E. M. Ivanova

Design of Functional Diversity in Oligonucleotides via Zwitter-Ionic Derivatives of Deprotected Oligonucleotides

Abstract In this work a number of new designed mono- and bifunctional derivatives of oligonucleotides (deoxyribo-, ribo-series, and their 2′-O-methyl-, P-ethyl, methylphosphonate, and thiophosphate analogs) is described including those bearing reactive, stabilizing, and hydrophobic groups. New approach based on the use of cooperative tandems of short oligonucleotide derivatives is suggested to enhance the selective recognition of nucleic acids.

Thermodynamic parameters for calculating the stability of complexes of bridged oligonucleotides.

211 The efficiency of use of oligonucleotide constructs largely depends on optimality of selection of their structure. Directed constructing of sequence-specific ligands based on oligonucleotides and their derivatives is possible only if a physicochemical description is made, which characterizes the relationship between the structure and stability of complexes formed. To date, the corresponding parameterization has been done only for native duplex structures of DNA [1] and RNA [2], as well as for a very narrow set of complexes of oligonucleotide derivatives and their analogues [3, 4].

Enhancement of a Hybridization Analysis Efficiency by the Controlled DNA Fragmentation

The influence of a DNA amplicon fragmentation on the efficiency of detecting a specific sequence by heterophase hybridization analysis was investigated. The nucleotide sequence was detected colorimetrically after biotinylation of an oligonucleotide probe immobilized on a solid carrier via limited elongation in complex with the sample DNA with the use of Taq polymerase. Two simple and reproducible techniques of amplicon fragmentation were proposed. The techniques are based on the introduction of apurinic/apyrimidinic sites in DNA and their subsequent thermal degradation. DNA was depurinated by a mild acidic treatment. Apyrimidinic sites were generated by treating a DNA fragment containing dUMP in place of some dTMP in various proportions with uracil-DNA glycosylase (UDG). The DNA sample treated by either method proved to be suitable for hybridization analysis with Taq polymerase without additional purification. The efficiency of hybridization analysis was higher with the fragmented than with the native DNA amplicon. DNA fragmentation makes it possible to use bridged oligonucleotides, having a lower hybridization ability, as highly selective hybridization probes.

Oligonucleotide Conjugates Designed for Discriminative Hybridization at Physiological Temperature

Abstract We report the synthesis of oligonucleotide conjugates engineered to allow discriminative hybridization at temperatures around physiological. Two types of structural modifications were introduced: 1) internal oligomethylene and oligoethylene glycol spacers, and 2) terminal phenazinium residues. The thermal denaturation behaviour of the complexes formed by these oligonucleotide conjugates with a target sequence is compared to that of natural duplexes. We observed a lowering of the Tm of the duplexes formed by the internal modified oligonucleotides, whilst the terminal phenazinium residues enhance their stability. The effect of the spacers is modulated by their length and hydrophobic or hydrophilic nature. Alkylating substituents, which modify the target DNA strand on hybridization, were introduced on all conjugates, and the target cleavage obtained after piperidine treatment used as a further indicator of hybridization.

Oligonucleotide-Peptide Conjjugates for RNA Cleavage

Abstract Directed cleavage of RNA phosphodiester bonds by peptidyloligodeoxyribonucleotide containing the peptide residues with the alternated hydrophobic and basic amino acids was demonstrated.

Detection of Single-Base Substitutions in Amplified Fragments via Ligation of a Tandem of Short Oligonucleotides in Solution and on a Solid Carrier

Ligation of a tandem of short oligonucleotides was proposed for detecting single-base substitutions in amplified DNA fragments. An octamer–tetramer–octamer tandem was ligated on a 20-mer template with T4 DNA ligase. As shown with radiolabeled oligonucleotides, the efficiency and selectivity of ligation did not change with an octamer linked to a water-soluble carrier based on polyethylene glycol (MPEG), while ligation was somewhat lower with the octamer immobilized on methacrylate beads (DMEG). In both cases, polymer attachment improved the discrimination of 20-mer templates with single-base substitutions in the binding site for the tetramer or for the immobilized octamer. Tandems with a radiolabeled or biotinylated component were also efficiently ligated on amplified DNA fragments. The data obtained with DNA fragments of HIV-1 strains bru and rf demonstrate the possibility of reliable detection of single-base substitutions via ligation of a tandem and colorimetric detection of the immobilized ligation product with the streptavidin–alkaline phosphatase technique.

A New Strategy of Discrimination of a Point Mutation by Tandem of Short Oligonucleotides

Abstract A new strategy based on the use of cooperative tandems of short oligonu-cleotide derivatives (TSOD) has been proposed to discriminate a “right” DNA target from a target containing a single nucleotide discrepancy. Modification of a DNA target by oligodeoxyribonucleotide reagents was used to characterize their interaction in the perfect and mismatched complexes. It is possible to detect any nucleotide changes in the binding sites of the target with the short oligonucleotide reagent. In the presence of flanking di-3′,5′-N-(2-hydroxyethyl)phenazinium derivatives of short oligonucleotides (effectors) the tetranucleotide alkylating reagent modifies DNA target efficiently and site-specifically only in the perfect complex and practically does not modify it in the mismatched complex. It has been shown that TSOD is much more sensitive tool for the detection of a point mutation in DNA as compared to a longer oligonucleotides.

Comparison of interactions of 5'-derivatives of deoxyoctathymidylate with human DNA polymerize alpha and HIV reverse transcriptase.

Km and Vmax values for d(pT8) and its derivatives containing various 5′-end groups were estimated in the reaction of DNA polymerization α catalyzed by DNA polymerase α and HIV-RT. The effect of 5′-end modification of primer is more pronounced in the case of HIV-RT. Strong influence is observed for an intercalating (ethidium) group. The affinity of EtpT8 is 200-fold higher than that of d(pT8). Attachment of Phn-, Dnm- and Hem-groups results in the increase of affinity of modified primer from 10 up to 20 times. For DNA polymerase α the influence of modifiers on primer affinity is much weaker. The effect of 5′-end residues on the Vmax values is also more pronounced for HIV RT.The way to improve selective interaction of oligonucleotide derivatives with the primer site of HIV RT is suggested.

The nature of stabilization of the tandem DNA duplex pTGGAGCTG · (pCAGC+(Phn-NH-(CH2)3-NH)pTCCA) basing on the UV, CD, and two-dimensional NMR spectroscopy data

The properties and the three-dimensional structure of the tandem DNA duplex pTGGAGCTG·(pCAGC+(PhnL)pTCCA) in aqueous solution, where L is an amino linker and Phn is anN-(2-hydroxyethyl)phenazinium residue, were studied spectrophotometrically and by two-dimensional1H NMR spectroscopy (COSY and NOESY). When a tandem complex involving a Phn residue-bearing oligonucleotide is formed, the dye aromatic system intercalates into the double helix at the nick site and takes part in two stacking interactions: a strong one (3.5–4 Å) with the T5-A12 base pair of its own duplex moiety and a weak one (4–5 Å) with the C4-G13 pair of the adjoining duplex (mainly with the C4 base). This arrangement of the dye residue, providing a cross-interaction of the phenazinium moiety with the base pairs of the adjacent duplex structures, results in the stabilization of the whole tandem complex.

Cleavage of RNA in hybrid duplexes by theE. coli ribonuclease H: II. Substrate properties of oligonucleotides containing nonnucleotide linkers

The 20-mer bridged oligodeoxynucleotides containing short oligomers joined by the hexamethylenediol and hexaethylene glycol linkers were shown to form complementary DNA/DNA and RNA/DNA complexes whose thermostability depends on the length and number of the nonnucleotide linkers. Hybrid complexes of the bridged oligonucleotides proved to be substrates for theE. coli ribonuclease H. The presence of one-three nonnucleotide linkers in a 20-mer decreased the hydrolysis efficacy only 1.2–1.4-fold. It is the composition of the RNA cleavage products that was influenced the most significantly by the nonnucleotide linkers. RNase H simultaneously hydrolyzed the RNA 3′-ends of each hybrid duplex involving a bridged oligonucleotide. The presence of an inverted 3′-3′-phosphodiester bond at the 3′-end of the oligodeoxyribonucleotide only slightly affected the RNase H activity.