). The circle probe was designed especially for human genome research. In second variant, allele-specific padlock probes that may be circularized by selective ligation were immobilized on microarray. Polymorphism of codon 72 in human p53 gene was used as a biological model. It was shown that LDR/RCA on microarray is a quantitative reaction and gives high discrimination of alleles. Principles and perspectives of selective ligation and rolling circle amplification are being discussed.

Biosensing and monitoring of cell populations using the hydrogel bacterial microchip.

Advanced development of the hydrogel bacterial microchip (HBMChip) technique is proposed. The microchip represents an array of hemispherical gel elements 0.3-60 nl in volume attached to hydrophobic glass surface and containing live immobilized microbial cells. Separate gel elements contain each up to 10(5) cells and retain them inside even while the cells are dividing. Porous structure of the gel provides easy access of nutrients and tested substances to the immobilized cells. Optical signals from the cells are easily measurable and allow monitoring of intracellular metabolism using vital fluorescent stains or engineered constructs encoding bioluminescent or fluorescent reporters. Two possible application modes of the HBMChip have been investigated, i.e. the observation of bacteria and biosensing. The dynamics of nucleic acids synthesis in growing E. coli cells has been analyzed using vital fluorescent stain SYTO 9. A special function has been suggested for evaluation of the cell growth parameters. Biosensing properties of the HBMChip have been illustrated by quantitative analysis of antibiotics and the detection of sodium meta-arsenite.

[Development of microchips for the detection of mutations of HIV-1 variability to protease inhibitors and the usage results]. / Razrabotka biologicheskikh mikrochipov dlia vyiavleniia mutatsii ustoichivosti VICH-1 k ingibitoram proteazy i rezul'taty ikh primeneniia.

An original biochip was constructed for the detection of 34 mutations of HIV-1 resistance to protease. A technology was worked out, which is based on the hybridization of a fluorescence-labeled amplified fragment of the pol gene of the HIV-1 provirus DNA with a set of specific oligonucleotides immobilized in 3-D hydrogel pads of the biological microchip. The biochip was used to analyze 115 samples of the subtype-1 provirus HIV-1 DNA isolated from untreated IDUs and their sexual partners in 15 regions of former USSR countries. Substitution of Val/IIe in position 77 of protease (V771) is known as secondary mutation of resistance to Nelfinavir detected in 55 (47.8%) of 115 HIV-1 variations. Its first appearance was registered in a patient with HIV in April 1997 in Tver, where its carrying variant caused an HIV outbreak. It is demonstrated that the V771-substitution variant, that dominates in Moscow, caused outbreaks in Irkutsk and Yekaterinburg and spread into separate districts of Perm and Perm Region. At the same time, no V771 HIV-1 was detected in any of the HIV studied cases diagnosed before 1998 in Moldova, Ukraine and Rostov Region.

[New technologies in the determination of drug susceptibility in Mycobacterium tuberculosis]. / Novye tekhnologii opredeleniia lekarstvennoi chuvstvitel'nosti Mycobacterium tuberculosis.

A variety of mutations in the genes rpoB, katG, inhA, ahpC, kasA was studied by using different molecular biological methods (conformational polymorphism of single-chain fragments, heteroduplex analysis, biochips) in rifampicin- and isoniazid-resistant Mycobacterium tuberculosis (MBT) strains isolated from patients with pulmonary tuberculosis. Twenty-nine mutation combinations were identified in the MBT strains. The use of biochips is the most promising method for identifying the type of mutations responsible for the simultaneous resistance to rifampicin and isoniazid. Detection of several MBT strains in one patient requires the use a combination of molecular biological and microbiological studies.

[Analysis of chromosome translocations involving MML by hybridization with an oligonucleotide microarray]. / Analiz khromosomnykh translokatsii s uchastiem gena MLL metodom gibridizatsii s oligonukleotidnym mikrochipami.

Identification of chromosome rearrangements is of importance for exact diagnosis, risk assessment, and therapy in blood malignancies. A new method was proposed for rapid and accurate identification of leukemia forms caused by chromosome rearrangements involving MLL (11q23). The method combines reverse transcription-multiplex PCR and hybridization with an oligonucleotide microarray. The microarray was designed to detect the five most common MLL rearrangements: t(4;11) MLL/AF4, t(9;11) MLL/AF9, t(11;19) MLL/ELL, t(11;19) MLL/ENL, and dup(11) MLL/MLL. With clinical specimens, the method was shown to efficiently identify the chromosome translocations in leukemia patients.

Hydrogel drop microchips with immobilized DNA: properties and methods for large-scale production.

Although gel-based microchips offer significant advantages over two-dimensional arrays, their use has been impeded by the lack of an efficient manufacturing procedure. Here we describe two simple, fast, and reproducible methods of fabrication of DNA gel drop microchips. In the first, copolymerization method, unsaturated groups are chemically attached to immobilized molecules, which are then mixed with gel-forming monomers. In the second, simpler polymerization-mediated immobilization method, aminated DNA without prior modification is added to a polymerization mixture. Droplets of polymerization mixtures are spotted by a robot onto glass slides and the slides are illuminated with UV light to induce copolymerization of DNA with gel-forming monomers. This results in immobilization of DNA within the whole volume of semispherical gel drops. The first method can be better controlled while the second one is less expensive, faster, and better suited to large-scale production. The microchips manufactured by both methods are similar in properties. Gel elements of the chip are porous enough to allow penetration of DNA up to 500 nucleotides long and its hybridization with immobilized oligonucleotides. As shown with confocal microscope studies, DNA is hybridized uniformly in the whole volume of gel drops. The gels are mechanically and thermally stable and withstand 20 subsequent hybridizations or 30-40 PCR cycles without decrease in hybridization signal. A method for quality control of the chips by staining with fluorescence dye is proposed. Applications of hydrogel microchips in research and clinical diagnostics are summarized.

[Identification of Mycobacterium tuberculosis strains and a simultaneous identification of their drug resistance by the hybridization method on oligonucleotide microchips]. / Opredelenie shtammov Mycobacterium tuberculosis s odnovremennym opredeleniem ikh lekarstvennoi ustoichivosti metodom gibridizatsii na oligonukleotidnykh mikrochipakh.

A method of multiplex polymerase chain reaction (PCR) with subsequent hyoridization on oligonucleotide microchips was worked out to identify the Mycobacterium tuberculosis complex and to determine simultaneously the bacterial sensitivity to 2 first-line drugs, i.e. rifampin and isoniazid. The method provides for detecting above 95% of rifampin-resistant and around 80% of isoniazid-resistant strains within 1 day.

Analysis of binding specificity of disulfide bonded dimeric lambda-Cro V55C protein with generic hexamer oligonucleotide microchip.

Binding specificity of mutant V55C disulfide bonded dimeric lambda-Cro protein (CroVC) to double-stranded DNA (dsDNA) was studied using generic hexamer oligonucleotide microchip. The curves of dissociation of hybridized DNA in the presence and absence of CroVC were converted into the effective discriminant constants to assess the relevant thermodynamic equilibrium binding constants for dsDNA-protein complexes. Then, tiling of longer oligonucleotides with shorter oligomers was used to search for sequence motifs with the highest binding specificity similarly to sequencing by hybridization. The comparison of the deduced sequences with the known natural operator half-sites demonstrated the principal ability to discern and reconstruct the major parts of 7-mer motifs corresponding to the strongest binding of CroVC subunits. Our results show the applicability of generic microchips to the analysis of binding specificity in the case of multi-subunit DNA-binding proteins.

Kinetics of hybridization on the oligonucleotide microchips with gel pads.

The kinetics of hybridization on the oligonucleotide microchip with gel pads is studied both theoretically and experimentally. The monitoring of kinetics was performed with the measurements of fluorescence intensity produced by the labeled target oligonucleotides. As is shown, the hybridization time depends on the stability of the formed duplexes, the concentrations of target and probe oligonucleotides, and the diffusion of target oligonucleotides in solution and gel pad. The initial stage of hybridization is determined by the flow of target oligonucleotides from solution, then, followed by the diffusive propagation with approximately constant concentration of oligonucleotides at the boundary of gel pad and, finally, by the exponential saturation. The theoretical predictions of hybridization kinetics reveal a good correspondence with the experimental results and may be used for the choice of the optimal hybridization conditions. The possible applications of kinetic hybridization curves to the discrimination problems and assessment of diffusion coefficients in gel pads are briefly discussed. Finally, we discuss the relationships between the binding kinetics and the general functioning of biomolecular microchips.

[Analysis of perfect and mismatched DNA duplexes by a generic hexanucleotide microchip]. / Analiz sovershennykh i mismatchevykh DNK-dupleksov s pomoshch'iu polnogo geksanukleotidnogo mikrochipa.

The thermodynamic analysis was done for the duplexes formed by fluorescently labeled oligonucleotide targets on a genetic hexanucleotide microchip. All 4096 different hexanucleotide chains were immobilized as probes in individual gel pads of the microchip. To strengthen the hybridization, each hexamer was extended at both ends by one nucleotide from the equimolar mixture of all four nucleotides to serve as nonselective linkers. It has been shown that the melting curves for oligonucleotide duplexes formed on the microchip and in a solution are quite similar. The influence of ionic surrounding has been studied in terms of the hybridization efficiency and discrimination between the mismatched and perfect duplexes. Different approaches have been tested to compensate the dependence of duplex stability on the GC content. It has been demonstrated that the use of chaotropic agents, addition of nonlabeled GC-rich competitor oligonucleotides, as well as creation of a temperature gradient along the microchip reproducing the distribution of melting temperatures, efficiently level out the AT/GC differences. The use of tetramethylammonium chloride for the same purpose was accompanied by weakening to some extent the discrimination between the mismatched duplexes and the perfect ones.

Hydrogel-based protein microchips: manufacturing, properties, and applications.

Here a simple, reproducible, and versatile method is described for manufacturing protein and ligand chips. The photo-induced copolymerization of acrylamide-based gel monomers with different probes (oligonucleotides, DNA, proteins, and low-molecular ligands) modified by the introduction of methacrylic groups takes place in drops on a glass or silicone surface. All probes are uniformly and chemically fixed with a high yield within the whole volume of hydrogel semispherical chip elements that are chemically attached to the surface. Purified enzymes, antibodies, antigens, and other proteins, as well as complex protein mixtures such as cell lysates, were immobilized on a chip. Avidin- and oligohistidine-tagged proteins can be immobilized within biotin- and Ni-nitrilotriacetic acid-modified gel elements. Most gel-immobilized proteins maintain their biological properties for at least six months. Fluorescence and chemiluminescence microscopy were used as efficient methods for the quantitative analysis of the microchips. Direct on-chip matrix-assisted laser desorption ionization-time of flight mass spectrometry was used for the qualitative identification of interacting molecules and to analyze tryptic peptides after the digestion of proteins in individual gel elements. We also demonstrate other useful properties of protein microchips and their application to proteomics and diagnostics.

[Identification of orthopoxvirus species using oligonucleotide micro-chips]. / Vidovaia identifikatsiia ortopoksvirusov na oligonukleotidnykh mikrochipakh.

A method for describing the Orthopoxviruses that are pathogenic both to man and animals is described in the article. The method is based on hybridization of a fluorescently labelled amplified DNA sample with oligonucleotides, which were immobilized in a microchip. Species-specific regions within the crmB gene encoding a viral analogue of the tumor necrosis factor receptor, i.e. an important gene determining the pathogenicity of the mentioned Orthopoxviruses type, were used as a target for identification. The identification procedure takes around 6 hours and does not demand any costly equipment (a portable fluorescent microscope can be used).

[Dye with low specificity to nucleotide sequences of DNA: use for assessing the quantity of oligonucleotides, immobilized in cells of biological microchips]. / Kasitel' s nizkoi spetsifichnost'iu k nukleotidnoi posledovatel'nosti DNK: primenenie dlia ostenki kolichestva oligonukleotidov, immobilizovannykh v iacheikakh biologicheskikh mikrochipov.

To assess the DNA amount in samples (e.g., in biological microchip gel pads) by means of fluorescent dyes, one should use the dyes whose fluorescence weakly depends on DNA composition and structure. With the ImD-310 dye created for this purpose, we have analyzed the staining of single- and double-stranded oligo- and polynucleotides of different nucleotide composition, length, and concentration both in solution and being immobilized in biological microchip gel pads. It turned out that ImD-310 has no pronounced specificity to the single- and double-stranded nucleotide sequences, while the intensity of fluorescence for the dye complexes with d(A)8, d(T)8, d(C)8, and d(G)8 at high temperatures (50 degrees C) differs by less than 25%. A linear correlation has been established between the intensity of fluorescence and the amount of oligonucleotides immobilized on a biological microchip. The plots of the intensity of fluorescence against the concentration of NaCl and the temperature were obtained. By using a generic microchip containing all 4096 hexamer oligonucleotides, it has been determined that the dye has no distinct specificity to any certain motifs of the nucleotide sequence. Thus, ImD-310 may serve as an efficient fluorescent probe to quickly estimate the amount of oligonucleotides immobilized in a microchip, in an electrophoretic gel, etc.

Specificity of mammalian Y-box binding protein p50 in interaction with ss and ds DNA analyzed with generic oligonucleotide microchip.

p50 protein is a member of the Y-box binding transcription factor family and is a counterpart of YB-1 protein. The generic microchip was used to analyze the sequence specificity of p50 binding to single (ss) and double-stranded (ds) oligodeoxyribonucleotides. The generic microchip contained 4,096 single-stranded octadeoxyribonucleotides in which all possible core 6-mers (4(6)=4,096) were flanked at their 3' and 5'-ends with degenerated nucleotides. The oligonucleotides were chemically immobilized within polyacrylamide gel pads fixed on a glass slide. The binding of p50 to the generic microchip was shown to be the most specific to ss GGGG motif and then to ss CACC and CATC motifs. GC-rich ds oligonucleotides of the generic microchip, and particularly those containing GGTG/CACC, GATG/CATC, and GTGG/CCAC heterogeneous motifs, were most efficiently destabilized due to interaction with p50. Gel-shift electrophoresis has shown that the protein exhibits much higher binding specificity to 24-mer oligoA-TGGGGG-oligoA containing G-rich 6-mer, in comparison with 24-mer oligoA-AAATAT-oligoA carrying A,T-rich 6-mer in full correspondence with the data obtained with the microchip. Studies of DNA-binding proteins using gel-immobilized ss and ds DNA fragments provide a unique possibility to detect low-affinity complexes of these proteins with short sequence motifs and assess the role of these motifs in sequence-specific interactions with long recognition sites.

[Fluorescence of meso-tetrakis(4-(carboxy)phenyl)porphine covalently bound to oligonucleotides d(CG)5 and d(TA)5]. / Fluorestsentsiia mezo-tetrakis(4-(karboksi)fenyl)porfina, kovalentno sviazanogo s oligonukleotidami d(CG)5 i d(TA)5.

The amino-reactive derivative of tetraphenylporphine meso-tetrakis[4-(carboxy)phenyl]porphine (TCPP) was synthesized, which is characterized by a high molar absorption coefficient (epsilon 416 = 36,500 M-1.cm-1). TCPP was covalently attached to oligonucleotides d(CG)5 [d(CG)5-TCPP] and d(TA)5 [d(TA)5-TCPP]. The spectral characteristics of these complexes were studied in 0.01 M phosphate buffer, pH 7 at 23 degrees C. UV-visible absorption spectra of these complexes have a clearly pronounced Soret band at (414 +/- 1) nm for d(CG)5-TCPP and at (412 +/- 1) nm for d(TA)5-TCPP. The fluorescence spectra of these complexes have maxima at (648 +/- 2) nm for d(CG)5-TCPP and at (658 +/- 2) nm for d(TA)5-TCPP. In this study we also determined fluorescence quantum yields q and fluorescence lifetimes tau [q = 0.099 +/- 0.011, tau = (9.0 +/- 0.3) ns for d(CG)5-TCPP and q = 0.080 +/- 0.011, tau = (8.7 +/- 0.3) ns for d(TA)5-TCPP]. A temperature rise from 5 to 50 degrees C produced only slight (within 23%) emission changes in both samples studied. Taking into account: a) high fluorescence yields (q), b) weak dependence of q on temperature, c) weak q dependence of q on the oligonucleotide type, we conclude that TCPP may be used as a sensitive fluorescence label in DNA studies.

[Molecular genetic methods for the detection of rifampicin-resistant Mycobacterium tuberculosis strains]. / Molekuliarno-geneticheskie metody vyiavleniia rifampitsinrezistentnykh shtammov Mycobacterium tuberculosis.

RCR-heteroduplex (GDA) and chip methods were used to detect rifampricin-resistant (RR) and rifampicin-sensitive (RS) Mycobacterium tuberculosis (MTB) in the samples from patients (sputum) and in the clinical isolates of MTB from these patients (MB/BacT liquid medium and Lowenstein Jensen's (LJ) solid medium. The efficiency of detecting RR and RS of MTB (from the sputum) is 100 and 92.3% in the chip and GDA tests, respectively. Correlations between GDA (sputum) and drug test (LJ) were 91.7%, that of chip (sputum) and drug test LJ, 88.5%, chip (sputum) and chip clinical isolates (LJ), 100%. The efficacy of GDA and chip in the detection of RR of MTB strains is under discussion.

Optimization of an oligonucleotide microchip for microbial identification studies: a non-equilibrium dissociation approach.

The utility of a high-density oligonucleotide microarray (microchip) for identifying strains of five closely related bacilli (Bacillus anthracis, Bacillus cereus, Bacillus mycoides, Bacillus medusa and Bacillus subtilis) was demonstrated using an approach that compares the non-equilibrium dissociation rates ('melting curves') of all probe-target duplexes simultaneously. For this study, a hierarchical set of 30 oligonucleotide probes targeting the 16S ribosomal RNA of these bacilli at multiple levels of specificity (approximate taxonomic ranks of domain, kingdom, order, genus and species) was designed and immobilized in a high-density matrix of gel pads on a glass slide. Reproducible melting curves for probes with different levels of specificity were obtained using an optimized salt concentration. Clear discrimination between perfect match (PM) and mismatch (MM) duplexes was achieved. By normalizing the signals to an internal standard (a universal probe), a more than twofold discrimination (> 2.4x) was achieved between PM and 1-MM duplexes at the dissociation temperature at which 50% of the probe-target duplexes remained intact. This provided excellent differentiation among representatives of different Bacillus species, both individually and in mixtures of two or three. The overall pattern of hybridization derived from this hierarchical probe set also provided a clear 'chip fingerprint' for each of these closely related Bacillus species.

Comparison of complex DNA mixtures with generic oligonucleotide microchips.

The reproducibility of melting curves for repeated hybridizations of target DNA with generic oligonucleotide microchips is shown experimentally to depend on the character of matching between fragments of target DNA and immobilized oligonucleotides. The reproducibility of melting curves is higher for the perfect match duplexes and decreases as the number of mismatched pairs within duplexes increases. This effect was applied to the comparative analysis of complex DNA mixtures. We developed a scheme in which we can identify and discriminate between the probe oligonucleotides responsible for the distinctions between target DNA mixtures. A scheme is illustrated by comparing DNA mixtures corresponding to V-D-J genes connected with populations of mRNAs CDR3 TCR Vb (T-cell receptor beta complementarity determining region 3) from the thymus and pancreas of NOD mice. Our results demonstrate that generic microchips can be applied efficiently to the analysis of DNA mixtures.