[2'-Modified oligoribonucleotides, containing 1,2-diol and aldehyde groups. Synthesis and properties].

1,2-Diol-oligoribonucleotides were prepared using fully protected 2'-O-[2-(2,3-dihydroxypropyl)amino-2-oxoethyl]uridine 3'-phosphoramidite. Incorporation of the 2'-modified uridine residue into oligonucleotide chains does not significantly affect the thermal stability of RNA and RNA-DNA duplexes. Periodate oxidation of the 1,2-diol results in reactive 2'-aldehyde oligoribonucleotides. Further application of these oligonucleotides for cross-linking with bacterial ribonuclease P was investigated.

[2'-aldehyde oligonucleotides: synthesis and use for affinity modification of DNA-recognizing proteins].

Oligonucleotides with 1,2-diol grouping were prepared from 2'-O-[2-(2,3-dihydroxypropyl)amino-2-oxo-ethyl]uridine 3'-phosphoramidite. The thermal stability of modified DNA duplexes and their ability to form complexes with the p50 subunit of the NF-kappaB transcription factor and (cytosine-5)-DNA methyltransferase SsoII were studied. The periodate oxidation of the l,2-diol grouping of the oligonucleotides resulted in reactive 2'-aldehyde derivatives. The opportunity of their use for the affinity modification of DNA-recognizing proteins was studied.

[Oligonucleotide derivatives in the nucleic acid hybridization analysis. II. Isothermal signal amplification in process of DNA analysis by minisequencing].

The isothermal amplification of reporter signal via limited probe extension (minisequencing) upon hybridization of nucleic acids has been studied. The intensity of reporter signal has been shown to increase due to enzymatic labeling of multiple probes upon consecutive hybridization with one DNA template both in homophase and heterophase assays using various kinds of detection signal: radioisotope label, fluorescent label, and enzyme-linked assay. The kinetic scheme of the process has been proposed and kinetic parameters for each step have been determined. The signal intensity has been shown to correlate with physicochemical characteristics of both complexes: probe/DNA and product/DNA. The maximum intensity has been observed at minimal difference between the thermodynamic stability of these complexes, provided the reaction temperature has been adjusted near their melting temperature values; rising or lowering the reaction temperature reduces the amount of reporting product. The signal intensity has been shown to decrease significantly upon hybridization with the DNA template containing single-nucleotide mismatches. Limited probe extension assay is useful not only for detection of DNA template but also for its quantitative characterization.